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Awesome Computational Neuroscience !Awesome (https://awesome.re/badge.svg) (https://awesome.re)
 
To contribute, see :pencil2: code of contribution (https://github.com/eselkin/awesome-computational-neuroscience/blob/master/contributing.md)
 
Computational neuroscience (https://en.wikipedia.org/wiki/Computational_neuroscience) is a multidisciplinary science that joins biology/neuroscience, medicine, biophysics, psychology, computer science,
mathematics, and statistics to study the nervous system using computational approaches.
 
This list of schools and researchers in computational neuroscience, theoretical neuroscience, (and systems neuroscience) aims to give a global perspective of researchers in the field, make it easier to apply to
the listed institutions, and also provide a reasonable way to find an advisor.
 
In addition to names of PIs, excerpts of their academic biographies, and links to their publications, many of the researchers are qualified with a small scale "+/=/- computational." The metric is subjective to
the editor of that material but it generally breaks down as: (+) refers to a researcher the university identifies as a computational neuroscientist, their bio consistently identifies a significant component of
their research is in the field, and they have a significant body of work in the field. (=) refers to the fact that the university identifies them as practicing computational research and they have occasionally
produced articles in the field. (-) means that the university identifies them as practicing computational neuroscience, their bio might also mention it, but articles could not be found that represent this
material. As with ratings, this metric might change for a researcher over time as they publish more.
 
Contents
 
- Europe (#europe)
- Germany (#germany)
- **INI** (#ini)
- Italy (#italy)
- **SISSA** (#sissa)
- Norway (#norway)
- **NTNU** (#ntnu)
- North America (#north-america)
- Canada (#canada)
- **Ontario** (#ontario)
- **University of Waterloo** (#university-of-waterloo)
- United States (#united-states)
- **U.S. West** (#us-west)
- **California Institute of Technology** (#california-institute-of-technology)
- **Stanford University** (#stanford-university)
- **University of California, Berkeley** (#university-of-california-berkeley)
- **University of California, Davis** (#university-of-california-davis)
- **University of California, Irvine** (#university-of-california-irvine)
- **University of California, Los Angeles** (#university-of-california-los-angeles)
- **University of California San Diego** (#university-of-california-san-diego)
- **University of California, Santa Barbara** (#university-of-california-santa-barbara)
- **University of Oregon** (#university-of-oregon)
- **University of Southern California** (#university-of-southern-california)
- **University of Texas, Austin** (#university-of-texas-austin)
- **University of Washington, Seattle** (#university-of-washington-seattle)
- **U.S. Central** (#us-central)
- **University of Chicago** (#university-of-chicago)
- **University of Illinois** (#university-of-illinois)
- **University of Iowa** (#university-of-iowa)
- **Indiana University** (#indiana-university)
- **University of Minnesota** (#university-of-minnesota)
- **U.S. East** (#us-east)
- **Boston University** (#boston-university)
- **Brandeis University** (#brandeis-university)
- **Brown University** (#brown-university)
- **Carnegie Mellon University and University of Pittsburgh** (#carnegie-mellon-university-and-university-of-pittsburgh)
- **Columbia University** (#columbia-university)
- **Johns Hopkins University** (#johns-hopkins-university)
- **Johns Hopkins University - Janelia Joint Graduate Program** (#johns-hopkins-university---janelia-joint-graduate-program)
- **Massachussetts Institute of Technology** (#massachussetts-institute-of-technology)
 
Europe
 
Germany
 
INI
 
- Ruhr-Universität Bochum, Institut für Neuroinformatik (INI) (https://www.ini.rub.de/research/groups/computational_neuroscience/)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/-
computatio
nal
├──────────┼─────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼─────────────────────────────────────────┼──────────┤
Cheng, SenOur first approach is modeling, including mathematic models as well as computer simulation of complex networks. While all models are simplified, Lab +
we aim to build biologically realistic models that capture the essence of the neural circuit mechanism underlying learning and memory. Our second(https://www.ini.rub.de/the_institute/peo
approach is data-mining. We develop methods for model-based data analysis and apply such methods to experimental data. These data include ple/sen-cheng/#publications)
electrophysiological and EEG recordings as well as behavioral data. We collaborate closely with neuroscientists on the RUB campus and at other
universities in Germany and abroad.
 
 
 
Italy
SISSA
 
- International School for Advanced Studies (SISSA), Trieste (https://phdcns.sissa.it/admission-procedure)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/-
computatio
nal
├──────────────┼──────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼────────────────────────────────────────────────────────┼──────────┤
Treves, Hippocampal Processing: The aim is to understand how the hippocampus contributes to memory, focusing on modelling coding Google +
Alessandro strategies within each structure of the hippocampal formation (e.g. self-organization of grid representations), as well as (https://scholar.google.com/citations?hl=en&user=I2Y8X5A
interactions between different structures. Neural Basis of Language: The aim is to describe network behaviour that could AAAAJ&view_op=list_works&sortby=pubdate)
subserve Language production. A class of reduced Potts models of large semantic associative networks, endowed with adaptation,
naturally displays Latching dynamics, i.e. hopping from one attractor to the next. Such dynamics may be associated with a
network capacity for infinite recursion, which is considered as the core of several higher cognitive functions.
(https://people.sissa.it/~ale/limbo.html)
 
 
 
Norway
 
NTNU
 
- Kavli Institute for Systems Neuroscience Center for Neural Computation @ Norwegian University of Science and Technology (https://www.ntnu.edu/kavli)
- Apply to Ph.D. in Medicine and Health Sciences. Masters degree requirement. Admission is rolling. Applications to the department with the desired academic advisor. (https://www.ntnu.edu/studies/phmed)
 
(#contents)
 
 
 
PI(Ph.D.s) Department Research Areas Research +/=/
-
comp
utat
iona
l
├─────────────────┼────────────────────────────────────┼─────────────────────────────────────────────────────────────────────────────────────┼───────────────────────────────────────────────────────────────┼────┤
Moser, Edvard Kavli Institute for Systems The Moser group implements and develops tools for large-scale brain recordings using Lab (https://www.ntnu.edu/kavli/moser-group#/view/publications)+?
Ingjald Neuroscience standard tetrode recording as well as recently introduced high-site-count silicon
probes (meaning they can sample from a particular brain area with high-resolution).
In addition, they use portable two-photon microscopes for high-resolution optical
imaging of neuronal activity. This means they can record the brain signal of many
neurons, while the mice are allowed to freely move through the environment.
(https://www.ntnu.edu/kavli/moser-group#/view/about)
Moser, May-Britt Kavli Institute for Systems The Moser group implements and develops tools for large-scale brain recordings using Lab (https://www.ntnu.edu/kavli/moser-group#/view/publications)+?
Neuroscience standard tetrode recording as well as recently introduced high-site-count silicon
probes (meaning they can sample from a particular brain area with high-resolution).
In addition, they use portable two-photon microscopes for high-resolution optical
imaging of neuronal activity. This means they can record the brain signal of many
neurons, while the mice are allowed to freely move through the environment.
(https://www.ntnu.edu/kavli/moser-group#/view/about)
Witter, Menno P. Kavli Institute for Systems Witter’s team uses genetically engineered animals and non-infectious viral tracers toLab +
Neuroscience fluorescently visualize specific cell types and connections within the entorhinal (https://www.ntnu.edu/kavli/witter-group#/view/publications)
cortex. After identifying cell types and connections, the team can turn specific
cells on and off with laser beams (a technique known as optogenetics) and then study
the effect of this manipulation on the rest of the circuit.
(https://www.ntnu.edu/kavli/witter-group#/view/about)
Kentros, CliffordKavli Institute for Systems The Kentros laboratory uses mouse molecular genetic techniques to address the neural Google +
Neuroscience circuitry underlying learning and memory. Combining the anatomical specificity of (https://scholar.google.com/citations?hl=en&user=YtdZeFgAAAAJ&v
mouse molecular genetics with in vivo recordings from awake, behaving animals gives iew_op=list_works&sortby=pubdate)
an edge to analyzing the functional circuitry of memory.
(https://www.kentroslab.com/research)
Roudi, Yasser Kavli Institute for Systems Roudi’s team uses mathematical tools from the field of theoretical physics to analyseLab (https://www.spinorkavli.org/) +
Neuroscience big datasets, to develop models that draw out neural mechanisms in big datasets, and
to identify and describe universal principles in biological systems.
(https://www.ntnu.edu/kavli/roudi-group#/view/about)
Whitlock, Kavli Institute for Systems The Whitlock group uses several tools to tackle their research questions: (1) a Google +
Jonathan Neuroscience tracking and visualization software (developed in-house), which follows and records a(https://scholar.google.com/citations?hl=en&user=OFVqZ6IAAAAJ&v
rat’s movement through three-dimensional space and (2) electrophysiological iew_op=list_works&sortby=pubdate)
recordings of the rat’s brain while it moves through that three-dimensional space.
These two pieces of information (behavior and neural activity) are then analyzed
using statistical methods. The parallel anatomical work in mice used tracers and
markers to map out the circuits of the PPC. (https://www.whitlocklab.org/)
Yakse, Emre Kavli Institute for Systems The Yaksi group uses two-photon microscopy, electrophysiology, genetic and applied Lab (https://yaksilab.com/publications/) +
Neuroscience mathematical tools to measure and analyze neural activity across the whole brain of
awake, behaving juvenile zebrafish in naturalistic and virtual reality environments.
(https://yaksilab.com)
Doeller, Medicine and Neuroscience The Doeller and Kaplan group uses neuroimaging techniques such as functional magneticLab (https://doellerlab.com/publications/) +?
Christian resonance imaging (fMRI) and magnetoencephalography (MEG) to investigate brain
systems that support learning, memory, and decision making. The former technique
boasts relatively good “spatial resolution” (the ability to detect where a signal is
coming from) while the latter boasts good “temporal resolution” (the ability to
detect when a signal occurs). By combining this data with electrophysiological
recordings from rodents, the team is able to paint a more comprehensive picture of
the link between entorhinal brain signals and general cognition. ... Our framework is
concerned with the key idea that this navigation system in the brain—potentially as a
result of evolution—provides a fundamental neural metric for human cognition.
(https://doellerlab.com/research/)
Kaplan, Raphael Kavli Institute for Systems See Doeller lab (https://doellerlab.com/research/) Google +?
Samuel Matthew Neuroscience (https://scholar.google.com/citations?hl=en&user=NHhnjsIAAAAJ&v
iew_op=list_works&sortby=pubdate)
 
 
 
North America
 
Canada
 
Ontario
 
University of Waterloo
 
- Theoretical Neuroscience (https://uwaterloo.ca/centre-for-theoretical-neuroscience/graduate-students/apply-admissions)
- Apply: Apply to established graduate department (e.g. <a
href="https://uwaterloo.ca/graduate-studies-academic-calendar/mathematics/department-applied-mathematics/doctor-philosophy-phd-applied-mathematics#admission_requirements
">Applied Math)
- For CS a GRE is required if you have not completed a Bachelor's degree in a North American university with English as a primary language.
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
-
comp
utat
iona
l
├───────────────────────┼─────────────────────────────────────────────────────────────────────────────────────────────────┼──────────────────────────────────────────────────────────────────────────────────┼────┤
Anderson, Britt Dr. Anderson combines computational and empirical approaches in the study of spatial attention Lab (https://brittlab.uwaterloo.ca/publications/) +
and general cognitive ability.
(https://uwaterloo.ca/centre-for-theoretical-neuroscience/people-profiles/britt-anderson)
Campbell, Sue Ann Her main research interest is in the mathematical modelling of neural systems at the single cell Google +
and small network level. (https://scholar.google.com/citations?hl=en&user=KgioDk8AAAAJ&view_op=list_works&s
(https://uwaterloo.ca/centre-for-theoretical-neuroscience/people-profiles/sue-ann-campbell) ortby=pubdate)
Danckert, James Dr. Danckert’s research explores the role of parietal cortex in the control of visually guided Google =
actions and examines the consequences of injury to this part of the brain. (https://scholar.google.com/citations?hl=en&user=Bb2jD2QAAAAJ&view_op=list_works&s
(https://uwaterloo.ca/danckert-attention-group/) ortby=pubdate)
Eliasmith, Chris With Charles Anderson, I have developed a general method for building large-scale, biologically Google +
detailed models of neural systems. I have applied this method in a variety of contexts, including(https://scholar.google.com/citations?hl=en&user=KOBO-6QAAAAJ&view_op=list_works&s
rat navigation, working memory, lamprey swimming, hemineglect, and language-based reasoning. ortby=pubdate)
(https://uwaterloo.ca/centre-for-theoretical-neuroscience/people-profiles/chris-eliasmith)
Fugelsang, Jonathan To understand the mechanisms underlying these processes, I use both behavioural and functional Google -
brain imaging (e.g., ERP, Functional Magnetic Resonance Imaging *fMRI* ) methodologies. (https://scholar.google.com/citations?hl=en&user=FD3P_78AAAAJ&view_op=list_works&s
(https://uwaterloo.ca/psychology/people-profiles/jonathan-fugelsang) ortby=pubdate)
Ingalls, Brian (More We use mathematical models and experimental methods to investigate the behaviour of intracellularGoogle +
computational biology molecular networks and cell-to-cell interactions. This work ranges from fundamental studies of (https://scholar.google.com/citations?hl=en&user=Td4gEp0AAAAJ&view_op=list_works&s
than neuroscience) biology to applications in biotechnology and health (https://uwaterloo.ca/scholar/bingalls/) ortby=pubdate)
Kapre, Nachiket (CS Digital systems, Embedded computing systems, Reconfigurable computing, FPGA Architecture, Google +
only, unrelated) Applications, Compilers (https://uwaterloo.ca/electrical-computer-engineering/profile/nachiket) (https://scholar.google.com/citations?hl=en&user=JxwwXHMAAAAJ&view_op=list_works&s
ortby=pubdate)
Marriott, Paul (AppliedHis interests focus on using geometric ideas, for example differential or convex geometry in Google +
math, some NS) statistics. He has recently been working on geometric methods to understand mixture models. (https://scholar.google.com/citations?hl=en&user=hX40SzUAAAAJ&view_op=list_works&s
(https://uwaterloo.ca/centre-for-theoretical-neuroscience/people-profiles/paul-marriott) ortby=pubdate)
Orchard, Jeff My research aim is to uncover mechanisms that underlie the computational and organizational Google +
aspects of the brain. For example, what function does feedback play in our brains, and how do our(https://scholar.google.com/citations?hl=en&user=cAfBytAAAAAJ&view_op=list_works&s
expectations influence our perceptions? I study these questions by modelling neural networks. ortby=pubdate)
(https://cs.uwaterloo.ca/~jorchard/UWaterloo/Home.html)
Spafford, J. David Major projects in Dr. Spafford's lab focus on the: a) cellular and molecular mechanisms -
underlying calcium channel expression and localization in developing synapses; b) modulation of
calcium channel function by G proteins, phosphorylation and synaptic proteins; c) isolation and
characterization of anti-calcium channel toxins for caveolin 1 (Cav1), Cav2 and Cav3 calcium
channels.
(https://uwaterloo.ca/centre-for-theoretical-neuroscience/people-profiles/j-david-spafford)
Tripp, Bryan The central goal of the lab is to develop increasingly realistic computer/robotic models of the Google +
dorsal visual pathways and the networks that control eye and limb motion. (https://scholar.google.com/citations?hl=en&user=OUMJw3oAAAAJ&view_op=list_works&s
(https://uwaterloo.ca/centre-for-theoretical-neuroscience/people-profiles/bryan-tripp) ortby=pubdate)
 
 
 
United States
 
U.S. West
 
California Institute of Technology
 
- CNS (http://www.cns.caltech.edu/admissions/index.html)
- General Graduate application, multidisciplinary program. (http://www.gradoffice.caltech.edu/admissions/applyonline)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
-
comp
utat
iona
l
├───────────────┼─────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼──────────────────────────────────────────────────────────────────┼────┤
Abu-Mostafa, The Learning Systems group at Caltech works on the theory, implementation, and application of automated learning, patternGoogle +
Yaser recognition, and neural networks. We are an interdisciplinary group with students coming from Electrical Engineering, (https://scholar.google.com/scholar?as_ylo=2018&q=Abu-mostafa,+yas
Computer Science, Mathematics, and Physics. We work on a variety of projects analyzing and synthesizing systems that can ser+caltech&hl=en&as_sdt=0,5)
be trained to perform their task. (http://www.cns.caltech.edu/people/faculty/abu-mostafa.html)
Adolphs, Ralph The Emotion and Social Cognition Lab (aka “The Adolphs Lab”) investigates the neural underpinnings of human social Lab (http://emotion.caltech.edu/?page_id=12470) =
behavior. We are pursuing questions such as: How do we recognize emotion from facial expressions? How do we make social
judgments about other people? How do we look at people’s faces (how do we move our eyes when looking at them)? How do we
make decisions that are influenced by emotion? How do we remember emotional events in our lives? How do we make moral
judgments about what is right and wrong? (http://emotion.caltech.edu/)
Allman, John We are using a variety of histological methods to visualize the complex structure of these cells and will be performing Google +
computer simulations of the cells activity in living brain. We are also pursuing several lines of research investigating (https://scholar.google.com/scholar?as_ylo=2018&q=allman,+john+M+c
evolutionary pressures and scaling relationships in mammalian brains. We have performed computer-assisted imaging of altech&hl=en&as_sdt=0,5)
living and fixed brains of modern species as well as subfossil and fossil samples of extinct species.
(http://www.cns.caltech.edu/people/faculty/allman.html)
Ames, Aaron Bipedal robotics, hybrid systems, Zeno behavior, prosthetic devices. Theoretical foundations with practical applications Lab (http://ames.caltech.edu/publications.html) +
to human inspired bipedal walking, Hybrid mechanical systems with a special emphasis on bipedal robots;Hybrid stability
theory and its relationship to Zeno behavior;Hybrid geometric mechanics with a focus on hybrid geometric reduction and
geometric control; Hybrid topology, geometry and homology; Novel Applications such as Prosthetics
(http://ames.caltech.edu/research.html)
Anandkumar, Tensors (seminal work). Democratizing ML. Fairness. PhD students and postdoctoral candidates with strong foundation in Lab =
Anima machine learning, statistics, and algorithms. (http://tensorlab.cms.caltech.edu/users/anima/) (http://tensorlab.cms.caltech.edu/users/anima/publications.html)
Andersen, One project in the lab is to develop a cognitive-based neural prosthesis for paralyzed patients;We have been examining Lab (http://www.vis.caltech.edu/papers) +
Richard the coordinate frame for coordinated movements of the hand and eyes;We have been examining decision making in
parietal-frontal circuits;A 4.7 Tesla vertical magnet for monkey imaging has recently been installed at Caltech. We are
using this magnet, combined with neural recordings, to examine the correlation between neural activity and fMRI signals.
(http://www.cns.caltech.edu/people/faculty/andersen.html)
Anderson, DavidResearch in this laboratory is aimed at understanding the neurobiology of emotion. We seek to elucidate how fundamental Lab (http://davidandersonlab.caltech.edu/publications) +
properties common to emotional states, such as arousal, are encoded in the circuitry and chemistry of the brain and how
these internal states combine with sensory stimuli to elicit specific emotional behaviors, such as fear or aggression
(http://davidandersonlab.caltech.edu/)
Barr, Alan A source of motivation and long term goal for the research is the creation of tools for simulation and behavioral +
prediction of mechanical and biophysical structures. The methods are intended to eventually be applied to simulating the
behavior of cellular organelles, but also to self-assembling robotic structures as potentially needed for human
colonization of space; the same modeling technology can be used for both applications.
(http://www.cns.caltech.edu/people/faculty/barr.html)
Bruck, JehoshuaWe attempt to prove this conjecture by evaluating string replication systems from an information theory perspective, as Google +
well as study tandem duplication and interspersed duplication mechanisms. (http://www.paradise.caltech.edu/index.html) (https://scholar.google.com/citations?hl=en&user=HgaNy9kAAAAJ&view
_op=list_works&sortby=pubdate)
Burdick, Joel Our research group pursues both Robotics and BioEngineering related to spinal cord injury Google +
W. (http://robotics.caltech.edu/wiki/index.php/Robotics) (https://scholar.google.com/scholar?as_ylo=2018&q=Joel+W.+Burdick&
hl=en&as_sdt=0,5)
Camerer, Colin Neuroeconomics. Psychology and economics, decision making, business administration, game theory. Google +
F. (http://www.cns.caltech.edu/people/faculty/camerer.html) (https://scholar.google.com/citations?hl=en&user=8udO65kAAAAJ&view
_op=list_works&sortby=pubdate)
Dickinson, studies the neural and biomechanical basis of behavior in the fruit fly, Drosophila. We strive to build an integrated Google +
Michael model of behavior that incorporates an understanding of morphology, neurobiology, muscle physiology, physics, and ecology(https://scholar.google.com/citations?hl=en&user=kc3snaQAAAAJ&view
(https://dickinsonlab.caltech.edu/) _op=list_works&sortby=pubdate)
Elowitz, The Elowitz Lab is interested in how genetic circuits, composed of interacting genes and proteins, enable individual Lab (http://www.elowitz.caltech.edu/publications.html) +
Michael cells to make decisions, oscillate, and communicate with one another (http://www.elowitz.caltech.edu/)
Gradinaru, The Gradinaru Lab studies the mechanism of action for deep brain stimulation (DBS), a therapeutical option for motor and Lab (http://glab.caltech.edu/publications.html) +
Viviana mood disorders such as Parkinson’s and depression. Our previous work highlighted the importance of selectively
controlling axons and not local cell bodies in modulating behavior, a principle that might play a generalized role across
many effective deep brain stimulation paradigms. We are now particularly interested in the long-term effects of DBS on
neuronal health, function, and ultimately behavior. (http://glab.caltech.edu/)
Hong, Betty Our goal is to understand how molecular diversity at synapses gives rise to useful variation in synaptic physiology, and Lab (http://www.ejhonglab.org/publications/) +
(E.J.) how this may reflect the specialization of synapses to perform specific useful computations in their respective circuits.
(http://www.ejhonglab.org/team/)
Konishi, Owls. Preditors. The work over the past twenty years has led to a reasonably good understanding of the algorithm for the Google +
Masakazu computation of sound locations in 2 dimensions (http://www.cns.caltech.edu/people/faculty/konishi.html) (https://scholar.google.com/scholar?as_ylo=2016&q=Konishi,+Masakaz
u++caltech&hl=en&as_sdt=0,5)
Lester, Henry The Lester lab uses techniques at the intersection of biophysics, single-molecule imaging, chemistry, mouse genetics, andGoogle +
A. neuroscience to understand the biophysical basis of ligand-gated ion channels including the nicotinic acetylcholine (https://scholar.google.com/citations?hl=en&user=8KbzXvoAAAAJ&view
receptor. (http://henrylesterresearchgroup.caltech.edu/) _op=list_works&sortby=pubdate)
Lois, Carlos Our laboratory is interested in the assembly of brain circuits and the mechanisms by which the activity of neurons in Google +
these circuits give rise to behavior. We focus on the process of neuron addition into the vertebrate brain, and seek to (https://scholar.google.com/citations?hl=en&user=BO4a37QAAAAJ&view
understand how new neurons integrate into the circuits of the adult brain, and their role in information processing and _op=list_works&sortby=pubdate)
storage (http://www.cns.caltech.edu/people/faculty/lois.html)
Mead, Carver Very diverse history of research spanning gravitation to analog silicon retinas... (http://www.carvermead.caltech.edu/) Lab (http://www.carvermead.caltech.edu/publications.html) +
(emeritus)
Meister, MarkusMy goal is to understand the function of neuronal circuits. By "circuit" I mean a brain structure with many neurons that Google +
has some anatomical and functional identity, and exchanges signals with other brain circuits (https://scholar.google.com/citations?hl=en&user=QKhjs2YAAAAJ&view
(http://www.cns.caltech.edu/people/faculty/meister.html) _op=list_works&sortby=pubdate)
Mobbs, Dean The Mobbs Lab is inspired by insights from the fields of behavioral ecology, social, evolutionary and clinical Lab (https://www.deanmobbslab.com/publications) +
psychology. Our lab’s main endeavor is to understand the neural and behavioral dynamics of human social and emotional
experiences and consequently build new theoretical models that merge multiple fields. We employ brain imaging (e.g. fMRI)
and novel behavioral techniques to examine the neurobiological systems that coordinate fear and anxiety in humans. My lab
also investigates the proximate and ultimate value of social behavior. (https://www.deanmobbslab.com/)
Murray, RichardCurrent projects include integration of control, communications, and computer science in multi-agent systems, informationLab =
dynamics in networked feedback systems, analysis of insect flight control systems, and synthetic biology using (http://www.cds.caltech.edu/~murray/wiki/index.php?title=Papers)
genetically-encoded finite state machines. (http://www.cds.caltech.edu/~murray/wiki/Main_Page)
O'Doherty, JohnThe ability to make decisions requires neural machinery that has been honed through evolution to enable animals to learn Lab (http://olab.caltech.edu/publications.html) +
about the structure of their environment and uncover causal links between their own behavior and the probability of
obtaining rewards. A deeper understanding of how the brain does this will not only inspire new theories of decision
making, it will also contribute to the development of genuine "artificial intelligence", and it will enable us to
understand why some humans are better than others at making decisions, why humans with certain psychiatric disorders or
brain lesions are less capable of doing so, and why under some circumstances humans systematically fail to make
"rational" decisions. The goal of our research is to unravel the neural computations underlying this process in the human
brain. (http://olab.caltech.edu/)
Oka, Yuki Our goal is to understand where and how appetites are encoded in the brain... With these thirst-controlling neurons in Lab (http://www.okalab.caltech.edu/Publications.html) +
hand, we are now exploring the downstream and upstream neural circuits to decipher how motivational signals are
translated into behavioral outputs. (http://www.okalab.caltech.edu/)
Perona, Pietro We are interested in the computational foundations of vision. This knowledge helps us design machine vision systems with Google +
applications to science, consumer products, entertainment, manufacturing and defense (http://www.vision.caltech.edu/) (https://scholar.google.com/citations?hl=en&user=j29kMCwAAAAJ&view
_op=list_works&sortby=pubdate)
Prober, David We are using zebrafish as a new model to discover and understand genetic and neuronal circuits that regulate sleep. Lab (https://www.proberlab.caltech.edu/Publications) +
A. (https://www.proberlab.caltech.edu/)
Quartz, Steven Impact of neuroscience advances for many of the traditional problems of mind, ranging from a neurally plausible theory of =
mental representation, the origin of knowledge, to the formal learning properties of neurally constrained developing
systems. (http://www.cns.caltech.edu/people/faculty/quartz.html)
Rangel, AntonioWe study the neural basis of economic decision-making using tools from cognitive neuroscience and experimental economics.Lab (http://www.rnl.caltech.edu/publications/index.html) +
The tools that we use include functional magnetic resonance imaging, transcranial magnetic stimulation, and eye tracking.
The research team includes neuroscientists, psychologists, and economists. (http://www.rnl.caltech.edu/)
Shimojo, We would like to understand how the brain adapts real-world constraints to resolve perceptual ambiguity and to reach Lab (http://neuro.caltech.edu/page/publications/) =
Shinsuke ecologically valid, unique solutions (https://neuro.caltech.edu/)
Siapas, Thanos Our research focuses on the study of information processing across networks of neurons, with emphasis on the neuronal Google +
mechanisms that underlie learning and memory formation. (http://www.cns.caltech.edu/people/faculty/siapas.html) (https://scholar.google.com/citations?hl=en&user=xDF_m1EAAAAJ&view
_op=list_works&sortby=pubdate)
Sternberg, PaulWe measure gene expression by RNA-seq and transgenic reporters; we measure behavior using automated systems and Lab (http://wormlab.caltech.edu/Publications) +
optogenetics. We focus on intercellular signals and their transduction by the responding cell into transcriptional
outputs. Many of the genes we have identified are the nematode counterparts of human genes, and we expect that some of
our findings will apply to human genes as well. (http://wormlab.caltech.edu/)
Tsao, Doris Segmentation (Our lab is pursuing the neural mechanisms underlying segmentation through a variety of approaches includingLab (https://www.tsaolab.caltech.edu/publications/) +
mathematical modeling and development of new experimental models for study of visual segmentation), Recognition,
Consciousness, Space, Tools such as ultrasonic neuromodulation, ultrasonic chemogenetics, and high-channel count
electrophysiology. (https://www.tsaolab.caltech.edu/)
Winfree, Erik Biomolecular computation, DNA based computation, algorithmic self-assembly, in vitro biochemical circuits, noise and Google +
fault-tolerance, DNA and RNA folding, evolution. (http://www.dna.caltech.edu/~winfree/) or (https://scholar.google.com/citations?hl=en&user=5GQF2FwAAAAJ&page
(http://molecular-programming.org/) size=100&view_op=list_works&sortby=pubdate)
Yue, Yisong Yisong Yue's research interests lie primarily in the theory and application of statistical machine learning. He is more Lab (http://www.yisongyue.com/) +
generally interested in artificial intelligence. Currently, he is particularly interested in learning with humans in the
loop, interactive learning systems, and spatiotemporal reasoning (http://www.yisongyue.com/)
 
 
 
Stanford University
 
- MBCT (https://neuroscience.stanford.edu/mbct/home)
- Neurosciences Ph.d., GREs no longer used. (https://med.stanford.edu/neurogradprogram/prospective_students.html)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
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├────────────────┼──────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼────────────────────────────────────────────────────────┼────┤
Airan, Raag precisely deliver drugs to the brain, to mediate more precise control of neural activity, in addition to other therapeutic effectsLab (http://airan-lab.stanford.edu/publications/) =
(http://airan-lab.stanford.edu/)
Baccus, Stephen (Brain-Machine Interfaces,Neuro-circuit interventional research consortium for understanding the brain and improving treatment) WeGoogle +
A. study how the circuitry of the retina translates the visual scene into electrical impulses in the optic nerve...experimental data (https://scholar.google.com/scholar?as_ylo=2017&q=baccus
is used to create mathematical models to predict and explain the output of the retinal circuit. +stephen+a&hl=en&as_sdt=0,5)
(https://baccuslab.sites.stanford.edu/)
Chichilnisky, The goal of our research is to understand how the neural circuitry of the retina encodes visual information, and to use this Lab +
E.J. knowledge in the development of artificial retinas for treating incurable blindness (http://med.stanford.edu/neurosurgery/research/chichilni
(http://med.stanford.edu/neurosurgery/research/chichilnisky.html) sky/publications.html)
Clandinin, My lab seeks to understand how the brain computes at the cellular and molecular level (https://flyvisionlab.weebly.com/) Lab (https://flyvisionlab.weebly.com/publications.html) +
Thomas
Druckmann, ShaulWe seek to relate circuit dynamics to computation by understanding the unique computational style used by the brain Lab (https://www.druckmannlab.com/publications.html) +
(https://www.druckmannlab.com/)
Etkin, Amit we collaborate with neuroscientists, engineers, psychologists, physicians and others to establish a new intellectual, scientific Lab (http://www.etkinlab.stanford.edu/publications) +
and clinical paradigm for understanding and manipulating human brain circuits in healthy individuals and for treating psychiatric
disease (http://www.etkinlab.stanford.edu/research-1)
Ganguli, Surya we exploit and extend tools and ideas from a diverse array of disciplines, including statistical mechanics, dynamical systems Lab (http://ganguli-gang.stanford.edu/pubs.html) +
theory, machine learning, information theory, control theory, and high-dimensional statistics, as well as collaborate with
experimental neuroscience laboratories collecting physiological data from a range of model organisms, from flies to humans
(http://ganguli-gang.stanford.edu/index.html)
Gardner, Justin Using knowledge of the visual system and decision theoretical models of how behavior is linked to cortical activity, we seek to Lab +
understand the cortical computations that construct human vision (http://gru.stanford.edu/doku.php/shared/research) (http://gru.stanford.edu/doku.php/shared/publications)
Ghajar, Jashmid improve the diagnosis and treatment of TBI. To do this, we lead the way in cutting-edge clinical research spanning the spectrum Lab (https://www.braintrauma.org/pages/publications) =
MD, FACS from concussion to coma (https://www.braintrauma.org/research)
Giocomo, Lisa Giocomo Lab integrates electrophysiology, behavior, imaging, gene manipulations, optogenetics and computational modeling to study Lab (https://giocomolab.weebly.com/publications.html) +
how single-cell biophysics and network dynamics interact to mediate spatial memory and navigation (https://giocomolab.weebly.com/)
Grill-Spector, Our research utilizes functional imaging (fMRI), computational techniques, and behavioral methods to investigate visual Lab (http://vpnl.stanford.edu/publications.htm) +
Kalanit recognition and other high-level visual processes (http://vpnl.stanford.edu/)
Gross, James (Psychology) The goal of this project is to create a computational model that will help us understand the unfolding of emotions atLab (https://spl.stanford.edu/selected-publications) +
the group level (collective emotion) and to correlate this model with real life events (https://spl.stanford.edu/projects-0)
Holmes, Susan We use computational statistics, multitable and nonparametric methods such as the bootstrap and MCMC computation of complex Lab (http://statweb.stanford.edu/~susan/papers.html) +
posterior distributions to draw inferences about complex biological phenomena (http://statweb.stanford.edu/~susan/LabIndex.html)
Huguenard, John Our approach is an analysis of the discrete components that make up thalamic and cortical circuits, and reconstitution of Lab +
components into both in vitro biological and in silico computational networks (https://huguenard-lab.stanford.edu/wp1/) (https://huguenard-lab.stanford.edu/wp1/publications/)
Knutson, Brian (NeuroChoice), Neural circuit dynamics of drug action (http://stanford.edu/group/spanlab/Projects/projects.html) Lab +
(http://stanford.edu/group/spanlab/Publications/publicat
ions.html)
Lee, Jin Hyung The Lee Lab uses interdisciplinary approaches from biology and engineering to analyze, debug, and manipulate systems-level brain Lab +
circuits (https://neuroscience.stanford.edu/people/jin-hyung-lee) (https://profiles.stanford.edu/jin-hyung-lee?tab=publica
tions)
Luo, Liqun Organization and function of neural circuits in the mouse and Developing genetic tools to probe neural circuit assembly and Lab +
organization (http://web.stanford.edu/group/luolab/Research.shtml) (http://web.stanford.edu/group/luolab/Publications.shtml
)
McClelland, Jay ...the primary current focus is on mathematical cognition from Parallel and Distributed Processing site Lab (https://stanford.edu/~jlmcc/papers/) +
(https://stanford.edu/~jlmcc/)
Newsome, WilliamComputer modelling techniques are then used to develop more refined hypotheses concerning the relationship of brain to behavior Lab (http://monkeybiz.stanford.edu/pubs.html) +
that are both rigorous and testable. This combination of behavioral, electrophysiological and computational techniques provides a
realistic basis for neurophysiological investigation of cognitive functions such as perception, memory and motor planning
(http://monkeybiz.stanford.edu/index.html)
Norcia, Anthony Brain mechanisms underlying face and text processing...methods for exploiting the temporal resolution of the EEG to study the Lab (https://svndl.stanford.edu/research/publications) =
dynamics of brain processing... (https://svndl.stanford.edu/research)
Poldrack, Our lab uses the tools of cognitive neuroscience to understand how decision making, executive control, and learning and memory areGoogle +
Russell implemented in the human brain. We also develop neuroinformatics tools and resources to help researchers make better sense of (https://scholar.google.com/citations?user=RbmLvDIAAAAJ&
data. (https://poldracklab.stanford.edu/) hl=en)
Raymond, The goal of our research is to understand the algorithms the brain uses to learn (http://raymondlab.weebly.com/) Lab (http://raymondlab.weebly.com/publications.html) +
Jennifer L.
Schnitzer, Mark Development of high-throughput, massively parallel imaging techniques for studying brain function in large numbers of Drosophila Lab (http://pyramidal.stanford.edu/publications.html) +
J. concurrently (http://pyramidal.stanford.edu/)
Shenoy, Krishna (BMIs), conducts neuroscience, neuroengineering and translational research to better understand how the brain controls movement, Lab (https://shenoy.people.stanford.edu/journal-papers) +
and to design medical systems to assist people with paralysis (https://shenoy.people.stanford.edu/overview)
Soltesz, Ivan We are interested in how brain cells communicate with each other in the normal brain, and how the communication changes in Lab +
epilepsy ... highly realistic large-scale supercomputational modeling approaches (http://med.stanford.edu/ivansolteszlab/front-page.html#
(http://med.stanford.edu/ivansolteszlab/front-page.html) publications)
Wagner, Anthony Current research directions – which combine behavior, brain imaging, virtual reality, and computational approaches Lab +
D (https://memorylab.stanford.edu/) (https://memorylab.stanford.edu/publications/2010-curren
t)
Williams, Leanne...Biomedical data sciences and informatics are also essential, not only because of the amount of data we generate, but also Lab (http://williamspanlab.com/publications) +
because we rely on increasingly sophisticated computational models to understand such complex phenomena as the brain and
depression (http://williamspanlab.com/)
Yamins, Daniel Our research lies at intersection of neuroscience, artificial intelligence, psychology and large-scale data analysis. We seek to Lab (http://neuroailab.stanford.edu/publications.html) +
"reverse engineer" the algorithms of the brain, both to learn about how our minds work and to build more effective artificial
intelligence systems (http://neuroailab.stanford.edu/)
 
 
 
University of California, Berkeley
 
- Theoretical Neuroscience (https://redwood.berkeley.edu/people/)
- Neuroscience Ph.D., GRE: Institution: 4833, Department: 0213 (http://neuroscience.berkeley.edu/ph-d-program/)
- Vision Science Ph.D., Apply, GRE: Institution: 4833, Department: 0611 (https://vision.berkeley.edu/admissions)
- Electrical Engineering and Computer Sciences, Ph.D., GRE: Institution(4833), Department(Not required) (https://eecs.berkeley.edu/academics/graduate/research-programs/admissions)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
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├──────────────┼─────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼───────────────────────────────────────────────────────────────────┼────┤
Banks, Martin Visual space perception and sensory combination (http://bankslab.berkeley.edu/) Lab (http://bankslab.berkeley.edu/publications/index.html) +
Bouchard, How distributed neural circuits give rise to coordinated behaviors and perception Google +
Kristofer (https://redwood.berkeley.edu/people/kristofer-bouchard/) (https://scholar.google.com/citations?hl=en&user=mDvGOLkAAAAJ&view_
op=list_works&sortby=pubdate)
Carmena, Jose Neural basis of motor skill learning. Application to neural prostheses and development of neural dust technology Google
(https://neuroscience.berkeley.edu/faculty/) (https://scholar.google.com/citations?user=qyF6UhQAAAAJ&hl=en&oi=ao
)
Collins, Anne Computational modeling of human learning, decision-making, and executive functions.... Computational modeling lets us Lab +
precisely and quantitatively define theories, make explicit predictions, and investigate how well different information (https://www.ocf.berkeley.edu/~acollins/pages/publications.html)
representations work in different environments. Computational modeling may also provide a link to the mechanistic
implementation of processes. (https://www.ocf.berkeley.edu/~acollins/)
Cooper, Emily Computational modeling of visual perception...We study the statistics of natural images and examine their relevance for Lab (http://www.emilyacooper.org/publications.html) +
visual coding and perception (http://www.emilyacooper.org/research.html)
Dan, Yang Neural circuits controlling sleep; mechanisms of executive control... (http://mcb.berkeley.edu/faculty/NEU/dany) Google +
(https://scholar.google.com/citations?hl=en&user=8dea7mQAAAAJ&view_
op=list_works&sortby=pubdate)
DeWeese, Mike experimental and theoretical neuroscience (https://redwood.berkeley.edu/people/mike-deweese/) Google +
(https://scholar.google.com/citations?hl=en&user=DZ9-LmkAAAAJ&view_
op=list_works&sortby=pubdate)
Feinberg, MRI technology development, mapping columnar and visual circuitry, modeling neurovascular coupling. +
David
Gallant, Jack Identifying cortical maps to discover how the brain represents information about the world and its own mental states... Google +
To address this problem, our laboratory makes heavy use of an inductive scientific approach called system identification. (https://scholar.google.com/citations?user=nSZG-vcAAAAJ&hl=en)
System identification is a systematic approach for discovering the computational principles of an unknown system such as
the brain. (http://gallantlab.org/)
Li, Lexin Neuroimaging data analysis: brain connectivity and network analysis, imaging causal inference, imaging genetics, Google +
longitudinal imaging analysis, multi-modality analysis, tensor analysis; Statistical genetics, computational biology; (https://scholar.google.com/citations?hl=en&user=JTwOVhEAAAAJ&view_
Dimension reduction, variable selection, high dimensional regressions; Statistical machine learning, data mining, op=list_works&sortby=pubdate)
computational statistics (http://lexinli.biostat.berkeley.edu/)
Maharbiz, Building micro- and nano- scale machine interfaces to cells and organisms, including development of neural dust Lab (https://maharbizgroup.wordpress.com/publications/) +
Michel technology. (maharbizgroup.wordpress.com)
Olshausen, Developing new theoretical frameworks and models of vision (https://redwood.berkeley.edu/people/bruno-olshausen/) Lab (http://www.rctn.org/bruno/papers/) +
Bruno
Sommer, Theoretical principles of learning and perception.My lab investigates the theoretical principles of learning and Google +
Friedrich perception and their biological bases in the circuit dynamics of the brain. To study these issues we develop (https://scholar.google.com/citations?hl=en&user=lA-oLkgAAAAJ&view_
computational models of the brain, as well as advanced techniques of data analysis op=list_works&sortby=pubdate)
(http://www.rctn.org/wiki/Fritz_Sommer#Research_Interests)
Theunissen, The overarching goal of our laboratory is to understand how complex natural sounds such as human speech, music and animalLab (http://theunissen.berkeley.edu/publications.html) +
Frédéric vocalizations are detected and recognized by the brain...We use computational methods in neuroscience to generate
theories of audition, to study sounds and to analyze our neural data (http://theunissen.berkeley.edu/)
 
 
 
University of California, Davis
 
- Computational Neuroscience (https://neuroscience.ucdavis.edu/computational)
- Neuroscience, GRE: Institution(4834), Dept(None specified), GRE Subject test encouraged (...) (https://grad.neuroscience.ucdavis.edu/apply)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
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├────────────────┼───────────────────────────────────────────────────────────────────────────────────────────────────────────────┼───────────────────────────────────────────────────────────────────────────┼────┤
Antzoulatos, large-scale neural networks that implement cognitive functions Google +
Evangelos (https://neuroscience.sf.ucdavis.edu/people/evangelos-antzoulatos) (https://scholar.google.com/citations?hl=en&user=cMIRlNwAAAAJ&view_op=list_
works&sortby=pubdate)
DeBello, Williamcomplete wiring diagram of local circuits in the barn owl auditory localization pathway +
(https://neuroscience.ucdavis.edu/people/william-debello)
Ditterich, bridging this gap by utilizing both behavioral and neurophysiological methods and by using mathematical models Google +
Jochen for exploring potential neural mechanisms (https://neuroscience.ucdavis.edu/people/jochen-ditterich) (https://scholar.google.com/scholar?as_ylo=2018&q=Ditterich,+Jochen&hl=en&a
s_sdt=0,5)
Goldman, Mark wide variety of systems and seek to address questions ranging from cellular and network dynamics to sensory Google +
coding to memory and plasticity (https://neuroscience.ucdavis.edu/people/mark-goldman) (https://scholar.google.com/scholar?as_ylo=2018&q=Goldman,+Mark+uc+davis&hl
=en&as_sdt=0,5)
Hanks, Tim We use the knowledge gained from these experiments to develop and constrain circuit-level descriptions of the Google +
computations that underlie decision making. (https://neuroscience.ucdavis.edu/people/tim-hanks) (https://scholar.google.com/citations?hl=en&user=a2nnsrAAAAAJ&view_op=list_
works&sortby=pubdate)
Nord, Alex (Brain Disease, Disorders), To that end, I perform both experimental work and computational analysis to reveal Google +
function of primary DNA sequence, epigenomic modifications, and chromatin structure (https://scholar.google.com/citations?hl=en&user=_FbUThYAAAAJ&view_op=list_
(https://neuroscience.ucdavis.edu/people/alex-nord) works&sortby=pubdate)
Usrey, W. MartinStructure, Function and Development of Neural Circuits for Vision Google +
(Chair) (https://neuroscience.ucdavis.edu/people/w-martin-usrey) (https://scholar.google.com/scholar?as_ylo=2018&q=Usrey+uc+davis&hl=en&as_s
dt=0,5)
 
 
 
University of California, Irvine
 
- Admission to UCI Cognitive Sciences Ph.D. program. GRE general test required to: 4859 (https://www.cogsci.uci.edu/graduate/program.php#apply)
 
(#contents)
 
 
 
PI(Ph.D.s) Department Research Areas Research +/=/
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├────────────────┼────────────────────────┼────────────────────────────────────────────────────────────────────────────────┼─────────────────────────────────────────────────────────────────────────────────┼────┤
Bornstein, AaronCognitive Sciences The lab's ongoing research investigates the influence of memories on behavior. Google +
M. Specific projects in progress examine the roles of episodic and working memory (https://scholar.google.com/citations?hl=en&user=ltlh6LQAAAAJ&view_op=list_works&
in decisions for reward, perceptual inference, drug choice and addiction, and sortby=pubdate)
intertemporal choice, using computational model-driven analysis of behavior and
brain activity (via fMRI, but with plans for EEG and other methods).
(http://aaron.bornstein.org)
Brewer, Alyssa Cognitive Sciences Our primary areas of research are fundamental visual system organization, visualGoogle +
adaptation and plasticity, and neurodegeneration. The tools we use for our (https://scholar.google.com/citations?hl=en&user=00yn31kAAAAJ&view_op=list_works&
investigations include magnetic resonance imaging (MRI), functional MRI (fMRI), sortby=pubdate)
diffusion tensor imaging (DTI), psychophysics, genetic assays,
psychopharmacology, mathematical modeling, and surveys.
(http://www.socsci.uci.edu/~aabrewer)
Chernyak, Nadia Cognitive Sciences Our specific research topics include the development of fairness and prosocial Lab (https://www.dosclab.com/publications) -
behavior, how we learn from choice and agency, the development of prospection
(future-oriented thinking), and how our social contexts and cognitive
competencies shape our emerging world views. We typically conduct behavioral
studies with young children and adults. (https://www.dosclab.com/)
Chubb, Charlie Cognitive Sciences Research analyzing camouflage: strategies in nature, how to make it and how to Google +
break it; A technique to compare the effects of stimulus salience across sensory(https://scholar.google.com/citations?hl=en&user=OlFlu1oAAAAJ&view_op=list_works&
properties and tasks; Research exploring how and why the time to initiate a sortby=pubdate)
response increases with the number of possible choices; Research that explores
two functions relating movement speed and accuracy, their generality, and the
mechanisms that underlie them; Visual and auditory experiments aimed at figuring
out what sorts of variations in physical energy are spontaneously discriminated
by human observers. (https://cwlab.ss.uci.edu/research-areas/)
D'Zmura, MichaelCognitive Sciences The Cognitive NeuroSystems Lab at UC Irvine conducts research on vision, hearingGoogle +
and EEG studies of speech and attention; past work includes studies of search (https://scholar.google.com/citations?hl=en&user=eci4MtQAAAAJ&view_op=list_works&
and navigation in 4D virtual environments. (http://cnslab.ss.uci.edu/) sortby=pubdate)
Dosher, Barbara Cognitive Sciences Memory in humans, with emphasis on forgetting and retrieval in explicit and Google +
implicit memory; Attention processes and their consequences for perceptual (https://scholar.google.com/scholar?as_ylo=2015&q=%22BA+Dosher%22&hl=en&as_sdt=0,
efficiency in information processing; How training in perceptual tasks improves 5)
visual performance and its use in cognitive rehabilitation
(https://www.socsci.uci.edu/maplab/index.html)
Grossman, Emily Cognitive Sciences The VPNL uses a combination of functional magnetic resonance imaging (fMRI), Lab (https://vpnl.ss.uci.edu/publications/pubs/) +
transcranial magnetic stimulation (TMS), concurrent TMS and
electroencephalography (EEG), and psychophysical techniques to isolate the
neural correlates of visual perception. (https://vpnl.ss.uci.edu/)
Hickok, Gregory Cognitive Sciences Our interests include psycholinguistics, neuropsychology (aphasia, lesion, Wada,Google +
developmental disorders), MEG, and fMRI. Recent work has focused on developing (https://scholar.google.com/citations?hl=en&user=wdxCzXoAAAAJ&view_op=list_works&
an integrative neurocomputational model of speech production, drawing on sortby=pubdate)
constructs from (psycho) linguistics, motor control, neuropsychology, and
cognitive neuroscience. (https://sites.uci.edu/alns/)
Hoffman, Donald Cognitive Sciences, machine and human vision, visual recognition, artificial intelligence, virtual CV (http://cogsci.uci.edu/~ddhoff/publications.pdf) +?
D. Logic and Philosophy of reality, consciousness and cognition, shape from motion
Science (http://www.cogsci.uci.edu/~ddhoff/)
Krichmar, Cognitive Sciences In the Cognitive Anteater Robotics Laboratory (CARL) at the University of Lab (https://www.socsci.uci.edu/~jkrichma/publications.html) +
Jeffrey California, Irvine, we are designing robotic systems whose behaviors are guided
by large-scale simulations of the mammalian brain. Because these simulated
nervous systems are embodied on a robot, they provide a powerful tool for
studying brain function. Moreover, because these cognitive robots are embedded
in the real-world, the system's behavior and function can be tested similarly to
that of an animal under experimental conditions.
(https://www.socsci.uci.edu/~jkrichma/CARL/)
Lee, Michael Cognitive Sciences My research involves the development, evaluation, and application of models of Google +
cognition including representation, memory, learning, and decision making, with (https://scholar.google.com/citations?hl=en&user=gbY_w1IAAAAJ&view_op=list_works&
a special focus on individual differences and collective cognition. Much of my sortby=pubdate)
research uses naturally occurring behavioral data, and tries to pursue a
solution-oriented approach to empirical science, in which the research questions
are generated from real-world problems. My methods involve probabilistic
generative modeling, and Bayesian methods of computational analysis.
(https://faculty.sites.uci.edu/mdlee/)
Liljeholm, Mimi Cognitive Sciences Our approach is multidisciplinary, drawing on a wide range of methods from Lab (https://faculty.sites.uci.edu/LDNLab/publications/) +
psychology, neuroscience, economics, statistics and machine learning. In
particular, we combine innovative experimental designs with computational
cognitive modeling and functional MRI, to develop formal accounts of neural and
psychological processes. (https://faculty.sites.uci.edu/LDNLab/)
Mednick, Sara Cognitive Sciences We are specifically interested in translational research questions that lead to Lab (http://sleepandcognitionlab.org/#publications) +
improving the lives of people with cognitive impairments. To accomplish this
work, we utilize electroencephalography (EEG) and functional magnetic resonance
imaging (fMRI) to measure brain activity during sleep and wake. We also use
pharmacology and brain stimulation during sleep to improve waking performance.
In addition, we use signal processing and computational modeling to reveal
patterns in the data not available to the naked eye.
(http://sleepandcognitionlab.org/)
Narens, Louis Cognitive Sciences, measurement, logic, metacognition (http://www.imbs.uci.edu/~lnarens/narens.html)Google +
Logic and the Philosophy (https://scholar.google.com/citations?hl=en&user=4wB25lAAAAAJ&view_op=list_works&
of Science sortby=pubdate)
Neftci, Emre Cognitive Sciences Bridge ML and neuroscience (Lifelong learning machines); Extracting information Lab (http://www.nmi-lab.org/pubs_by_name/) +
from unlabeled data; scalable neuromorphic learning machines; On-line,
spike-based deep learning and Stochastic Spiking Neural Networks
(http://www.nmi-lab.org/research-topics/)
Pearl, Lisa Language Science, The main technique of investigation we use is empirically-grounded computationalLab -- winner of most organized publications +
Cognitive Sciences modeling, drawing on constraints from realistic examples of human language and (https://www.socsci.uci.edu/~lpearl/CoLaLab/publications.html)
what we know about how humans process language information. Complementary
techniques include psycholinguistic methodologies to assess knowledge in
children and adults, and human computation methodologies for gathering realistic
samples of language use and interpretation.
(https://www.socsci.uci.edu/~lpearl/CoLaLab/index.html)
Peters, Megan Cognitive Sciences we use neuroimaging and computational modeling to study how brains represent andLab (https://neurocomp.engr.ucr.edu/publications.html) +
use uncertain information and uncertainty itself
(https://neurocomp.engr.ucr.edu/)
Pizlo, Zygmunt Mathematical Psychology,Our group is studying mental mechanisms (algorithms) involved in cognitive Google +
Cognitive Sciences functions. More precisely, we study those cognitive functions that are (https://scholar.google.com/citations?hl=en&user=63Oe0c8AAAAJ&view_op=list_works&
computationally difficult. A cognitive function is computationally difficult if sortby=pubdate)
there is currently no algorithm that can perform this function equally well as
the human mind does. This definition includes a lot: perception of shape,
motion, color, depth, language understanding, speech recognition, reading, motor
control, visuomotor coordination, learning, thinking, problem solving. By
studying computationally difficult cognitive functions, we hope to contribute to
both: psychology, by understanding cognitive mechanisms, and artificial
intelligence, by formulating smart algorithms.
(http://bigbird.psych.purdue.edu/index.html)
Richards, Cognitive Sciences My research interests include human perception, cognition, and mathematical Google +
Virginia psychology as applied to the perception of complex sounds. Using psychophysical (https://scholar.google.com/scholar?as_ylo=2015&q=%22VM+Richards%22&hl=en&as_sdt=
techniques, we study the rules governing low-level auditory processing and the 0,5)
possible mechanisms by which multiple sound sources are segregated. Recent work
has been aimed at the development and testing of multiple-channel models of
masking that depend on both energetic and temporal aspects of complex sounds. At
present, the goal is to extend this work into the realm of perceptual
organization, including "auditory streaming" and the detection of a target
pattern of sounds against a background of distracter sounds. Both psychophysical
experiments and the allied processing models depend on digital signal processing
techniques in which acoustical features are independently varied, allowing the
determination of the relative contribution of the different cues as well as the
underlying combination rules. (http://hearlab.ss.uci.edu/)
Rouder, Jeffrey Mathematical Psychology We develop new statistical methods to address long-standing questions in Google +
(chair), Cognitive cognitive psychology. Our substantive interests are in attention, cognitive (https://scholar.google.com/citations?hl=en&user=W5inQnkAAAAJ&view_op=list_works&
Sciences control, perception, intelligence, and learning; our methodological interests sortby=pubdate)
are in Bayesian hierarchical statistical and process models.
(https://sites.uci.edu/specl/)
Saberi, Kourosh Cognitive Sciences We draw from a number of scientific disciplines that include cognitive sciences,Google +
neuroscience, computer science, physics, and philosophy. This interdisciplinary (https://scholar.google.com/scholar?hl=en&as_sdt=0%2C5&as_ylo=2015&q=Kourosh+Sabe
approach allows us to capture converging expertise in exploring fundamental ri&btnG=)
questions in the study of consciousness and the nature of reality. We use
empirical, theoretical, and computational techniques in our investigations.
(http://www.conscioussystemslab.com/)
Sarnecka, Cognitive Sciences Much of my work over the past 20 years has been about how young children acquireGoogle +?
Barbara number concepts. But in recent years, I've branched out to work on social (https://scholar.google.com/citations?hl=en&user=sH0pY84AAAAJ&view_op=list_works&
cognitive development, the development of judgment and decision making, adult sortby=pubdate)
moral psychology, and most recently, scientific writing. (Developing and testing
ways to help PhD students and other scientists increase their productivity and
write more clearly.)
(https://sites.google.com/uci.edu/sarneckalab/people/barbara-w-sarnecka?authuser
=0)
Srinivasan, Cognitive Sciences Our working hypothesis is that cognition involves the interaction between local Google +
Ramesh processes in specific regions of the cortex and global brain networks. We carry (https://scholar.google.com/citations?hl=en&user=opgkEvkAAAAJ&view_op=list_works&
out experimental studies using EEG, MEG, TMS, and fMRI on visual and auditory sortby=pubdate)
perception and attention, and we use volume conduction and dynamic models to
elucidate the neural mechanisms underlying our findings.
(http://hnl.ss.uci.edu/)
Steyvers, Mark Cognitive Sciences Learning & Memory; Cognitive Skill Acquisition; Metacognition; Hybrid Google +
human-machine algorithm systems; Wisdom of crowds; Bayesian computational (https://scholar.google.com/citations?hl=en&user=szUb_isAAAAJ&view_op=list_works&
modeling; Machine learning; Joint models for behavior and neuroimaging data sortby=pubdate)
(https://steyvers.socsci.uci.edu/)
Vandekerckhove, Cognitive Sciences Current projects include quantitative modeling of cognition and individual Lab (http://www.cidlab.com/publications.php) +
Joachim differences, Bayesian statistics, and implementation and deployment of useful
computational algorithms. I am also interested in quantitative approaches of
detecting and undoing some of the societal challenges currently faced by
psychological science (such as publication bias, fraud detection, and closed
access to scientific literature) and in new design and analysis methods.
(http://www.cidlab.com/research-topics.php)
Wright, Charles Cognitive Sciences See Chubb, Charlie (https://cwlab.ss.uci.edu/research-areas/) Google +
E. (Ted) (https://scholar.google.com/citations?hl=en&user=EvHWeysAAAAJ&view_op=list_works&
sortby=pubdate)
 
 
 
University of California, Los Angeles
 
- Admission to UCLA Interdepartmental Ph.D. program in Neuroscience. GRE general test required to: R4837 Field code: 0213 (http://neuroscience.ucla.edu/admissions)
 
(#contents)
 
 
 
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├────────────────┼────────────────────────────┼─────────────────────────────────────────────────────────────────────────────────────────┼────────────────────────────────────────────────────────────────────┼────┤
Adhikari, Psychology, Brain Reasearch We have discovered neural circuits in mice that control specific symptoms of high anxietyPubMed (https://www.ncbi.nlm.nih.gov/pubmed/?term=avishek+adhikari) +
Avishek Institute states, such as avoidance of risk and increases in heart rate. We also showed how the
flow of neural activity in brain circuits control anxiety.
(https://adhikarilab.psych.ucla.edu/)
Basso, Michele Semel Institute for Dr. Basso's work is aimed at understanding how the brain combines memory and sensory Google +
A. Neuroscience and Human information to guide decisions and how these processes are impaired in diseases. (https://scholar.google.com/citations?hl=en&user=YmmvnoYAAAAJ&view_o
Behavior, BRI (http://neuroscience.ucla.edu/profile/basso-michele) p=list_works&sortby=pubdate)
Bisley, James Neurobiology, BRI Dr. Bisley’s research interests revolve around the cognitive processing of visual Google +
information, with particular foci on understanding the neural mechanisms underlying the (https://scholar.google.com/scholar?as_ylo=2018&q=james+bisley&hl=en
guidance of visual attention, the guidance of eye movements and spatial stability. His &as_sdt=0,5)
lab has also studied visual working memory and he has been involved in implementing
haptic feedback for surgical robotics.
(http://neuroscience.ucla.edu/profile/bisley-james)
Buonomano, Dean Behavioral Neuroscience, Our research focuses on how neural circuits learn and perform complex computations--such Lab (http://www.buonomanolab.com/publications) +
Neurobiology, BRI as telling time and temporal processing. Towards this goal our lab uses
electrophysiological, optogenetic, computational, and psychophysical techniques.
(http://www.buonomanolab.com)
Golshani, PeymanNeurology, BRI The mission of our laboratory is to discover how changes in the excitability and Google +
connectivity of neuronal ensembles results in autism and developmental epilepsies. (https://scholar.google.com/citations?hl=en&user=H-e-YNUAAAAJ&view_o
(https://golshanilab.neurology.ucla.edu/) p=list_works&sortby=pubdate)
Hong, Weizhe Biological Chemistry, We aim to understand how social behavior is regulated at the molecular and circuit level Lab (http://www.hong-lab.com/publications.html) +
Neurobiology and how social behavior and social experience lead to molecular and circuit level changes
in the brain (http://www.hong-lab.com/)
Kao, Jonathan Electrical Engineering, BRI Our research group studies questions at the intersection of neuroscience and computation.Lab (https://seas.ucla.edu/~kao/pubs.html) +
In particular, we develop and apply statistical signal processing and machine learning
techniques to elucidate how populations of neurons carry out computations in the brain.
Further, we also develop experimental and algorithmic techniques for neural engineering
applications, including brain-machine interfaces. (https://seas.ucla.edu/~kao/)
Masmanidis, Neurobiology, BRI Key questions: What are the dynamics of neural microcircuits during reward-conditioned Lab (https://masmanidislab.neurobio.ucla.edu/publications.html) +
Sotiris behavior? What role does the activity of specific microcircuits play in
reward-conditioned behavior? How is neural activity and information processing disrupted
in models of brain disorders? (https://masmanidislab.neurobio.ucla.edu/)
Mehta, Mayank Physics and Astronomy, Key techniques: Develop hardware to measure and manipulate neural activity and behavior; Lab (http://www.physics.ucla.edu/~mayank/publications.html) +
Neurology,Neurobiology, BRI Measure the activity of ensembles of well isolated neurons from many hippocampal and
neocortical areas simultaneously during learning and during sleep; Develop data analysis
tools to decipher the patterns of neural activity and field potentials, and their
relationship to behavior; Develop biophysical theories of synapses, neurons and neuronal
networks that can explain these experimental findings, relate them to the underlying
cellular mechanisms, and make experimentally testable predictions.
(http://www.physics.ucla.edu/~mayank/)
Portera-CailliauNeurology, Neurobiology, BRIAutism; How are cortical circuits assembled during typical brain development? What are Lab (https://porteralab.dgsom.ucla.edu/pages/publications) +
, Carlos the underlying circuit defects in autism and intellectual disability? What are the best
ways to model neuropsychiatric symptoms? (https://porteralab.dgsom.ucla.edu/pages/)
Ringach, Dario Psychology, Behavioral Our research focuses on visual perception and neurophysiology. In particular, we are Google +
Neuroscience, Neurobiology, interested in cortical dynamics, circuitry, function, and mathematical modeling of the (https://scholar.google.com/citations?hl=en&user=V6xKYw4AAAAJ&view_o
BRI visual system. The main methods in the laboratory include multi-electrode recordings fromp=list_works&sortby=pubdate)
single neurons, as well as intrisic and voltage senstive dye imaging of visual cortex.
(http://neuroscience.ucla.edu/profile/ringach-dario)
Sharpe, Melissa Psychology The lab has a particular interest in how this model building goes awry in schizophrenia. Lab (https://sharpelab.psych.ucla.edu/publications/) +
J. People with schizophrenia are known to exhibit failures in associative learning,
characteristically learning to associate events that are not really related or may be
irrelevant. This is thought to contribute to the positive symptoms of the disorder, such
as hallucinations and delusions, as patients attempt to cognitively rationalize their
aberrant learning experience. As a lab, we want to uncover how dysfunction in particular
neural circuits contribute to these associative learning deficits, which ultimately lead
to positive symptoms of the disorder. The hope is that this work will provide the impetus
to develop novel therapeutic compounds targeting these neural circuits to improve quality
of life in patients. (https://sharpelab.psych.ucla.edu/)
Suthana, NanthiaNeurosurgery We focus on development of invasive and non-invasive methodologies to restore cognitive Lab (http://lonn.semel.ucla.edu/?page_id=53) =?
functions such as learning, memory and spatial navigation. This research program utilizes
methods of deep brain stimulation combined with intracranial recordings of single-unit
and local field potentials to characterize and develop neuromodulatory methods of memory
restoration in individuals with debilitating memory impairments.
(http://mentalhealth.ucla.edu/lonn/)
Trachtenberg, Neurobiology, BRI But how do novel sensory experiences embed themselves in the fabric of the brain to form Google =?
Joshua memories? This question drives the research in my laboratory, which examines the cellular(https://scholar.google.com/citations?hl=en&user=7KQc7SMAAAAJ&view_o
and synaptic mechanisms of experience-dependent plasticity in the neocortex p=list_works&sortby=pubdate)
(https://www.neurobio.ucla.edu/people/joshua-trachtenberg-phd)
Wikenheiser, Psychology Our lab studies how neural representations support behaviors like decision making. We Google +
Andrew approach this question by recording the electrical activity of neurons as rats perform (https://scholar.google.com/citations?hl=en&user=W1fYwRMAAAAJ&view_o
behavioral tasks. Electrophysiological techniques are augmented with optogenetics and p=list_works&sortby=pubdate)
computational analyses. (https://wikenheiserlab.psych.ucla.edu/)
 
 
 
University of California San Diego
 
- Neurograd program, GRE: Institution(4836) Department(0213), Specify interest in Computational Neuroscience specialization
(https://medschool.ucsd.edu/education/neurograd/prospective-students/Pages/default.aspx)
 
(#contents)
 
 
 
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├───────────────┼──────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼─────────────────────────────────────────────────────────────────┼────┤
Abarbanel, (physics) electrophysiological properties of neurons Google +
Henry (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/henry-abarbanel.aspx) (https://scholar.google.com/citations?hl=en&user=GutIbK0AAAAJ&vie
w_op=list_works&sortby=pubdate)
Albright, neural structures and events underlying the perception of motion, form, and color Lab =
Thomas (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/thomas-albright.aspx) (https://www.salk.edu/scientist/thomas-albright/publications/)
Asahina, Kenta ... employing ... CRISPR/Cas9 genome editing, manipulation of specific neural populations, 2-photon functional imaging, Lab (https://www.salk.edu/scientist/kenta-asahina/publications/) +
and machine vision-assisted behavioral analyses
(https://medschool.ucsd.edu/education/neurograd/faculty/Pages/kenta-asahina.aspx)
Bazhenov, we apply a variety of methods – quantitative experimental techniques, sophisticated mathematical analysis and large-scale Lab (https://www.bazhlab.ucsd.edu/publications/) +
Maksim computer modeling – to a variety of problems to reveal common features
(https://medschool.ucsd.edu/education/neurograd/faculty/Pages/Maksim-Bazhenov.aspx)
Cauwenberghs, VLSI microsystems for adaptive neural computation Google +
Gert (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/gert-cauwenberghs.aspx) (https://scholar.google.com/citations?hl=en&user=KZQz_7AAAAAJ&vie
w_op=list_works&sortby=pubdate)
Chalasani, ...interested in understanding how neural circuits sense and process information to generate behaviors Google +
Sreekanth (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/sreekanth-chalasani.aspx) (https://scholar.google.com/scholar?as_ylo=2018&q=chalasani+sreek
anth&hl=en&as_sdt=0,5)
Coleman, Todd Flexible bio-electronics, systems neuroscience, quantitative approaches to understand and augment brain function. Lab (http://coleman.ucsd.edu/publications) +
(https://medschool.ucsd.edu/education/neurograd/faculty/Pages/todd-coleman.aspx)
de Sa, VirginiaWe study the computational properties of machine learning algorithms and also investigate what physiological recordings Lab +
and the constraints and limitations of human performance tell us about how our brains learn (http://www.cogsci.ucsd.edu/academicPubs/desa/Publications.html)
(http://www.cogsci.ucsd.edu/~desa/)
Gentner, (Acoustic) We want to know how the brain represents behaviorally important, complex, natural stimuli Google +
Timothy (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/timothy-gentner.aspx) (https://scholar.google.com/citations?hl=en&user=s9_46JoAAAAJ&vie
w_op=list_works&sortby=pubdate)
Gilja, Vikash brain-machine interfaces (http://neuro.eng.ucsd.edu/people) Lab (http://neuro.eng.ucsd.edu/publications) +
Kleinfeld, network and computational issues within nervous systems Lab (http://neurophysics.ucsd.edu/journal_articles.php) +
David (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/david-kleinfeld.aspx)
Komiyama, neuronal ensembles in behaving animals, BCI, two-photon in vivo Lab +
Takaki (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/takaki-komiyama.aspx) (http://labs.biology.ucsd.edu/komiyama/html/publications.html)
Kristan, study vector calculations, coding/decoding, and control of gain Google +
William (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/william-klristan.aspx) (https://scholar.google.com/scholar?hl=en&as_sdt=0%2C5&as_ylo=201
8&q=Kristan%2C+William&btnG=)
Mishra, Jyoti Neurotechnology engineering studies in humans and animals to advance experimental diagnostics and therapeutics for Google +
neuropsychiatric disorders. (http://neatlabs.ucsd.edu/index.html) (https://scholar.google.com/citations?hl=en&user=ZUFLEBIAAAAJ&vie
w_op=list_works&sortby=pubdate)
Mukamel, Eran (Epigenomics) Research in our lab uses computational modeling and analysis of large-scale data sets to understand complex Lab (https://brainome.ucsd.edu/publications.html) +
A. biological networks, from the genome to brain circuits
(https://medschool.ucsd.edu/education/neurograd/faculty/Pages/eran-mukamel.aspx)
Navlakha, SaketAlgorithms in nature (http://www.algorithmsinnature.org/) Lab (http://www.snl.salk.edu/~navlakha/) +
Reinagel, computational models to explain reward-motivated choice behavior Lab (http://www.ratrix.org/Publications.html) +
Pamela (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/pamela-reinagel.aspx)
(One of the founders of Deep Learning)... To uncover linking principles from brain to behavior using computational Lab +
models...New techniques have been developed for modeling cell signaling using Monte Carlo methods (MCell)...new methods (http://papers.cnl.salk.edu/index.php?SearchText=Type=Article)
for analyzing sources for electrical and magnetic signals... from functional brain imaging by blind separation using
independent components analysis (ICA)
(https://medschool.ucsd.edu/education/neurograd/faculty/Pages/terrence-sejnowski.aspx)
Serences, John To investigate the influence of behavioral goals and previous experiences on perception and cognition, we employ a Google +
combination of psychophysics, computational modeling, and neuroimaging techniques (https://scholar.google.com/citations?hl=en&user=mSaemJkAAAAJ&vie
(https://medschool.ucsd.edu/education/neurograd/faculty/Pages/john-serences.aspx) w_op=list_works&sortby=pubdate)
Sharpee, Our approaches are often derived from methods in statistical physics, mathematics, and information theory Lab +
Tatyana (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/tatyana-sharpee.aspx) (http://papers.cnl-t.salk.edu/index.php?SearchText=Type=Article)
Silva, Gabriel (Ophthlmology) In particular, we are interested in the mechanisms that underlie signal and information propagation in Lab (http://www.silva.ucsd.edu/publications) +
biological cellular neural networks, and the computational potential of such networks in the brain
(http://www.silva.ucsd.edu/)
Stevens, mechanisms responsible for synaptic transmission Google +
Charles F. (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/charles-stevens.aspx) (https://scholar.google.com/scholar?as_ylo=2017&q=Charles+stevens
+salk&hl=en&as_sdt=0,5)
Störmer, Viola ...Cognitive and neural mechanisms of human perception, selective attention, and multisensory processing...to understand Lab (http://stoermerlab.ucsd.edu/publications) +
the computations and processes involved to process these diverse inputs, it is important to consider the full breadth of
incoming information (https://medschool.ucsd.edu/education/neurograd/faculty/Pages/viola-stormer.aspx)
Voytek, Bradleyfocused on combining large scale data-mining and machine-learning techniques with hypothesis-driven experimental research Lab (https://voyteklab.com/publications/) +
to understand the relationships between the human frontal lobes, cognition, and disease
(https://medschool.ucsd.edu/education/neurograd/faculty/Pages/bradley-voytek.aspx)
Yeo, Gene leader in developing the molecular and cellular resources and robust technologies required for truly large-scale studies Lab (http://yeolab.github.io/papers/) +
of hundreds of RNA binding proteins and their RNA targets
(https://medschool.ucsd.edu/education/neurograd/faculty/Pages/gene-yeo.aspx)
Yu, Angela J. Computational modeling and psychophysics of attention, learning, and decision-making Lab (http://www.cogsci.ucsd.edu/~ajyu/) +
(https://medschool.ucsd.edu/education/neurograd/faculty/Pages/angela-yu.aspx)
 
 
 
University of California, Santa Barbara
 
- DYNS (https://www.dyns.ucsb.edu/people)
- Graduate School application. Regardless of degree, preference will be given to applicants with undergraduate coursework in biology, chemistry, physics, and mathematics
(https://www.graddiv.ucsb.edu/eapp/Login.aspx)
 
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Ashby, Greg Psychological & Brain Sciences Dr. Ashby's approach is to collect a wide varity of empirical data (e.g., from Lab (https://labs.psych.ucsb.edu/ashby/gregory/publications) +
cognitive behavioral experiments, fMRI experiments, and studies with various
neuropsychological patient groups), and use these data to develop and test
neurobiologically detailed mathematical models
(https://www.dyns.ucsb.edu/people/ashby)
Carlson, Jean Physics The Complex Systems group at UCSB, headed by Physics professor Jean Carlson, Lab (http://web.physics.ucsb.edu/~complex/publications.html) +
investigates robustness, tradeoffs, and feedback in complex, highly connected
systems, and develops multi-scale models to capture important small-scale
details and predict large-scale behavior.
(http://web.physics.ucsb.edu/~complex/)
Chrastil, Liz Geography The focus of our research is understanding how the brain supports spatial Lab (https://chrastil.geog.ucsb.edu/node/9) +
navigation. We use virtual reality, fMRI, and EEG methods to test questions
about the nature of our spatial geometry, why individuals differ so much in
their navigational abilities, and how we acquire and use spatial knowledge.
(https://www.dyns.ucsb.edu/people/chrastil)
Eckstein, Psychological & Brain Sciences The Vision and Image Understanding Laboratory at the University of California, Google +
Miguel Santa Barbara pursues computational modeling of behavioral, cognitive (https://scholar.google.com/citations?hl=en&user=G5dQztgAAAAJ&view_op=list_
neuroscience and physiological data with the aim of elucidating the mechanisms works&sortby=pubdate)
and neural substrates mediating perception, attention and learning.
(https://labs.psych.ucsb.edu/eckstein/miguel/)
Gazzaniga, Psychological & Brain Sciences The Center integrates a wide range of scholarly endeavors and technologies in Google =?
Michael the humanities, social sciences and the sciences. These will include, for (https://scholar.google.com/citations?hl=en&user=jpVab-AAAAAJ&view_op=list_
example, the metaphysics and the philosophy of the mind; methodologies in the works&sortby=pubdate)
social and behavioral sciences; and the relatively recent tools that have been
developed in the sciences such as functional neuro-imaging, genetic techniques,
computational modeling and immersive virtual environment technology.
(https://www.sagecenter.ucsb.edu/about)
Giesbrecht, Psychological & Brain Sciences We use a combination of behavioral and neuroimaging techniques (EEG, fMRI) Lab +
Barry coupled with advanced analytical methods to systematically investigate the (https://labs.psych.ucsb.edu/giesbrecht/barry/Attention_Lab/Publications.ht
dynamics of the perceptual, cognitive, and neural mechanisms of selective ml)
attention. (https://www.dyns.ucsb.edu/people/giesbrecht)
Goard, Michael Molecular, Cellular, and To this end, my lab employs large-scale two-photon calcium imaging, multi-unit Lab (https://labs.mcdb.ucsb.edu/goard/michael/publications) +
Developmental Biology electrophysiology, and optogenetic manipulation of neural activity in behaving
mice. We then use computational approaches to analyze and interpret the data
collected from large populations of neurons.
(https://www.dyns.ucsb.edu/people/goard)
Grafton, Scott Psychological & Brain Sciences Our research emphasizes experiments that elucidate the underlying cognitive Google +
architecture that represents action and transforms intentions and goals into (https://scholar.google.com/citations?hl=en&user=7yJze9oAAAAJ&view_op=list_
specific movements...Data modeling approaches include conventional multivariate works&sortby=pubdate)
methods, machine learning and representational similarity. We also characterize
functional data using dynamic community detection algorithms.
(https://www.dyns.ucsb.edu/people/grafton)
Jacobs, Emily Psychological & Brain Sciences he Jacobs Lab is focused on understanding the extent to which sex steroid Lab (https://jacobs.psych.ucsb.edu/publications) =?
hormones shape the neural circuitry underlying higher order cognitive
functions... (https://jacobs.psych.ucsb.edu/)
Janusonis, Psychological & Brain Sciences The brain serotonin matrix and its interaction with other cellular elements; Lab (https://labs.psych.ucsb.edu/janusonis/skirmantas/publications.html) +
Skirmantas Stochastic processes driving the formation of the ascending reticular activating
system; The architectures of early vertebrate brains
(https://www.dyns.ucsb.edu/people/janusonis)
Kosik, Kenneth Molecular, Cellular, and The lab is interested in the underlying molecular basis of plasticity, Lab (https://ken-kosik.mcdb.ucsb.edu/publications) =?
Developmental Biology particularly how protein translation at the synapse affects learning and how
impairments of plasticity lead to neurodegenerative diseases.
(https://ken-kosik.mcdb.ucsb.edu/)
Louis, MatthieuMolecular, Cellular, and My lab seeks to reveal building blocks of neural computation underlying sensory Google +
Developmental Biology perception and adaptive decision making...Combining neuronal imaging and (https://scholar.google.com/citations?hl=en&user=UX3e9O0AAAAJ&view_op=list_
perturbation analysis through optogenetics, we generate mechanistic hypothesis works&sortby=pubdate)
about the neural implementation of navigational decisions.
(https://www.dyns.ucsb.edu/people/louis)
Madhow, Electrical and Computer Examples of ongoing projects include multiGigabit millimeter wave communication Lab (https://wcsl.ece.ucsb.edu/publications) =?
Upamanyu Engineering networks, novel architectures and hardware prototypes for very large scale
sensor networks, and target tracking using very simple sensors.
(https://wcsl.ece.ucsb.edu/people/upamanyu-madhow)
B.S. Manjunath Electrical and Computer Current research focus is on (a) integration of human and contextual informationLab +
Engineering in analyzing images and video, leading to bio-inspired methods for computer (https://vision.ece.ucsb.edu/publications/by-year?field_subject_tid=All&fie
vision; (https://vision.ece.ucsb.edu/) ld_author_value=&field_grant_tid=All&field_project_tid=All&field_lab_value=
All&field_target_value=All&nid=&field_pubid_value=&field_vrlid_value=&sortb
y=by-year&viewtype=)
Miller, MichaelPsychological & Brain Sciences His research employs a variety of techniques, including functional magnetic Lab (https://labs.psych.ucsb.edu/miller/michael/publications.html) =?
resonance imaging (fMRI), event-related potentials (ERP), transcranial magnetic
stimulation (TMS), split-brain studies, and signal detection analysis
(https://labs.psych.ucsb.edu/miller/michael/index.html)
Moehlis, Jeff Mechanical Engineering We have been developing procedures for determining an optimal electrical deep Google +
brain stimulus which desynchronizes the activity of a group of neurons by (https://scholar.google.com/citations?hl=en&user=qDFqGPQAAAAJ&view_op=list_
maximizing the Lyapunov exponent associated with their phase dynamics, work thatworks&sortby=pubdate)
could lead to an improved "brain control" method for treating Parkinson's
disease...Other research interests include the applications of dynamical systems
and control techniques to other neuroscience systems, cardiac dynamics, energy
harvesting, and collective behavior. (https://www.dyns.ucsb.edu/people/moehlis)
Montell, Craig Molecular, Cellular, and Using molecular genetic, optogenetic, thermogenetic, electrophysiological, Lab (https://labs.mcdb.ucsb.edu/montell/craig/publications) +?
Developmental Biology biochemical and cell biological approaches in the fruit fly, Drosophila
melanogaster, our laboratory is decoding the receptors, ion channels and
neuronal circuits that are critically important in allowing flies to sense the
outside world, and impact on decisions ranging from food selection to choosing
the ideal thermal landscape, mate selection and others.
(https://labs.mcdb.ucsb.edu/montell/craig/)
Simpson, Julie Molecular, Cellular, and How does the brain control behavior? We study the neural circuits that organize Google (https://labs.mcdb.ucsb.edu/simpson/julie/publications) +
Developmental Biology a flexible sequence of movements that remove dust from fruit flies.
(https://labs.mcdb.ucsb.edu/simpson/julie/)
Smith, Spencer Electrical and Computer We are exploring population dynamics with single cell resolution to elucidate Lab (http://slslab.org/#publications) +
L. Engineering principles of circuit architecture, dynamics, and computation. We are currently
using this technology to explore activity in primary and higher visual cortical
areas in mice...To explore cellular and population activity in a context in
which behaviorally relevant mechanisms are engaged, we have developed and
optimized insturmentation to explore quantitative psychophysical behavior guided
by complex visual stimuli...We are exploring the technological headroom in
several domains for developing new tools and techniques for neuroscience and
other biological applications. (http://slslab.org/)
Turk, Matthew Computer Science My primary research interests are in computer vision and imaging, human-computerLab (http://ilab.cs.ucsb.edu/publications) +
interaction, machine learning, and augmented reality. I'm also interested in
computation models of, and tools for, neuroscience. (http://ilab.cs.ucsb.edu/)
 
 
 
University of Oregon
 
- Computational and Systems Neuroscience (http://ion.uoregon.edu/content/cognitive-computational-and-systems-neuroscience-training-program)
 
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Ahmadian, (Theoretical Neuroscience)...understanding how large networks of neurons...process sensory inputs and give rise to higher-level Google +
Yashar cognitive functions through their collective dynamics on multiple time scales (http://ion.uoregon.edu/content/yashar-ahmadian) (https://scholar.google.com/citations?hl=en&user=ZDaT
hWgAAAAJ&view_op=list_works&sortby=pubdate)
Doe, Chris Assembly and function of neural circuits driving larval locomotion in Drosophila... interested in (1) temporal identity programs used Lab (http://www.doelab.org/recent-pubs.html) +
to generate an ordered series of neural progeny from a single progenitor, (2) how spatial patterning and temporal identity are
integrated to generate heritable neuronal identity, (3) how neuronal progenitors change competence to respond to intrinsic and
extrinsic cues over time, and (4) the developmental mechanisms driving neural circuit assembly, with a focus on larval locomotor
circuits and adult central complex circuits. (http://ion.uoregon.edu/content/chris-doe-0)
Huxtable, neural control of breathing (the central brainstem and spinal cord networks), with a specific focus on how inflammation ... undermines Lab (https://huxtable.uoregon.edu/publications/) =
Adrianne breathing (http://ion.uoregon.edu/content/adrianne-huxtable)
Lockery, Shawnnervous system controls behavior by analyzing the neural networks for decision making, focusing on spatial exploration behaviors, and Google +
food choice involving trade-offs that mimic human economic decisions (http://ion.uoregon.edu/content/shawn-lockery) (https://scholar.google.com/citations?hl=en&user=x4pa
az0AAAAJ&view_op=list_works&sortby=pubdate)
Mazzucato, Computational models of cortical network function. (https://www.mazzulab.com) Lab (https://www.mazzulab.com/publications.html) +
Luca
Miller, Adam Neural circuit wiring, synapse formation, and electrical synaptogenesis in zebrafish (http://ion.uoregon.edu/content/adam-miller) Lab (http://millerlab.brainbuild.org/publications) +
C.
Niell, Cris Function and development of neural circuits for visual processing (http://ion.uoregon.edu/content/cris-niell) +
Smear, Matt will pursue general principles of how neural circuits generate behavior (http://ion.uoregon.edu/content/matt-smear) Google +
(https://scholar.google.com/citations?user=nU455D0AAA
AJ&hl=en)
Swann, Nicki Studies the motor system in healthy people as well as patients with movement disorders (e.g. Parkinsons), using a combination of Lab (https://swannlab.uoregon.edu/publications/) +
invasive and non-invasive electrophysiology. (http://ion.uoregon.edu/content/nicki-swann)
Sylwestrak, understand how heterogeneous, molecularly-defined neuronal populations work together to drive behavior Lab (https://www.sylwestraklab.com/papers) =
Emily (http://ion.uoregon.edu/content/emily-sylwestrak)
Washbourne, Molecular mechanisms of synapse formation (http://ion.uoregon.edu/content/philip-washbourne) Lab =
Philip (https://blogs.uoregon.edu/washbournelab/publications
/)
Wehr, Michael How local circuits in the auditory cortex encode and transform sensory information (http://ion.uoregon.edu/content/michael-wehr) Lab +
(http://uoneuro.uoregon.edu/wehr/publications.html)
 
 
 
University of Southern California
 
- USC Neuroscience Graduate Program. GRE Average: 155(Verbal), 167(Quant), Institution(4852), Department(0213) (https://ngp.usc.edu/admissions/)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
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├───────────────┼─────────────────────────────────────────────────────────────────────────────────────────────────────────────┼──────────────────────────────────────────────────────────────────────────────┼────┤
Brocas, I combine economic theoretical modeling (optimization based, game theoretic based), computational approaches,Google +
Isabelle and a large variety of experimental methods. (https://dornsife.usc.edu/label/home/) (https://scholar.google.com/scholar?as_ylo=2018&q=isabelle+brocas&hl=en&as_sdt
=0,5)
Coricelli, Our objective is to apply robust methods and findings from behavioral decision theory to study the brain Google =
Giorgio structures that contribute to forming judgments and decisions, both in an individual and a social context (https://scholar.google.com/citations?hl=en&user=nEVZSJUAAAAJ&view_op=list_wor
(https://ngp.usc.edu/faculty/?faculty-profile=159) ks&sortby=pubdate)
Duncan, Epilepsy, EEG, MRI, Traumatic Brain Injury, Alzheimer's Disease, Applied Harmonic Analysis, Diffusion Google +
Dominique Geometry, Biomedical Signal Processing, Nonlinear Filtering, Analysis and Modeling of Signals, Statistical (https://scholar.google.com/citations?hl=en&user=zMF-ELoAAAAJ&view_op=list_wor
Signal Processing, Virtual Reality ks&sortby=pubdate)
Finley, James Dr. Finley's lab develops theoretical models and experiments based on principles of neuroscience, Lab (http://lcl.usc.edu/publications.html) +
M. biomechanics, and exercise physiology to identify the factors that guide learning and rehabilitation.
Ultimately, the goal of his work is to design novel and effective interventions to improve locomotor control
in individuals with damage to the nervous system. (http://lcl.usc.edu/)
Humayun, Mark Electrical stimulation of the retina,Retinal prosthesis, Retinal disease, Instrumentation for vitreoretinal Google =
S. surgery (https://ngp.usc.edu/faculty/?faculty-profile=45) (https://scholar.google.com/scholar?as_ylo=2018&q=humayun+mark+s&hl=en&as_sdt=
0,5)
Irimia, Andrei My research involves the use of multimodal neuroimaging (MRI, MRA, PET, CT, EEG, MEG) to understand how Lab (http://www.andrei-irimia.com/publications.html) +
traumatic brain injury (TBI) alters brain aging... We integrate brain mapping techniques with machine
intelligence and computational biology approaches to investigate how brain connectivity alterations...
(http://www.andrei-irimia.com/index.html)
Kalluri, Radha First, we study how the hydromechanical properties of the inner ear form the place-frequency map by using Google =
non-invasive measurements of inner ear physiology combined with mechanical modeling. Second, using whole-cell(https://scholar.google.com/scholar?as_ylo=2018&q=Radha+Kalluri&hl=en&as_sdt=0
patch clamping techniques combined with neuroanatomy and modeling we study the biophysical processes ,5)
underlying sensory signalling at the first synapse between cochlear sensory cells and the primary auditory
neuron. (https://ngp.usc.edu/faculty/?faculty-profile=156)
Kim, Hosung NIDLL's research is focused on developing an analytic platform that assesses aging of brain structures and Google +
their structural and functional networks. Our scientific mission lies in predicting the eventual long-term (https://scholar.google.com/citations?hl=en&user=y2YSIGgAAAAJ&view_op=list_wor
outcome for neurodevelopment and quantifying the progression of neurodegeneration. ks&sortby=pubdate)
(https://sites.google.com/usc.edu/nidll/research?authuser=0)
Kutch, Jason J he AMPL performs basic science and translational research focused on the neural mechanisms for muscle Google +
activation, engineering of non-invasive systems to study human motor function, and neuromuscular chronic pain(https://scholar.google.com/citations?hl=en&user=QOeSn50AAAAJ&view_op=list_wor
disorders. Of particular interest to the lab are adaptive and maladaptive motor adaptations in individuals ks&sortby=pubdate)
with chronic pain, and the brain mechanism of these adaptations. (http://ampl.usc.edu/)
Mel, Bartlett Using computer models to study brain function at single cell and systems levels. Role of active dendritic Google +
W. processing in the sensory and memory-related functions of pyramidal neurons. Neuromorphic models of visual (https://scholar.google.com/citations?hl=en&user=OXkq-Z8AAAAJ&view_op=list_wor
cortex; neurally-inspired approaches to image processing problems. ks&sortby=pubdate)
(https://ngp.usc.edu/faculty/?faculty-profile=12)
Narayanan, SAIL conducts fundamental and applied research in human-centered information processing. Our emphasis is on Lab (https://sail.usc.edu/publications/) +
Shrikanth speech, audio, language, biomedical and multi-modal signal processing, machine learning and pattern
recognition. (https://sail.usc.edu/)
Quadrato, The goal of our lab is to improve emerging brain-region specific models of the human brain, including Lab (https://quadratolab.usc.edu/publications/) =
Giorgia pluripotent stem cell derived 3D organoids and human chimeric mice... (https://quadratolab.usc.edu/research/)
Read, Stephen Neuroscience of Decision-making; Computational models of motivated decision-making; Computational models of Lab (https://dornsife.usc.edu/labs/sandlab/publications/) +
J. personality; Pavlovian Instrumental Transfer in human social behavior
(https://dornsife.usc.edu/labs/sandlab/)
Smith, Beth A. Current projects are focused on understanding the relationship between movement experience, movement outcomesGoogle +
and underlying neural control. We are using Opal movement sensors (small, lightweight, synchronized (https://scholar.google.com/citations?hl=en&user=97mrgpYAAAAJ&view_op=list_wor
accelerometer /gyroscope /magnetometers) to analyze infant movement experience and movement outcomes through ks&sortby=pubdate)
full-day, in-home monitoring (https://sites.usc.edu/inclab/)
Song, Dong My main research interests are in the fields of computational neuroscience and neural engineering. The Google +
overarching goal of my research is to develop brain-like, biomimetic devices that can mimic and restore (https://scholar.google.com/citations?hl=en&user=noJkQ7wAAAAJ&view_op=list_wor
cognitive functions (https://ngp.usc.edu/faculty/?faculty-profile=783) ks&sortby=pubdate)
Swanson, Larry We are interested in the organization of neural networks that control motivated behavior in mammals. The Google +
approach is mostly structural, and to display and model results we are developing computer graphics and (https://scholar.google.com/citations?hl=en&user=CsQTBwsAAAAJ&view_op=list_wor
database approaches (http://larrywswanson.com/) ks&sortby=pubdate)
Tao, Huizhong We are interested in the architecture of visual cortical circuits. To dissect the circuits that consist of Lab (https://ngp.usc.edu/faculty/?faculty-profile=84) =
W. excitatory and inhibitory neurons, we will apply in vivo electrophysiology, in particular two-photon imaging
guided recording, to target different types of neurons in rodent visual cortex. From the response properties
of individual neurons and the pattern of synaptic inputs to these neurons, we will be able to deduce the
connectivity rules governing the construction of cortical circuits
(https://ngp.usc.edu/faculty/?faculty-profile=84)
Zhang, Li I As a systems neuroscientist, our ultimate research goal is to decipher the brain circuits, and to understand Google +
how perception and behaviors are generated and controlled, how the brain's cortex adapts in response to (https://scholar.google.com/scholar?as_ylo=2018&q=LI+Zhang+USC&hl=en&as_sdt=0,
changes in the dynamic external environment, and how specific changes in cortical functions result in 5)
neurological and psychiatric disorders. To address these highly challenging questions, our approach is to
resolve the neural circuitry (how neurons are wired in the brain), i.e. the structural basis underlying the
brain functions. (https://sites.usc.edu/zhanglab/)
 
 
 
University of Texas, Austin
 
- Apply through: GRE: Institutional(6882), Mathematics (GRE: self report on application), Computer Science (No minimum, but high quant), Physics, ECE, Neuroscience, Psychology...
(http://ctcn.utexas.edu/apply-students/)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
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├──────────────┼─────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼───────────────────────────────────────────────────────┼────┤
Goris, Robbe He uses behavioral experiments, computational theory, and monkey electrophysiology to study representation and computation in the Lab (http://ctcn.utexas.edu/publications/) +
primate visual system (http://ctcn.utexas.edu/member/robbe-goris/)
Fiete, Ila uses computational and theoretical approaches to understand the nature of distributed coding, error correction, and dynamical Lab (http://clm.utexas.edu/fietelab/publications.html) +
mechanisms that underlie representation and computation in the brain (http://ctcn.utexas.edu/member/ila-fiete/)
Geisler, Bill research combines behavioral studies, neurophysiological studies, studies of natural stimuli, and mathematical analysis Lab +
(http://ctcn.utexas.edu/member/bill-geisler/) (https://liberalarts.utexas.edu/cps/faculty/wsg8#public
ations)
Huth, Alex Our lab uses quantitative, computational methods to try to understand how the human brain processes the natural world. In particular,Lab (https://www.cs.utexas.edu/~huth/publications.html)+
we are focused on understanding how the meaning of language is represented in the brain (https://www.cs.utexas.edu/~huth/)
Soloveichik, (molecular programming), theoretical connections between distributed computing and molecular information processing. David is also Google +
David interested in understanding how neural networks can execute distributed computing algorithms (https://scholar.google.com/citations?hl=en&user=dSPQHD
(http://ctcn.utexas.edu/member/david-soloveichik/) oAAAAJ&view_op=list_works&sortby=pubdate)
Taillefumier, We develop novel analytical and algorithmic tools to address questions at the interface of Systems Neuroscience and Applied Lab (https://mathneuro.cns.utexas.edu/publications) +
Thibaud Mathematics (https://mathneuro.cns.utexas.edu/research)
Tran, Ngoc Maiprobabilistic and combinatorial questions arising from tropical geometry and neuroscience Lab +
(http://ctcn.utexas.edu/member/ngoc-mai-tran/) (https://web.ma.utexas.edu/users/ntran/publications.htm
l)
 
 
 
University of Washington, Seattle
 
- Computational Neuroscience Center (https://cneuro-web01.s.uw.edu/training-programs/graduate-training-program/)
- Apply to Computer Science and Engineering, Applied Mathematics, Neurobiology and Behavior, Psychology, Physics...
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
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├──────────────┼────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼────────────────────────────────────────────────────────────────┼────┤
Bair, Wyeth understand neural circuitry and neural coding in the cerebral cortex with a major emphasis on the primate visual system. We Google +
approach this problem by recording directly from neurons in the functioning brain in vivo and by creating and refining large(https://scholar.google.com/scholar?hl=en&as_sdt=0%2C5&as_ylo=20
scale spiking neural network models that run on parallel computers 17&q=W+bair+washington&btnG=)
(http://depts.washington.edu/neurogrd/people/faculty/wyeth-bair/)
Brunton, Bing Data-driven dynamic models of large-scale neural data; Neural computations underlying long-term, naturalistic behavior; Google +
Efficient algorithms for closed-loop neuroengineering; Sparse sensors for biological and engineered systems (https://scholar.google.com/citations?user=UftAYPkAAAAJ&hl=en)
(https://www.bingbrunton.com/research)
Buice, Michaelidentifying and understanding the mechanisms and principles that the nervous system uses to perform the inferences which PubMed (https://www.ncbi.nlm.nih.gov/pubmed/?term=Buice+Michael +
allow us to perceive the world. I am particularly interested in neural implementations of Bayesian inference and mechanisms Author )
by which prior knowledge is encoded as well as the implications that coding efficiency has on the structure of neural
circuits (https://alleninstitute.org/what-we-do/brain-science/about/team/staff-profiles/michael-buice/)
Chizeck, (telerobotics and neural engineering). His telerobotic research includes haptic navigation and control for robotic surgery Lab (http://brl.ee.washington.edu/eprints/) +
Howard Jay and for underwater devices, as well as security of telerobotic systems. His neural engineering work involves the design and
security of brain-machine interfaces, and the development of assistive devices to restore hand and locomotion capabilities
(https://www.ece.uw.edu/people/howard-jay-chizeck/)
Koch, Christofbiophysical mechanisms underlying neural computation, understanding the mechanisms and purpose of visual attention, and Google +
uncovering the neural basis of consciousness and the subjective mind (https://scholar.google.com/citations?user=JYt9T_sAAAAJ&hl=en)
(https://alleninstitute.org/what-we-do/brain-science/about/team/staff-profiles/christof-koch/)
Fairhall, theoretical approaches to understand processing in nervous systems. We collaborate closely with experimental labs to uncoverLab (https://fairhalllab.com/publications/) +
Adrienne algorithms of information processing in a range of systems, from single neurons to foraging mosquitoes to navigating
primates (https://fairhalllab.com/)
Fox, Emily B. large-scale Bayesian dynamic modeling and computations (https://homes.cs.washington.edu/~ebfox/) Lab (https://homes.cs.washington.edu/~ebfox/publications/) =
Kutz, Nathan Theoretical Methods for Characterizing the Brain and Sensory-Motor Processing Google +
(https://faculty.washington.edu/kutz/page2/page8/) (https://scholar.google.com/citations?hl=en&user=kfT42KEAAAAJ&vi
ew_op=list_works)
Mihalas, he works to build a series of models of increasing complexity for both individual components, i.e., neurons, synapses, and NCBI (https://www.ncbi.nlm.nih.gov/pubmed/?term=Mihalas+Stefan +
Stefan microcircuits, as well as for large portions of the entire system Author )
(https://alleninstitute.org/what-we-do/brain-science/about/team/staff-profiles/stefan-mihalas/)
Rao, Rajesh Neural networks implemented on Neurochip FPGA; A dynamical systems approach to understanding cortical microcircuits, Google +
adaptation and plasticity induction (http://www.csne-erc.org/content/projects) (https://scholar.google.com/citations?hl=en&user=02nHF0gAAAAJ&vi
ew_op=list_works&sortby=pubdate)
Rokem, Ariel development of data science tools, techniques and methods and their application to the analysis of neural data Google +
(https://escience.washington.edu/people/ariel-rokem/) (https://scholar.google.com/citations?user=hrBeLVYAAAAJ&hl=en)
Shea-Brown, nonlinear dynamics of neurons, neural networks, and neural populations (http://faculty.washington.edu/etsb/) Lab (http://faculty.washington.edu/etsb/publications.html) +
Eric
Stocco, Andrearesearch concerns how human use abstract mental representations (like, rules, instructions, and plans) to perform complex Lab (http://depts.washington.edu/ccdl/?page_id=63) +
tasks. He uses computational and mathematical models, neuroimaging techniques, and brain stimulation methods determine and
predict how these mental representations are encoded in the brain, how they are transformed into behavior, and how this
knowledge can be used to improve learning and skill acquisition
(http://ilabs.washington.edu/institute-faculty/bio/i-labs-andrea-stocco-phd)
Shlizerman, development of generic computational approaches and modeling actual biological and physical systems Lab (http://faculty.washington.edu/shlizee/publications.html) +
Eli (http://faculty.washington.edu/shlizee/)
Witten, statistical machine learning techniques for problems in genomics and neuroscience Lab (https://faculty.washington.edu/dwitten/research.html) +
Daniela (https://faculty.washington.edu/dwitten/research.html)
 
 
 
U.S. Central
 
University of Chicago
 
- Neuroscience (https://neuroscience.uchicago.edu/faculty)
- Apply to biosciences. Optional GRE @ Institution(1832). (https://biosciences.uchicago.edu/admissions/how-to-apply)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
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├────────────────┼───────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼───────────────────────────────────────────────────────────────────┼────┤
Amit, Yali The main focus of my research is the formulation of statistical models for objects. Although not extensively used in Google ?+
computer vision these emerge as a powerful tool in developing recognition algorithms which allow for proper modeling of(https://scholar.google.com/scholar?as_ylo=2018&q=yali+amit&hl=en&a
object and data variability. (https://galton.uchicago.edu/faculty/amit.shtml) s_sdt=0,5)
Awh, Edward We study the interactions between visual working memory and selective attention using psychophysical and Lab (https://awhvogellab.com/publications/) ?+
electrophysiological methods. (https://awhvogellab.com/people/)
Bensmaia, Slimanwe record neuronal responses, measure the elicited percepts, and develop mathematical models to link the neuronal Lab (http://bensmaialab.org/publications/) +
representations to behavior (http://bensmaialab.org/)
Bezanilla, search for the dynamics of the molecular correlates of the function in membrane transport proteins. This is being Lab (http://nerve.bsd.uchicago.edu/FB/project.htm#Publication) +?
Francisco approached with physical techniques such as temperature effects and complex capacitance measurements in the frequency
domain combined with mutations of the molecule and assessed by gating currents, macroscopic currents and single
molecule recordings. The correlation with structural changes are being monitored with optical techniques using real
time fluorescence spectroscopy including lifetimes, changes in intensity and fluorescence resonance energy transfer
from probes attached to strategic sites in the molecule of interest while being functional in the membrane.
(http://nerve.bsd.uchicago.edu/FB/)
Cacioppo, Combining high-performance electrical neuroimaging, algorithms integrating brain source localization, noise suppressionGoogle +
Stephanie and boostrapping with high performance computing, and other methods the Brain dynamics laborator offers cutting edge (https://scholar.google.com/citations?hl=en&user=Qm3akmwAAAAJ&pages
tools for the study of brain dynamics in social species...Fields: High Performance Computing (HPC), Psychology, ize=100&view_op=list_works)
Psychiatry, Neurology, and Cognitive and Social Neuroscience. (https://braindynamics.uchicago.edu/)
Carillo, Robert ...to understand the molecules and developmental programs that regulate neuronal development and wiring Lab (https://www.carrillolab.com/publications/) ?+
(https://www.carrillolab.com/research-1/)
Dawson, Glyn ...understand the role of sphingolipids in how our brains work. Our techniques include chromatography, PubMed ?=
mass-spectrometry, confocal microscropy, DNA manipulation and a range of biochemical and genetic approaches. (https://www.ncbi.nlm.nih.gov/pubmed/?term=Dawson+g+AND+Chicagoad
(https://glyndawsonlab.uchicago.edu/) +not+autism+not+psychiatric)
Decety, Jean To characterize the neural underpinnings of fairness and distributive justice, and how they differ or not by cultural Google ?=
environment, we are conducting EEG/ERP studies in the US, France, Mexico and Taiwan. (https://scholar.google.com/citations?hl=en&user=fbNxH6UAAAAJ&view_
(https://voices.uchicago.edu/childneurosuite/) op=list_works&sortby=pubdate)
Freedman, David We use sophisticated neurophysiological techniques to monitor the activity of neuronal ensembles during behavioral Lab (https://monkeylogic.uchicago.edu/publications/) +
L tasks which require visual recognition, decision making, and learning. To identify key computational mechanisms used by
the brain, we also employ advanced quantitative approaches such as neural network modeling and machine learning.
(https://monkeylogic.uchicago.edu/)
Hatsopoulos, Our approach has been to simultaneously record neural activity from large groups of neurons using multi-electrode Lab +
Nicholas G. arrays while performing detailed kinematic, kinetic, and muscle measurements of goal-directed, motor behaviors, and to (https://pondside.uchicago.edu/oba/faculty/Hatsopoulos/lab/#publica
develop mathematical models that relate neural activity with behavior. These mathematical models provide insights as totions)
what aspects of motor behavior are being encoded in cortical neurons, but also can be used to decipher or “decode”
neural activity in order to predict movement which has practical implications for brain-machine interface development.
(https://pondside.uchicago.edu/oba/faculty/Hatsopoulos/lab/index.html)
Maunsell, John Our research is aimed at understanding how neuronal signals in visual cerebral cortex generate perceptions and guide Google =?
behavior. Our approach is to record from individual neurons in trained, behaving monkeys and mice while they perform (https://scholar.google.com/citations?hl=en&user=4U1F6tcAAAAJ&view_
visual tasks. (https://neurobiology.uchicago.edu/page/john-maunsell) op=list_works&sortby=pubdate)
Palmer, I study how populations of neurons collectively encode information present in their inputs and how they perform Google +
Stephanie computations on these signals. The brain performs several classes of computation including signal comparison, (https://scholar.google.com/citations?user=0gtvj54AAAAJ&hl=en)
prediction, error correction, and learning. To investigate these phenomena, I work with experimentalists on a variety
of systems: predictive coding in the retina and visual cortex of the rodent, motion coding in area MT, and temporal
coding in the zebra finch song system. (https://pondside.uchicago.edu/oba/faculty/palmer_s.html)
Sheffield, Mark The main goal of our lab is to establish an empirically well-supported unifying model of the neurobiology of complex Lab (https://sheffieldlab.org/publications/) =?
memory formation and recall from the level of synapses and dendrites to large-scale ensembles of neurons that is based
on data obtained from behaving animals engaged in memory-related tasks. (https://sheffieldlab.org/)
van Drongelen, Epilepsy is a serious neurological disease that affects a large population. To understand the mechanisms underlying Lab (https://epilepsylab.uchicago.edu/page/publications) +
Wim this disease we apply an interdisciplinary approach that includes clinical studies from patients with epilepsy,
experimental models, computer simulations and mathematical modeling. (https://epilepsylab.uchicago.edu/)
 
 
 
University of Illinois
 
- Computational Neuroscience (https://neuroscience.illinois.edu/research/research-overview/computational-neuroscience)
- No school or department code for GRE, but GRE required for Neuroscience admission. (https://neuroscience.illinois.edu/admissions/graduate-school-application-0)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
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├────────────────┼───────────────────────────────────────────────────────────────────────────────────────────────────────────┼───────────────────────────────────────────────────────────────────────────────┼────┤
Allen, Jont hearing/acoustics (?) Google =
(https://scholar.google.com/citations?hl=en&user=sGfS_aUAAAAJ&view_op=list_work
s&sortby=pubdate)
Fuller, Rebecca My lab is broadly interested in ecology and evolution as it applies to fishes. Google -?
(Becky) (https://scholar.google.com/citations?hl=en&user=Y1cDGKYAAAAJ&view_op=list_work
s&sortby=pubdate)
Gillette, RhanorNeuronal mechanisms of decision in circuit, cell, metabolism, and genome; Directed evolution of brain Google +
circuits for cognition and sociality; Computational simulations of choice, esthetic sense, and emerging (https://scholar.google.com/scholar?as_ylo=2018&q=Rhanor+Gillette&hl=en&as_sdt=
behavioral complexity; Comparative neurobiology of the predatory sea-slug Pleurobranchaea and the octopus 0,5)
(https://neuroscience.illinois.edu/profile/rhanor)
Llano, Daniel One specific set of issues that we address concerns the role of different cortical subnetworks in complex Google +
sound processing. For example, neurons in both cortical layer 5 and cortical layer 6 project to subcortical(https://scholar.google.com/citations?hl=en&user=wDfcEWIAAAAJ&view_op=list_work
structures, and the neurons in these layers have very different intrinsic, integrative and synaptic s&sortby=pubdate)
properties. Our work explores the different roles that these groups of neurons play in the processing of
complex sound (https://neuroscience.illinois.edu/profile/d-llano)
Lopez-Ortiz, Our research is interdisciplinary and involves the areas of dance, biomechanics, mathematical modeling, Lab (http://danceneuroscience.kch.illinois.edu/research) +
Citlali motor control, motor learning, physics, body-environment interfaces, mixed media, computational
neuroscience, neurophysiology, and rehabilitation (http://danceneuroscience.kch.illinois.edu/)
Nelson, Mark E. Research in the lab is focused on active sensory acquisition. We seek to understand neural mechanisms and Google +
computational principles that animals use to actively acquire sensory information in complex, dynamic (https://scholar.google.com/citations?hl=en&user=wr4PHUUAAAAJ&view_op=list_work
environments (https://mcb.illinois.edu/faculty/profile/m-nelson/) s&sortby=pubdate)
Vlasov, Yurii Behaviorial paradigms in virtual reality to study neural circuits in almost natural environment while mice Lab (https://www.integratedneurotech.com/neuro-informatics) +
are engaged in goal-directed behavior. Virtual reality systems allow full control over behaviorial tasks
and quantitative measurements of resulting behavior. Neuroanatomy leveraging new viral, genetic, and
computational tools to provide insights into brain circuits functionality. Machine learning based
analytical methods to extract dynamical patterns of neural activity that are correlated with animal
behavior and choice (https://neuroscience.illinois.edu/profile/yvlasov)
 
 
 
University of Iowa
 
- Neuroscience Ph.D. (https://grad.admissions.uiowa.edu/academics/neuroscience-phd)
- Apply to joint graduate program in neuroscience. No GRE requirement? (https://neuroscience.grad.uiowa.edu/prospective-students)
 
(#contents)
 
 
 
PI(Ph.D.s) Department Research Areas Research +/=/
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├────────────────┼──────────────────────────────┼────────────────────────────────────────────────────────────────────┼───────────────────────────────────────────────────────────────────────────────────────┼────┤
Abel, Ted Molecular Physiology and The primary focus of research in the Abel lab is to understand the Google =?
Biophysics cellular and molecular mechanisms of long-term memory storage with a(https://scholar.google.com/citations?hl=en&user=ubOEBGYAAAAJ&view_op=list_works&sortby
focus on the mammalian hippocampus. =pubdate)
(https://tedabel.lab.uiowa.edu/research)
Baek, Stephen Mechanical & Industrial I’m interested in mathematical representations and algorithms for Google +
Engineering learning trends and patterns in geometric objects. For my research, (https://scholar.google.com/citations?hl=en&user=dr2krBsAAAAJ&view_op=list_works&sortby(not
I have a lot of fun with photographs, videos, depth images, 3D =pubdate) so
models/scans, and medical images. much
(http://user.engineering.uiowa.edu/~sbaek//about.html) neur
osci
ence
)
Boes, Aaron Neurology Our laboratory is interested in the link between brain structure andLab (https://boes.lab.uiowa.edu/publications) +
function across the lifespan, particularly network-based
localization of neurological and psychiatric symptoms. We approach
this topic using multi-modal neuroimaging methods that include
lesion mapping, resting state functional connectivity MRI, and
structural MRI.
(https://boes.lab.uiowa.edu/neuroimaging-and-noninvasive-brain-stimu
lation-lab)
Carmichael, Chemical and Biochemical Air quality and atmospheric chemistry modeling; Data assimilation; Google =?
Gregory Engineering Chemical weather forecasting (https://scholar.google.com/citations?hl=en&user=MHbvpzAAAAAJ&view_op=list_works&sortby
(https://www.engineering.uiowa.edu/faculty-staff/gregory-carmichael)=pubdate)
Casavant, ThomasBiomedical Engineering Bioinformatics; Computational biology; Genome sequence analysis; Google +?
Software tools for human disease mutation identification; Computer (https://scholar.google.com/citations?hl=en&user=4uiMIaEAAAAJ&view_op=list_works&sortby
architecture; Parallel processing; Distributed computing; Software =pubdate)
engineering
(https://www.engineering.uiowa.edu/faculty-staff/thomas-casavant)
Chipara, Octav Mathematics Context-Sensitive Assessment of Real-World Listening Situations via Google =?
Integrated Smartphones and Hearing Aids; Contents and Contexts of (https://scholar.google.com/citations?hl=en&user=uBbYp8gAAAAJ&view_op=list_works&sortby
Cyberbullying: An Epidemiologic Study using Electronic Detection and=pubdate)
Social Network Analysis
(https://sites.google.com/site/ochipara/research)
Christensen, Electrical and Computer My research involves developing new image registration methods for Google +?
Gary E. Engineering customizing electronic anatomical atlases, automatic segmentation, (https://scholar.google.com/citations?hl=en&user=7h--HFoAAAAJ&view_op=list_works&sortby
modeling anatomical shape for the characterization of normalcy and =pubdate)
disease, and brain mapping.
(https://www.engineering.uiowa.edu/faculty-staff/gary-e-christensen)
Cromwell, John Surgery, Informatics Dr. Cromwell's research group focuses on the application of Google +
W. artificial intelligence, machine learning, predictive analytics, and(https://scholar.google.com/citations?hl=en&user=c4UXAk8AAAAJ&view_op=list_works&sortby
medical devices to improving the quality and safety of surgical =pubdate)
care. Non-invasive devices for predicting postoperative ileus and
for screening for delirium are currently undergoing
commercialization.
(https://medicine.uiowa.edu/surgery/profile/john-cromwell)
Darbro, BenjaminPediatrics My research concerns the emerging field of genomic medicine. In the Google -?
clinical laboratory we are interested in how new high throughput (https://scholar.google.com/scholar?hl=en&as_sdt=0,5&q=%22benjamin+darbro%22&scisbd=1)
technologies can be applied in a clinically appropriate fashion. We
are particularly interested in the clinical laboratory application
and quality control of whole genome single nucleotide polymorphism
(SNP) arrays, comparative genomic hybridization (CGH) arrays and
whole genome and/or exome high throughput DNA sequencing. In the
research laboratory our focus is on discovering genetic determinants
of intellectual disability/cognitive developmental delay as well as
recurrent genomic aberrations in both solid tumors and hematopoietic
malignancies that can aid in diagnosis, prognosis, and therapeutic
decision making.
(https://medicine.uiowa.edu/pediatrics/profile/benjamin-darbro)
Darcy, Isabel K.Mathematics Knot theory, DNA Knots, Modelling? Google =?
(https://scholar.google.com/scholar?as_ylo=2018&q=isabel+k+darcy&hl=en&as_sdt=0,5)
Dietrich, Bryce Political Science Bryce Dietrich’s research uses novel quantitative, automated, and Lab (http://www.brycejdietrich.com/research.html) +
machine learning methods to analyze non-traditional data sources
such as audio (or speech) data and video data. He uses these
techniques to understand the causes and consequences of elite
emotional expressions in a variety of institutional settings, with a
particular emphasis on non-verbal cues, such as vocal pitch
(https://clas.uiowa.edu/polisci/people/bryce-dietrich)
Freeman, John Psychological and Brain A major focus of our research is to identify neural circuit Lab (https://psychology.uiowa.edu/neuroscience-learning-lab/publications) +?
Sciences interactions that contribute to motor learning in rats. We are
currently examining interactions between the prefrontal cortex,
amygdala, and cerebellum during motor learning. Techniques used in
our lab include multiple tetrode recording, multisite recording,
optogenetics, DREADDs, functional imaging, various neuroanatomy
methods, electrical stimulation, and localized drug infusions in the
brain.
(https://psychology.uiowa.edu/neuroscience-learning-lab/research)
Jacob, Mathews Electrical and Computer Model Based Deep Learning (We introduce a model-based image Lab (http://research.engineering.uiowa.edu/cbig/content/publications) +
Engineering reconstruction framework with a convolution neural network (CNN)
based regularization prior). Continuous domain compressed sensing
(In particular, we reformulate sparse recovery of continuous domain
signal as a low-rank matrix completion problem in the spectral
domain, thus providing the benefit of sparse recovery with
performance guarantees.). Learned image representations for
multidimensional imaging. Free breathing & ungated cardiac MRI using
manifold models....
(http://research.engineering.uiowa.edu/cbig/content/research)
Johnson, Hans Electrical and Computer SINAPSE is an interdisciplinary team of computer scientists, Google +
Engineering software engineers, and medical investigators who develop (https://scholar.google.com/citations?hl=en&user=QOjKEt0AAAAJ&view_op=list_works&sortby
computational tools for the analysis and visualization of medical =pubdate)
image data. The purpose of the group is to provide the
infrastructure and environment for the development of computational
algorithms and open-source technologies, and then oversee the
training and dissemination of these tools to the medical research
community. (https://medicine.uiowa.edu/psychiatry/sinapse/)
Koylu, Caglar Geographical and GIScience, spatial data science, information visualization, Google =?
Sustainability Sciences, human-computer interaction, mobility and geo-social networks (https://scholar.google.com/citations?hl=en&user=sYeUuDQAAAAJ&view_op=list_works&sortby
Geoinformatics (https://clas.uiowa.edu/geography/people/caglar-koylu) =pubdate)
Magnotta, Radiology, Psychiatry, I am interested in the development of novel imaging approaches and Google +?
Vincent A. Biomedical Engineering analysis strategies to better understand psychiatric and (https://scholar.google.com/citations?hl=en&user=EguIOioAAAAJ&view_op=list_works&sortby
neurological brain disorders. My work in image acquisition focuses =pubdate)
on diffusion tensor imaging and chemical shift imaging. I am also
working on methods to automate the analysis of brain morphology and
incorporating these tools into diffusion tensor and chemical shift
imaging.
(https://medicine.uiowa.edu/radiology/profile/vincent-magnotta)
Michaelson, Psychiatry, Neuroscience, We are interested in the use of computing to improve the Lab (https://michaelson.lab.uiowa.edu/publications) +
Jacob J. Computational and Molecular understanding, diagnosis, monitoring, and treatment of
Psychiatry, Communication neuropsychiatric and neurodevelopmental conditions. To do this, we
Sciences and Disorders, build predictive models that draw on a wide variety of data types:
Biomedical Engineering including genomics, medical records, imaging, body movement, and
standardized test scores, among many others. We have
extramurally-supported research programs involving computational
methodology, human subjects research, and animal models.
(https://michaelson.lab.uiowa.edu/)
Nopoulos, Peggy Psychiatry, Neurology, The Peg Nopoulos Laboratory conducts research that is designed to Google -?
C. Pediatrics evaluate brain development and its relationship to long term (https://scholar.google.com/scholar?as_ylo=2019&q=Peggy+C.+Nopoulos&hl=en&as_sdt=0,5)
behavioral, cognitive, and emotional outcome. Our studies
investigate the impact of various medical conditions throughout the
lifespan – from shortly after birth to mature adulthood. In
particular, much of our work focuses on inherited brain disease with
adult onset. (https://nopoulos.lab.uiowa.edu/)
O'Leary, Daniel Psychiatry, Psychology Current research explores the neural basis of the genetic Google -?
vulnerability of children (ages 13 - 18 of alcoholics). Another (https://scholar.google.com/citations?hl=en&user=bVmokLUAAAAJ&view_op=list_works&sortby
project assesses the effects of marijuana on brain blood flow and =pubdate)
cognition. Both research areas involve purely behavioral assessment
of cognitive functions such as attention and memory, as well as
neuroimaging studies performed during cognitive task performance. We
are assessing blood flow with positron emission tomography (PET)
during cognitive task performance in schizophrenic patients, normal
volunteers, and marijuana users.
(https://medicine.uiowa.edu/psychiatry/profile/daniel-oleary)
Parker, Krystal Psychiatry My long-term goal is to understand the cerebellar contribution to Google +
L. cognitive and affective processes. In pursuit of this goal, I (https://scholar.google.com/citations?hl=en&user=KlAGhpIAAAAJ&view_op=list_works&sortby
combine neurophysiology, pharmacology and optogenetics in animals =pubdate)
performing behavioral tasks to dissect cerebellar neural circuitry.
I study the potential for cerebellar stimulation to rescue cognitive
impairments and mood in humans using EEG but also in animals with
pharmacologically- and genetically-induced phenotypes of disease. My
training in psychology, systems neurophysiology, and clinical
psychiatry allows me to target the cerebellum for novel treatments
of diseases involving cognitive and affective dysfunction.
(https://parker.lab.uiowa.edu/)
Paulsen, Jane Psychiatry, Neurology, Huntington’s disease, Alzheimer’s disease, schizophrenia, dementia, Google =?
Psychological & Brain Sciencespsychoses, tardive dyskinesia, neuropsychological features and (https://scholar.google.com/citations?hl=en&user=mzO_jcQAAAAJ&view_op=list_works&sortby
correlates of the above. =pubdate)
(https://psychology.uiowa.edu/people/jane-paulsen)
Schnieders, Biomedical Engineering My research interests are focused on the molecular biophysics theoryGoogle +
Michael J. and high performance computational algorithms that are essential to (https://scholar.google.com/citations?hl=en&user=sXWbF2sAAAAJ&view_op=list_works&sortby
reducing the time and cost of engineering new pharmaceuticals. A =pubdate)
complementary goal is to understand patient specific responses to
pharmaceuticals by integrating genetic information and molecular
phenotypes.
(https://www.engineering.uiowa.edu/sites/www.engineering.uiowa.edu/f
iles/person/cv/michael_j_schnieders_cv.pdf)
Shinozaki, Gen Psychiatry, Neurosurgery The Shinozaki Laboratory studies the molecular influence of PubMed (https://www.ncbi.nlm.nih.gov/pubmed/?term=Shinozaki+G) +
environmental factors such as trauma, stress, and inflammation on
individual susceptibility to psychiatric conditions including major
depressive disorder (MDD), post-traumatic stress disorder (PTSD),
and delirium using epigenetic/genetic approaches as well as a
medical engineering approach through device development and machine
learning. (https://shinozaki.lab.uiowa.edu/)
Sonka, Milan Electrical and Computer Research interests include medical imaging, image segmentation, and Google +
Engineering automated knowledge-based image analysis in a variety of (https://scholar.google.co.in/citations?hl=en&user=ve3AkSIAAAAJ&view_op=list_works&sort
applications and in various image modalities. by=pubdate)
(http://user.engineering.uiowa.edu/~sonka/research.php)
Srinivasan, Computer Science Information Retrieval & NLP - Text Mining - Web Mining - Biomedical Lab (http://homepage.cs.uiowa.edu/~psriniva/newsite/papers-page.html) -?
Padmini Text Mining - Privacy/Security & Censorship - Social Media Analytics
(Politics, Health Beliefs) - Crowdsourcing & Games
(http://homepage.cs.uiowa.edu/~psriniva/newsite/index.html)
Stewart, David Mathematics Numerical Analysis, Mathematical Modeling, Scientific Computing, Lab (http://homepage.divms.uiowa.edu/~dstewart/des_publns.html) -?
Optimization, Optimal Control
(http://homepage.divms.uiowa.edu/~dstewart/index.html)
Strathearn, LaneBehavioral Pediatrics My lab aims to explore the neurobiology of early attachment NIH -?
relationships using functional MRI and other neurophysiological and (https://www.ncbi.nlm.nih.gov/sites/myncbi/lane.strathearn.1/bibliography/41163872/publ
endocrine measures. This includes projects examining brain and ic/?sort=date&direction=descending)
behavioral responses of drug addicted mothers, and how intranasal
oxytocin may impact maternal responses. This research has been
funded by the National Institute of Child Health and Human
Development and the National Institute of Drug Abuse. We have also
published on the effects of intranasal oxytocin on children and
adolescents with autism.
(https://medicine.uiowa.edu/pediatrics/profile/lane-strathearn)
Vaidya, Jatin Psychiatry The laboratory uses state-of-the-art functional imaging tools such Google -?
as functional magnetic resonance imaging (fMRI) and positron (https://scholar.google.co.in/scholar?as_ylo=2019&q=Jatin+Vaidya&hl=en&as_sdt=0,5)
emission tomography (PET) as well as advanced structural imaging
protocols (e.g., diffusion weighted imaging) in conjunction with
neuropsychological tests and personality assessments.
(https://cognitive-brain.lab.uiowa.edu/)
Wemmie, John Psychiatry, Molecular John Wemmie, MD, PhD, professor in the Department of Psychiatry at Google =?
Physiology and Biophysics, the University of Iowa, is interested in the role of brain pH and (https://scholar.google.com/citations?hl=en&user=HEr04BQAAAAJ&view_op=list_works&sortby
Neurosurgery acid-sensing ion channels in brain function and behavior. This work =pubdate)
has led to the discovery of critical roles for brain pH in synaptic
plasticity, anxiety, and depression-related behaviors in mice.
Current projects include investigating the synaptic mechanisms for
acid-sensing ion channel action and also translating these
discoveries to human behavior and brain function. For example, his
laboratory is using non-invasive pH-sensitive magnetic resonance
imaging to investigate the roles of brain pH in psychiatric
illnesses such as panic disorder and bipolar affective disorder.
(https://wemmie.lab.uiowa.edu/)
Williams, Psychiatry The Williams lab is interested in understanding the molecular and Lab (https://williams.lab.uiowa.edu/publications) =?
Aislinn cellular mechanisms by which genetic risk factors contribute to
psychiatric disease from a developmental perspective. Our current
projects focus on voltage-gated calcium channel genes, which have
been linked to the risk of developing bipolar disorder,
schizophrenia, depression, and autism. We use induced pluripotent
stem cells and transgenic mouse models to study how calcium channel
gene SNPs alter neuronal development, neural circuit function, and
affective behavior. We employ a wide range of approaches, including
molecular biology, live cell imaging, neuropathology, and animal
behavioral assessments, to try to unravel the developmental pathways
involved in neuropsychiatric disease, in the hope of identifying
novel treatment targets. (https://williams.lab.uiowa.edu/)
 
 
 
Indiana University
 
Cognitive and Computational Neuroscience (https://neuroscience.indiana.edu/research/core-research-areas/cognitive-computational.html)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
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├───────────────┼────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼───────────────────────────────────────────────────────────────────────────┼────┤
Beer, Randall I work on the evolution and analysis of dynamical "nervous systems" for model agents, neuromechanical modeling Google +
D. of animals, biologically-inspired robotics, and dynamical systems approaches to behavior and cognition. More (https://scholar.google.com/citations?hl=en&user=F_J8QyAAAAAJ&view_op=list_
generally, I am interested in computational and theoretical biology, including models of metabolism, gene works&sortby=pubdate)
regulation and development (http://mypage.iu.edu/~rdbeer/)
Beggs, John M. Our work focuses on understanding how groups of brain cells work together to process information. We approach Google +
this topic by using advanced arrays with hundreds of tiny wires to eavesdrop on electrical signals within small (https://scholar.google.com/citations?hl=en&user=y9X4_AkAAAAJ&view_op=list_
pieces of brain tissue. To try and explain how networks of interacting brain cells give rise to patterns of works&sortby=pubdate)
signals, we borrow ideas from statistical physics, where the self-organized patterns of multiple interacting
particles have been well-studied. (http://www.beggslab.com/)
Bertenthal, My research focuses on the origins, development, and basic processing mechanisms involved in the perception and Google =
Bennett I. representation of actions by social and non-social stimuli. (https://scholar.google.com/citations?hl=en&user=RoPQHxEAAAAJ&view_op=list_
(https://psych.indiana.edu/directory/faculty/bertenthal-bennett.html) works&sortby=pubdate)
Betzel, RichardOur work involves analysis of network data at different spatial, temporal, and topological scales. Our goal is Lab (https://www.brainnetworkslab.com/publications/) +
to understand the underlying principles that shape the organization and function of biological neural networks.
(https://www.brainnetworkslab.com/)
Brown, Joshua The mission of the Cognitive Control Lab is to identify and characterize the neural mechanisms of goal directed Lab (https://ccsrv1.psych.indiana.edu/cclab/publications/) +
W. behavior. To this end, we focus on the frontal lobes, and especially the medial prefrontal cortex. Our research
involves a tight integration of computational neural modeling, functional MRI, and cognitive psychology.
(https://ccsrv1.psych.indiana.edu/cclab/)
Busey, Thomas visual perception; recognition memory; face recognition EEG analysis of face and object perception; mathematicalPersonal (http://cognitrn.psych.indiana.edu/busey/HomePage/pubs.htm) +
modeling techniques applied to above domains (http://cognitrn.psych.indiana.edu/busey/HomePage/)
Farley, Joseph cellular and molecular mechanisms of learning and memory; neurobiology of behavior; excitable membranes/ion Google +
channels; neurobiology of nicotine abuse and addiction; molecular bases of signal transduction; computational (https://scholar.google.com/scholar?hl=en&as_sdt=0%2C5&as_ylo=2018&q=Joseph
models of neuronal excitability (https://psych.indiana.edu/directory/faculty/farley-joseph.html) +Farley&btnG=)
Garyfallidis, Prof. Garyfallidis is leading a new lab for Neuroengineering at ISE specializing in the developing of new Lab (https://grg.sice.indiana.edu/publications/) +
Eleftherios methods and intelligent algorithms for medical imaging and brain mapping with applications to research, clinic
and industry. (https://grg.sice.indiana.edu/)
Izquierdo, My research interest is in understanding the neural basis of behavior, as it arises from the interaction betweenGoogle +
Eduardo the organism’s nervous system, its body, and its environment. I combine connectome graph analysis, neural (https://scholar.google.com/citations?hl=en&user=KWCQjl0AAAAJ&view_op=list_
network simulations, evolutionary algorithms for optimization, taking into account experimental observations, works&sortby=pubdate)
and mathematical analysis, including information theory and dynamical systems theory, to generate and understand
complete brain-body-environment models of simple but biologically and cognitively interesting behaviors.
(http://mypage.iu.edu/~edizquie/)
James, Thomas Object recognition and categorization; Perceptual decision making; Functional neuroimaging; Sensory integration;Google +
W. Visual, somatosensory and auditory perception; Priming, adaptation, and perceptual learning (https://scholar.google.com/scholar?hl=en&as_sdt=0%2C5&as_ylo=2018&q=Thomas
(https://psych.indiana.edu/directory/faculty/james-thomas.html) +W.+James&btnG=)
Jones, Michael Large-Scale Semantic Modeling; Large-Scale Automated Synthesis of Human Functional Neuroimaging Data; Lab (https://www.compcog.com/publications.html) +
Integrating Linguistic and Perceptual Information in Models of Lexical Semantics; Model-Based Guided Retrieval
Practice Systems; Understanding linguistic and semantic development via naturalistic child-directed data;
Retrieval Operations from Episodic and Semantic Memory... (https://www.compcog.com/)
I am interested in the development of statistical methods for the analysis of brain imaging data. My recent or Google +
ongoing projects include: High-dimensional outlier detection methods for artifact removal in fMRI data; (https://scholar.google.com/citations?hl=en&user=HS9XWtAAAAAJ&view_op=list_
Empirical Bayes shrinkage estimation of subject-level resting-state functional connectivity; Bayesian spatial works&sortby=pubdate)
modeling in task activation studies using cortical surface fMRI; Empirical Bayesian techniques to account for
spatial dependence in fMRI task activation studies; Leveraging big fMRI datasets for estimation of subject-level
and group-level resting-state networks through “template” independent component analysis (ICA); Synthesis of
quantitative structural MR images (e.g. quantitative T1 maps, DTI, MTR) using conventional sequences (e.g.
T1-weighted and FLAIR) (https://mandymejia.wordpress.com/research/)
Newman, Ehren How do neural circuits give rise to human memory? To answer this question, our group combines optogenetics, PubMed (https://www.ncbi.nlm.nih.gov/pubmed?term=Newman%20EL%5BAuthor%5D) +
pharmacology and behavioral manipulations with high-density tetrode and depth-probe recordings of neural
activity in awake behaving rats. We are most interested in areas known as the hippocampus, medial septum, and
entorhinal cortex which have all been shown to play important roles in memory in humans and animals. We use
computational modeling to bridge this experimental work and human memory processing. Our work suggests that
neural rhythms allow the brain to code, manipulate and store information and that these dynamics are regulated
by acetylcholine. (http://www.iu.edu/~memlab/)
Pisoni, David Our long-term goal is to provide broad interdisciplinary research training in the Communication Sciences and =
P. Disorders and to encourage novel and creative approaches to basic and clinical research problems in Speech,
Hearing and Sensory Communication. (http://www.iu.edu/~srlweb/)
Cognition and modeling of cognition; Machine learning; Computational Statistics; Learning; Memory; Sensory Google +
coding; Information retrieval; Attention and automatism; Organization and structore of memory; Control processes(https://scholar.google.com/scholar?as_ylo=2018&q=Richard+Shiffrin&hl=en&as
in memory; Decision theory; Optimal decision making; Rationality and reasoning; Vision processing and visual _sdt=0,5)
features; Psychological representation, mathematical and computer models of the various content areas listed
above. (https://psych.indiana.edu/directory/faculty/shiffrin-richard.html)
Sporns, Olaf To make sense of the brain as a complex system we employ a broad range of analysis and modeling techniques, Google +
particularly methods coming from computational neuroscience, graph theory, time series analysis, complexity and (https://scholar.google.com/citations?hl=en&user=gzPWwdIAAAAJ&view_op=list_
information theory. (http://www.indiana.edu/~cortex/) works&sortby=pubdate)
Swanson, Need detailed info (https://optometry.iu.edu/people-directory/swanson-william.html) Google ?
William H. (https://scholar.google.com/scholar?hl=en&as_sdt=0%2C5&as_ylo=2018&q=WH+Swa
nson&btnG=)
 
 
 
University of Minnesota
 
- Computational Neuroscience (http://www.neuroscience.umn.edu/areas-research/computational-neuroscience)
- Neuroscience graduate admission (http://www.neuroscience.umn.edu/admissions/application-and-admissions-information)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
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├───────────────┼──────────────────────────────────────────────────────────────────────────────────────────────────────────────┼─────────────────────────────────────────────────────────────────────────────┼────┤
Amirikian, My current research interests are focused on two related issues: (i) deciphering the local cortical circuitry PubMed (https://www.ncbi.nlm.nih.gov/pubmed/?term=bagrat+amirikian) +
Bagrat from the spatial structure of axonal and dendritic arbors of pre- and post-synaptic cell-pairs and their
distribution across cortical layers, and (ii) understanding how these local circuits give rise to functional
modules, and how they shape the underlying cortical dynamics.
(http://www.neuroscience.umn.edu/people/bagrat-amirikian-phd)
Kersten, DanielMy lab uses behavioral and and brain imaging to investigate how the visual pathways of the brain transform PubMed +
image information into useful actions (Bloj et al., 1999, Murray et al., 2002). A major theoretical challenge (https://www.ncbi.nlm.nih.gov/pubmed?cmd=PureSearch&term=%28Kersten%20D%5BAut
is to discover the computational principles required to estimate object properties and determine motor output hor%5D%20%20AND%20%20%28%22minnesota%22%29%29)
from image features. Computational vision searches for these solutions (Kersten and Yuille, 2003). The
experimental challenge is to discover how our visual systems and those of other animals are built to achieve
useful actions from the images received. (http://www.neuroscience.umn.edu/people/daniel-j-kersten-phd)
Lim, Hubert The goal of my lab is to push the development and translation of brain-machine interfaces from scientific PubMed (http://www.neuroscience.umn.edu/people/hubert-lim-phd) -
concept into clinical application with close collaboration with clinicians and industry. Brain-machine
interfaces span a broad array of applications and consist of either direct connection of a device to neurons
within the brain or neural communication through noninvasive techniques, such as EEG recordings and
transcranial magnetic stimulation. (http://www.neuroscience.umn.edu/people/daniel-j-kersten-phd)
Olman, Cheryl Employing a combination of visual psychophysics and fMRI, I want to determine how detection of local image PubMed (https://www.ncbi.nlm.nih.gov/myncbi/browse/collection/45113341/) =
features interacts with scene perception. How are local features in an image selected and grouped to construct
a mental representation of a scene or object? To what extent do internal templates determine feature selection
and shape perception? (http://vision.psych.umn.edu/users/caolman/)
Redish, David I am interested in questions of how neural structures work together to create systems able to accomplish PubMed +
behavioral tasks. Our primary current projects are in the interaction between multiple learning systems (such (https://www.ncbi.nlm.nih.gov/myncbi/browse/collection/41152826/?sort=date&di
as hippocampus, cortex, and striatum) in the ability to make decisions, particularly deliberative decisions. rection=ascending)
(http://www.neuroscience.umn.edu/people/david-redish-phd/)
Schrater, Paul My research interests include human and computer vision, planning and guiding reaches with and without visual PubMed +
information, and the integration of visual, haptic, and motor information during the perception-action cycle. (https://www.ncbi.nlm.nih.gov/pubmed?cmd=PureSearch&term=%28Schrater%20PR%5BA
My research approach treats problems in vision and motor control as problems of statistical inference, which uthor%5D%20%20AND%20%20%28%22minnesota%22%29%29)
has led to a concurrent interest in statistical methods that includes Bayesian (Belief) Networks, Dynamic
Markov Decision Networks, Pattern Theory, Machine Learning, and other topics in statistics and pattern
recognition. (http://www.neuroscience.umn.edu/people/paul-schrater-phd)
Vinogradov, Dr. Sophia Vinogradov directs a translational clinical neuroscience laboratory that focuses on cognitive Google (https://scholar.google.com/citations?user=kbU8I1UAAAAJ&hl=en) +
Sophia dysfunction in schizophrenia. In collaboration with basic scientists, she studies neuroscience-informed
computerized cognitive training exercises for patients with schizophrenia that aim to drive enduring plastic
changes in cortical processing. The training programs utilize adaptive algorithms to adjust the difficulty
level to maintain a 70-80% correct performance rate, allowing for a customized approach to each individual’s
initial performance level and progress rate. Spanning several aspects of cognitive functioning, the exercises
fine tune sensory processing speed, working memory, and attention as well as higher-order cognitive processes.
In turn, this results in significant improvements in untrained cognitive skills as well as improvements in
quality of life. (http://www.neuroscience.umn.edu/people/sophia-vinogradov-md)
Wilcox, George Dr. Wilcox and colleagues are engaged in research into the spinal neurotransmission of pain and mechanisms PubMed (http://www.neuroscience.umn.edu/people/george-l-wilcox-phd) +
underlying hyperalgesia, analgesia and analgesic tolerance. Studies of both excitatory and inhibitory
neurotransmission in the rodent spinal cord apply behavioral, lectrophysiological (both in vivo and in vitro),
immunocytochemical and molecular techniques. Dr. Wilcox facilitates access for Neuroscience students to high
performance computing laboratories on campus: The Laboratory for Computational Science & Engineering and The
Minnesota Supercomputer Institute (MSI). High performance computers and visualization are now finding
applications in biological imaging, macromolecular modeling and neuronal simulation.
(http://www.neuroscience.umn.edu/people/george-l-wilcox-phd)
Zilverstand, Dr. Zilverstand is a psychologist and neuroimaging expert, faculty in the Department of Psychiatry and Google (https://scholar.google.com/citations?user=jg5A1hwAAAAJ&hl=en) +
Anna Behavioral Science and member of the Medical Discovery Team on Addiction. She leads an interdisciplinary team
focused on investigating how individual differences contribute to human drug addiction. Her research group
analyzes existing large-scale multimodal data sets, in addition to acquiring their own data by employing a
variety of techniques such as interviewing, neurocognitive testing, questionnaires and multi-modal
neuroimaging. Novel computational methods are employed for linking social, demographic, neurocognitive,
personality and clinical measures to the neuroimaging data, to explore the existence of neurobiological
subtypes within the addicted population. (http://www.neuroscience.umn.edu/people/anna-zilverstand-phd)
Zimmerman, Jan The primary research goal of the Z-LAB is to better understand decision making. Making a choice, independent Google (http://www.neuroscience.umn.edu/people/jan-zimmermann-phd) +
of it being a complex decision about your retirement allocations or which flavor of ice-cream to pick, is the
normative consequence of any behavior that is observable. To understand this process, we combine a multitude
of tools that allow us to study neural function of non human primates associated to decision making. We
combine single cell electrophysiology, computational modeling of neural responses as well as careful
behavioral analysis and ultra high field functional magnetic resonance imaging.
(http://www.neuroscience.umn.edu/people/jan-zimmermann-phd)
 
 
 
U.S. East
 
Boston University
 
- Computational Neuroscience (https://www.bu.edu/neuro/academics/graduate/curriculum/computational-neuroscience/)
- Apply directly through the Graduate Portal for Neuroscience (https://www.bu.edu/neuro/apply/request-for-application-materials/)
 
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├─────────────┼───────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼──────────────────────────────────────────────────────────┼────┤
ChandrasekaraUnderstanding how the primate brain makes decisions based on sensory input and guides limb movement. Extensive evidence from strokeGoogle +
n, patients and physiological/lesion studies in humans suggest that a part of the brain called the dorsal premotor cortex is involved (https://scholar.google.com/citations?user=3Yeb98kAAAAJ&hl
Chandramouli in selecting the appropriate limb movement on the basis of the sensory input. (http://sites.bu.edu/chandlab/) =en)
Eden, Uri Developing mathematical and statistical methods to analyze neueral spiking activity by developing a methodological, statistical Google +
framework and applying them to point process observations. (http://www.bu.edu/math/people/faculty/probability-and-statistics/eden/)(https://scholar.google.com/citations?user=M8rzdnwAAAAJ&hl
=en)
Kon, Mark Quantum probability and information, bioinformatics, machine and statistical learning, mathematical physics, mathematical and Google +
computational neuroscience, complexity theory, and wavelets. (http://math.bu.edu/people/mkon/) (https://scholar.google.com/citations?user=wVPc21cAAAAJ&hl
=en)
Kopell, NancyUnderstanding how the dynamical properties of local networks help to filter and transform the patterned input form other parts of Google -
the nervous system, to provide clues to the function of dynamics in the nervous system. (https://scholar.google.com/citations?user=mbDmBBsAAAAJ&hl
(https://www.bu.edu/eng/profile/nancy-kopell-ph-d/) =en)
Kramer, Mark His research focuses on interdisciplinary topics in mathematical neuroscience with particular emphasis on biophysical models of Google +
neural activity and data analysis techniques. He is currently interested in medical applications and networks in neuroscience. (https://scholar.google.com/citations?user=gn4NeQkAAAAJ&hl
(https://www.bu.edu/math/people/faculty/mathematical-biology-and-neuroscience/kramer/) =en)
Scott, Ben Develop and apply new technologies to study the neural basis of cognition and complex learned behavior through biomedical Lab (https://www.scottcognitionlab.com/publications) -
engineering, particularly the development of novel optical imaging and genetic methods to observe and perturb the activity of
neurons in their native habitat – the intact brains of living organisms - and neuroethology, the study of brain circuits that
underlie natural behaviors in order to elucidate basic principles of brain function. (https://www.bu.edu/csn/profile/ben-scott/)
 
 
 
Brandeis University
 
- Ph.D. GREs not required. Letters of recommendation are important. (https://www.brandeis.edu/neuroscience/graduate/apply/index.html)
- See also: Sloan-Swartz Center for Theoretical Neuroscience (http://www.bio.brandeis.edu/sloan/index.html)
 
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├──────────────┼────────────────────────────────────────────────────────────────────────────────────────────────────────────┼────────────────────────────────────────────────────────────────────────────────┼────┤
Epstein, The overall goal of our research is to understand, design and control chemical systems that exhibit complex,Google +
Irving nonlinear, dynamic behavior in time and space. This behavior includes periodic oscillation, chaos, wave (https://scholar.google.com/citations?hl=en&user=YZxj3HwAAAAJ&view_op=list_works
propagation and pattern formation. Such systems may have important applications to, or provide insights &sortby=pubdate)
into, related phenomena in biology, physics, mathematics, polymer and materials science. We employ a variety
of techniques, both experimental and theoretical, in our work. (http://hopf.chem.brandeis.edu/)
Jadhav, The Jadhav Lab integrates behavior, electrophysiology, optogenetics and computational analysis to Lab (http://www.bio.brandeis.edu/jadhavlab/publications.html) +
Shantanu investigate the neural basis of learning, memory and decision making in the mammalian brain.
(http://www.bio.brandeis.edu/jadhavlab/index.html)
Katz, Don We study the neural ensemble dynamics of sensori-motor processes in awake rodents, combining behavior, Google? +
multi-neuronal electrophysiology, complex analysis and modeling, pharmacology and optogenetics to probe (https://scholar.google.com/scholar?as_ylo=2018&q=Donald+B.+Katz+Brandeis&hl=en&
ongoing spiking activity in real-time (https://sites.google.com/a/brandeis.edu/katzlab/) as_sdt=0,5)
Marder, Eve How do neuromodulators and neuromodulatory neurons reconfigure circuits so that the same group of neurons Lab (http://blogs.brandeis.edu/marderlab/publication/) +
can produce a variety of behaviorally relevant outputs? How can networks be both stable over the lifetime of
the animal despite ongoing turnover of membrane proteins such as channels and receptors? How is network
stability maintained over long time periods? To what extent do similar network outputs result from different
underlying mechanisms or solutions?. How variable are the sets of parameters that govern circuit function
across animals? How can animals with disparate sets of circuit parameters respond reliably to perturbations
such as neuromodulators and temperature? (http://blogs.brandeis.edu/marderlab/)
Miller, Paul Quasi-stable attractor states as a framework for neural computing...Learning and Solving Associative Google +
Cognitive Tasks...Parametric Working Memory and Sequential Discrimination...Molecular basis of long-term (https://scholar.google.com/citations?hl=en&user=ZdwhFVYAAAAJ&view_op=list_works
memory (http://www.brandeis.edu/facultyguide/person.html?emplid=e155804f5e9e6a843dab5395a623718200ad54b8) &sortby=pubdate)
Touboul, My approach often involves data analysis, simplified mathematical models, computer simulations and Google ? +
Jonathan theoretical and mathematical analysis, using dynamical systems and probability. And in this program, I (https://scholar.google.com/citations?hl=en&user=t_YFoiUAAAAJ&view_op=list_works
enthusiastically collaborate with experimentalists, mathematicians and physicists! &sortby=pubdate)
(https://www.brandeis.edu/facultyguide/person.html?emplid=8cb81567ab262202223ac427c8e768ea4efad6b0)
Van Hooser, In the Neural Circuits Lab, we apply a new generation of optical and optogenetic tools to observe both Google +
Stephen fine-scale circuit features and systems-level responses at the same time, in the living brain. We combine (https://scholar.google.com/citations?hl=en&user=H3vXtAUAAAAJ&view_op=list_works
these optical approaches with advanced physiological and anatomical techniques to address previously &sortby=pubdate)
inaccessible questions about neural circuitry and its development in mammalian visual cortex.
(http://www.vhlab.org/)
 
 
 
Brown University
 
- Computational Neuroscience (http://neuroscience.brown.edu/graduate/faculty/computational)
- For all departments, apply generally to Brown Graduate school. GRE @ Institution(3094). For Brown University School of Public Health @ Institution(7765). Neuroscience @ Departmnent(0213). Applied Math ?.
(https://www.brown.edu/academics/gradschool/apply)
- For NIH/Neuroscience also fill out the NIH Partnership Application (https://www2.training.nih.gov/apps/publicForms/gpp/forms/login.aspx)
- See Behavioral Neuroscience Requirements (https://www.brown.edu/academics/cognitive-linguistic-psychological-sciences/prospective-graduate-students)
 
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Bienenstock, My research is in theoretical neuroscience, computational vision, and computational linguistics. I study the mechanisms +
Lucien Elie used by brains to create and work with complex, detailed, hierarchical representations of the external world
(https://vivo.brown.edu/display/lbienens#Research)
Connors, Barry We discovered that inhibitory neurons in the cortex communicate via electrical synapses, and that electrically coupled Google +
networks of neurons can serve as pacemakers for cortical rhythms in the brain. We are also studying how neural activity (https://scholar.google.com/citations?hl=en&user=whbW9AQAAAAJ&vie
leads to plasticity of cortical circuits, and how the seizure discharges of epilepsy begin and propagate through the w_op=list_works&sortby=pubdate)
cortex. Our methods include intracellular and extracellular recording and patch clamping, neuroanatomical techniques,
isolated slice preparations, optogenetics, and computer modeling. (https://vivo.brown.edu/display/bconnors#Research)
Cooper, Leon Leon Cooper studies neural networks, including architecture, learning rules, and real world applications; the biological +
basis of memory and learning; mean field theories; the foundations of quantum theory; and superconductivity.
(https://vivo.brown.edu/display/lcooper#Research)
Donoghue, John Our laboratory investigates how the brain turns thought into voluntary behaviors and how that knowledge can be used to Google +
P. help persons with paralysis. We study how populations of neurons represent and transform information as a motor plan (https://scholar.google.com/scholar?as_ylo=2018&q=John+Donoghue+b
becomes movement. This approach has required the creation of a novel recording array to study neural ensembles. With the rain&hl=en&as_sdt=0,5)
knowledge we have gained about movement representation, we have translated our findings to a clinical application in
which humans with paralysis can use their neurons directly to control devices.
(https://vivo.brown.edu/display/jdonoghu#Research)
Frank, Michael My research combines multiple levels of computational modeling and experimental work to understand the neural mechanisms Google +
underlying reinforcement learning, decision making and cognitive control. We develop neural circuit and algorithmic (https://scholar.google.com/citations?hl=en&user=f-xyFpUAAAAJ&vie
models of systems-level interactions between multiple brain areas (primarily prefrontal cortex and basal ganglia and w_op=list_works&sortby=pubdate)
their modulation by dopamine). We test theoretical predictions of the models using various neuropsychological,
pharmacological, genetic, and imaging techniques. (https://vivo.brown.edu/display/mjfrank)
Geman, Stuart My hypothesis is that the dual principles of re-usability and hierarchy, or what cognitive scientists call Google +
compositionality, form the foundation for efficient learning in biological systems; Statistical methods are being devised(https://scholar.google.com/scholar?as_ylo=2018&q=geman+stuart&hl
to support the systematic search for fine-temporal structure in stable multi-unit recordings; These spatio-temporal =en&as_sdt=0,5)
patterns, with their correlation-induced topologies, would be good candidates for the basic units of cognitive
processing... (http://www.dam.brown.edu/people/geman/)
Hochberg, Leigh Our Laboratory for Restorative Neurotechnology focuses on developing strategies to restore communication, mobility, and Lab (https://vivo.brown.edu/display/lhochber#Publications) +
independence for people with paralysis or limb loss. In addition to endeavors related to the pilot clinical trial of the
BrainGate2 Neural Interface System, we are interested in understanding human intracortical neurophysiology during the
planning and production of voluntary movement, and understanding neuronal ensemble function in a variety of neurologic
diseases or injuries. Our lab is also engaged in stroke neurorecovery research. (https://vivo.brown.edu/display/lhochber)
Jones, StephanieThe Jones Lab combines experimental and theoretical techniques to study human brain dynamics. Our mission is to develop Google +
biophysically principled computational models of neural circuits that bridge electrophysiological measures of brain (https://scholar.google.com/citations?hl=en&user=H2lcpR0AAAAJ&vie
function to the underlying cellular and network level dynamics. We aim to translate an understanding of the network w_op=list_works&sortby=pubdate)
mechanism underlying measured brain signals into strategies to improve disrupt function.
(https://blogs.brown.edu/joneslab/)
Nurmikko, Arto developing means to record from the brain of primates by employing implantable fully wireless, microelectronically activeLab (http://nurmikko.engin.brown.edu/?q=node/10) +
neural signal probes, with the goal of ‘reading out’ large numbers of individual neurons from different brain
microcircuits in real time; developing novel optoelectronic devices as bidirectional brain interfaces and employing these
devices in combination with so-called optogenetic methods to study brain function both in vivo and in vitro.; developing
a dual-function brain implantable microscale chip which combined both “readout” (by electrical or possibly optical means)
and “write-in”... (http://nurmikko.engin.brown.edu/?q=node/43)
Paradiso, The aims of Dr. Paradiso's research are to elucidate the encoding of visual information in cerebral cortex, the Lab (https://vivo.brown.edu/display/mparadis#Publications) +
Michael computations performed by interacting neurons, and the adaptive use of neural circuitry, with the goal of understanding
the mechanisms underlying human visual perception. (https://vivo.brown.edu/display/mparadis#Research)
Serre, Thomas My lab seeks to understand the neural computations supporting visual perception. There is little doubt that even a Lab (http://serre-lab.clps.brown.edu/publications/) +
partial solution to the question of which computations are carried out by the visual cortex would be a major
breakthrough: It would begin to explain one of our most amazing abilities, vision; and it would open doors to other
aspects of intelligence such as language, planning or reasoning. (http://serre-lab.clps.brown.edu/)
Sheinberg, DavidResearch in my lab explores how we identify objects and events in the real world, where both the observer and the Google +
environment change over time. (http://charlotte.neuro.brown.edu/) (https://scholar.google.com/scholar?as_ylo=2018&q=David+Sheinberg
&hl=en&as_sdt=0,5)
Truccolo, WilsonCollective neural dynamics in neurological disorders (epilepsy, stroke, ALS, spinal cord injury); Stochastic processes Google +
and random dynamical systems for multi-scale neural dynamics; Subsampling and spatiotemporal coarse graining of (https://scholar.google.com/citations?hl=en&user=gaKfE5MAAAAJ&vie
collective neural dynamics; Statistical algorithms for closed-loop neuromedical systems: Tracking, prediction & control w_op=list_works&sortby=pubdate)
of brain dynamics in neurological disorders (https://www.truccololab.com/)
 
 
 
Carnegie Mellon University and University of Pittsburgh
 
- Computational Neuroscience (http://www.cnbc.cmu.edu/training/graduate/computational-neuroscience/)
- Ph.D. in Neural Computation. GRE not required but Institution(0274) and Department(0213). (http://compneuro.cmu.edu/)
- Applications open during submission times (https://applygrad.cs.cmu.edu/apply/offline.php)
 
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Ahmari, SusanneHow do molecular and circuit changes in the brain cause psychiatric illness? And how can we leverage the Google =
inherent plasticity of the brain to treat psychiatric disorders? (https://pre.cnup.pitt.edu/people/ant) (https://scholar.google.com/scholar?as_ylo=2018&q=Susanne+E.+Ahmari&hl=en&as
_sdt=0,5)
Anderson, John We have taken on modeling the cognitive competences that are taught in the domains of mathematics, computer Google +?
R. programming, and cognitive psychology. (http://act-r.psy.cmu.edu/peoplepages/ja/ja-interests.html) (https://scholar.google.com/citations?hl=en&user=PGcc-RIAAAAJ&view_op=list_w
orks&sortby=pubdate)
Barth, Alison Research in the Barth Lab is focused on understanding how experience assembles and alters the properties of Lab (https://www.bio.cmu.edu/labs/barth/publications.html) +
neural circuits in the cerebral cortex, in both normal and disease states...In addition, researchers in the lab
are using electrophysiological recordings, electron microscopy, and computational modeling to understand how
functional networks are constructed and optimized in the neocortex.
(https://www.bio.cmu.edu/labs/barth/index.html)
Batista, Aaron Flexibility and constraints in learning and cognition. Improving brain-computer interfaces. Sensory-motor Google +
coordination. (https://smile.pitt.edu/) (https://scholar.google.com/citations?hl=en&user=kKE_lJUAAAAJ&view_op=list_w
orks&sortby=pubdate)
Behrmann, The major approach I use to address these questions is to study the behavior of human adults who have sustainedLab (https://www.cmu.edu/dietrich/behrmannlab/Publications/index.html) +
Marlene brain damage (usually through stroke or head injury) which selectively affects their ability to carry out these
processes... simulations of artificial neural networks which may be used to model these processes and their
breakdown following brain-damage; and functional neuroimaging studies which examine the biological substrate of
high-level vision. (https://www.cmu.edu/dietrich/behrmannlab/)
Chase, Steven Broadly speaking, my laboratory investigates how sensory feedback impacts the neural representation of motor Lab (http://www.cnbc.cmu.edu/~schase/publications.php) +
intent. One of the major tools we use is the brain-computer interface (BCI)... My research has two main
thrusts. First, I develop novel computational and experimental techniques that leverage BCIs as a research tool
for investigating the neural mechanisms of sensorimotor adaptation and skill acquisition. Second, I design new
BCI decoding algorithms to enhance the performance of these devices and hasten their clinical translation.
(http://www.cnbc.cmu.edu/~schase/)
Cohen, Marlene We are interested in how we use vision to gather information about the world and decide how to act. As Lab (http://www.cohenlab.com/publications.html) +
primates, we perceive the world primarily through our eyes...We use a combination of single and multi-electrode
electrophysiology, psychophysics, and computational techniques. (http://www.cohenlab.com/)
Coutanche, MarcOur lab works at the intersection of neuroscience and psychology, drawing on learning, memory consolidation, Lab (http://www.mcoutanche.com/publications.html) +
sleep, perception, and computer science. (http://thelenslab.org/)
Creswell, DavidDavid’s research focuses broadly on understanding what makes people resilient under stress. Specifically, he Google -?
conducts community intervention studies, laboratory studies of stress and coping, and neuroimaging studies to (https://scholar.google.com/citations?hl=en&user=UzpIzvEAAAAJ&view_op=list_w
understand how various stress management strategies alter coping and stress resilience. orks&sortby=pubdate)
(https://www.cmu.edu/dietrich/psychology/people/core-training-faculty/creswell-david.html)
Danks, David My research largely falls at the intersection of philosophy, cognitive science, and machine learning, using Google +
ideas and frameworks from each to inform the others. My primary research in recent years has been in (https://scholar.google.com/citations?hl=en&user=1lORpNsAAAAJ&view_op=list_w
computational cognitive science: developing fully-specified computational models to describe, predict, and mostorks&sortby=pubdate)
importantly, explain human behavior (in causal cognition, concepts and categories, and most recently,
linguistics). (https://www.cmu.edu/dietrich/philosophy/people/faculty/danks.html)
Doiron, Brent Theoretical Neuroscience. Cellular and synaptic dynamics; Network dynamics and neural coding; Cognitive Google +
processing (http://www.math.pitt.edu/~bdoiron/) (https://scholar.google.com/citations?hl=en&user=2o_bzEUAAAAJ&view_op=list_w
orks&sortby=pubdate)
Eddy, William In the last couple of years I have become keenly interested in the statistical problems associated with fMRI. AGoogle +?
F. typical fMRI experiment run by a cognitive psychologist produces as much as 1 gigabyte of data per hour. The (https://scholar.google.com/scholar?as_ylo=2018&q=William+F.+Eddy&hl=en&as_s
computational challenges are obvious. (http://www.stat.cmu.edu/GSS/eddy.html) dt=0,5)
Erickson, Kirk In The Brain Aging & Cognitive Health Lab we investigate how the mind and brain change with age and the factorsLab (http://bachlab.pitt.edu/publications) =?
that promote successful aging. To do this, we use a variety of neuropsychological assessments, genetic testing,
physical fitness testing, magnetic resonance imaging (MRI) and positron emission tomography (PET).
(http://bachlab.pitt.edu/people/kirk-erickson-phd)
Ermentrout, Olfactory Navigation;Dynamics and phase resetting;Pattern formation in neural systems;Waves and persistent Google +
Bard G. states in neural systems; Modeling the inflammatory response; (http://www.math.pitt.edu/~bard/pubs/lab.html) (https://scholar.google.com/citations?hl=en&user=E73icgUAAAAJ&view_op=list_w
orks&sortby=pubdate)
Fiez, Julie Our basic research examines the neural basis of speech, language, reading, working memory, and learning in Google =?
healthy and patient populations. Complementary applied research draws upon this foundation to inform studies on(https://scholar.google.com/citations?hl=en&user=LQNJQjsAAAAJ&view_op=list_w
effective instruction and intervention in reading and math. We use behavioral measures, magnetic resonance orks&sortby=pubdate)
imaging, magnetoencephalography, and neuropsychological methods to discover how the brain gives rise to the
mind. (https://www.fiezlab.us/)
Gandhi, Neeraj Tricking the brain into high gear: probing the link between attention and intention; Neural coding through Google =?
J. population dynamics; Neural Substrate Underlying Saccades to Moving Targets (http://www.pitt.edu/~neg8/) (https://scholar.google.com/citations?hl=en&user=RCiia08AAAAJ&view_op=list_w
orks&sortby=pubdate)
Genovese, Currently, in neuroscience, I am working with different groups to study the remapping of human's visual +
Christopher R. representation during and after eye movements and the role of the amygdala and pre-frontal cortex in depression
(http://www.stat.cmu.edu/~genovese/?p=research)
Ghuman, Avniel Specifically, we examine the spatiotemporal dynamics of how neural activity reflects the stages of information Lab (http://www.lcnd.pitt.edu/publications.html) =?
processing and how information flow through brain networks responsible for visual perception. We are
particularly interested in the dynamic neural representation of faces, bodies, objects, words, and social and
affective visual images. (http://www.lcnd.pitt.edu/index.html)
Gittis, Aryn Our research seeks to understand how neural circuits in the basal ganglia are organized and function to shape Google =?
movement in health and disease. We use optogenetics, electrophysiology, histology, and behavior to study the (https://scholar.google.com/citations?hl=en&user=FkS0PMEAAAAJ&view_op=list_w
function of neural circuits in brain slices and in vivo. (https://www.bio.cmu.edu/labs/gittis/) orks&sortby=pubdate)
Grover, Pulkit Our lab seeks to attain this understanding through a mix of thought and laboratory experiments, spanning Google =?
examination of fundamental limits all the way to experiments. Current topics of interest include fundamental (https://scholar.google.com/citations?hl=en&user=hklOXvkAAAAJ&view_op=list_w
and practical understanding of circuits and systems for processing and communicating information; flow of orks&sortby=pubdate)
information in neural systems and neural interfaces (and use of this understanding to design radically new
neural interfaces); and understanding information and its use by exploring the union of control and
communication. (http://users.ece.cmu.edu/~pgrover/)
 
 
 
Columbia University
 
- Center for Theoretical Neuroscience. (https://ctn.zuckermaninstitute.columbia.edu/apply)
 
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Abbott, Larry Collaborating with experimentalists. He works with pen and paper, or with computer simulations, to build models of systems other Google +
neuroscientists are studying in their labs. Some models are highly abstract, while others contain considerable biophysical detail. (https://scholar.google.com/citations?user=ca_O-WQAAAA
(https://zuckermaninstitute.columbia.edu/larry-f-abbott-phd) J&hl=en)
Miller, Ken Use theoretical and computational methods to unravel the circuitry of the cerebral cortex, the rules by which this circuitry develops Google +
or "self-organizes", and the computational functions of this circuitry. Our guiding hypothesis - motivated by the stereotypical nature(https://scholar.google.com/citations?hl=en&user=-5Zxg
of cortical circuitry across sensory modalities and, with somewhat more variability, across motor and "higher-order" cortical areas asGsAAAAJ&view_op=list_works&sortby=pubdate)
well - is that there are fundamental computations done by the cortical circuit that are invariant across highly varying input signals.
(https://ctn.zuckermaninstitute.columbia.edu/Ken)
Cunningham, Machine learning and its application to science and industry, including in particular using the tools of artificial intelligence to Lab (http://stat.columbia.edu/~cunningham/) +
John understand biological intelligence and other complex processes. (http://stat.columbia.edu/~cunningham/)
Fusi, Stefano He is using math to better understand how the brain itself computes information, especially as related to problem solving, reasoning PubMed -
and decision-making. (https://zuckermaninstitute.columbia.edu/stefano-fusi-phd) (https://www.ncbi.nlm.nih.gov/pubmed?term=%28Fusi%20S%
5BAuthor%5D%29%20AND%20Columbia%5BAffiliation%5D)
Litwin-Kumar, Learning algorithms and their neural implementations. How do organisms use their past experiences to adapt their current behavior? How =
Ashok do these neural algorithms compare to those studied in machine learning and artificial intelligence? We approach these questions by
working closely with experimental collaborators and building well-constrained models of learning and synaptic plasticity.
(http://lk.zuckermaninstitute.columbia.edu/)
Paninski, LiamI want to build good models of the neural code and use these models to make predictions about mechanisms, decode spike trains, predictLab (http://www.stat.columbia.edu/~liam/cv/) +
responses to novel stimuli, etc. I'm interested in statistical analysis at various levels of the neural code, from ensembles of
simultaneously-recorded spike trains down to voltage fluctuations in individual dendritic compartments.
(http://kavli.columbia.edu/member/paninski)
 
 
 
Johns Hopkins University
 
- Neuroscience at JHU (http://neuroscience.jhu.edu/research/area/3)
- Solomon H. Snyder Department of Neuroscience. (http://neuroscience.jhu.edu/graduate/apply)
 
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Aponte, Yeka Our interest is to understand how genetically-identified cell types and their projections drive behaviors essential for survival. Using the mouse -
as our model system, we apply optogenetics and chemogenetics to manipulate neuronal circuits in awake, behaving mice. In addition, we use a
combination of electrophysiology, two-photon fluorescence endomicroscopy, and behavioral assays to elucidate the neuronal basis of survival
behaviors, such as feeding, and to determine how these neuronal circuits drive the rewarding and addictive nature of food intake.
(http://neuroscience.jhu.edu/research/faculty/2)
Bastian, Amy My laboratory studies the movements of adults and children who have damage or disease of the central nervous system. We are interested in Google -
understanding the mechanisms of different types of movement disorders, as well as how and why different treatments improve movement. We are (https://scholar.google.com/citations?user=
actively studying how new movements are "learned" and what the course of movement recovery following different types brain damage is. XuCieIUAAAAJ&hl=en)
(http://neuroscience.jhu.edu/research/faculty/5)
Shadmehr, Our goal is to understand movement control in humans. Our approach stresses a close integration of the viewpoints from robotics and control Google +
Reza theory with neuroscience to provide a unique perspective on the nature of the biological computations that underlie the control of movements. Our(https://scholar.google.com/citations?user=
ultimate goal is to use the language of mathematics to describe how the various parts of the brain contribute to control of movement in humans. UM8YeikAAAAJ&hl=en)
(http://neuroscience.jhu.edu/research/faculty/80/)
Stuphorn, I am interested in the neurophysiological mechanisms that underlie decision-making and self-control, two essential functions of higher executive Google +
Veit processes. To this end, in my lab we record the activity of single neurons in awake animals that are engaged in decision-making. This allows us (https://scholar.google.com/citations?user=
to identify the types of signals that neurons in specific parts of the brain represent and the computations they carry out. I will also study 3C3nTXwAAAAJ&hl=en)
human subjects in the same tasks with the help of fMRI. These parallel experiments will provide comparative information about decision processes
in human and non-human primates. (http://neuroscience.jhu.edu/research/faculty/86/)
 
 
 
Johns Hopkins University - Janelia Joint Graduate Program
 
- Janelia Labs (https://www.janelia.org/our-research)
- Joint Ph.D. program (https://www.janelia.org/you-janelia/students-postdocs/joint-graduate-program)
 
(#contents)
 
 
 
PI(Ph.D.s)Research AreasResearch+/=/- computational
└──────────┴──────────────┴────────┴───────────────────┘
 
 
 
 
Massachussetts Institute of Technology
 
- Brain + Cognitive Sciences, GRE Institution(3514), (https://bcs.mit.edu/academic-program/graduate/graduate-admissions)
- Center for Brains, Minds and Machines (https://cbmm.mit.edu/about)
 
(#contents)
 
 
 
PI(Ph.D.s) Research Areas Research +/=/
-
comp
utat
iona
l
├──────────────┼─────────────────────────────────────────────────────────────────────────────────────────────────────────────────────────┼───────────────────────────────────────────────────────────────────┼────┤
Bear, Mark Our overarching interest is in the question of how experience and deprivation modify synaptic connections in the brain. Google +
Experience-dependent synaptic plasticity is the physical substrate of memory, sculpts connections during postnatal (https://scholar.google.com/citations?hl=en&user=xobgmhgAAAAJ&view_
development to determine the capabilities and limitations of brain functions, is responsible for the reorganization of op=list_works&sortby=pubdate)
the brain after damage, and is vulnerable in numerous psychiatric and neurological diseases and contributes to their
symptoms. (https://picower.mit.edu/mark-bear)
DiCarlo, JamesDiCarlo’s research goal is to reverse engineer the brain mechanisms that underlie human visual intelligence. He and his Google +
collaborators have revealed how population image transformations carried out by a deep stack of interconnected (https://scholar.google.com/citations?hl=en&user=qenoZwUAAAAJ)
neocortical brain areas — called the primate ventral visual stream — are effortlessly able to extract object identity
from visual images. His team uses a combination of large-scale neurophysiology, brain imaging, direct neural perturbation
methods, and machine learning methods to build and test neurally-mechanistic computational models of the ventral visual
stream and its support of cognition and behavior. (https://mcgovern.mit.edu/profile/james-dicarlo/)
Fee, Michale For the past six years, our laboratory has focused on studying the cellular, circuit, and mechanical underpinnings of Google +
songbird vocalizations. In one current project, we are studying nucleus RA, an area that projects directly to motor (https://scholar.google.com/citations?user=nelvBCQAAAAJ&hl=en)
neurons of the vocal organ. During song, RA neurons each generate a distinctive and reproducible sequence of brief bursts
of spikes. Using a new miniature motorized microdrive developed in this lab (see below), we have been able to record from
large populations of RA neurons (~50) in the singing bird to understand how premotor activity maps to vocal output.
(http://web.mit.edu/feelab/)
Jazayeri, The Jazayeri lab aims to understand the building blocks of cognition. The brain has a remarkable ability to generate Google +
Mehdrad complex behaviors by combining sensory evidence, prior experience, and cost-benefit considerations. Jazayeri’s research (https://scholar.google.com/citations?user=AkJyWbAAAAAJ&hl=en)
probes the neural mechanisms that allow the brain to integrate this plethora of cues, resulting in flexible,
goal-directed behavior. (https://mcgovern.mit.edu/profile/mehrdad-jazayeri/)
Sompolinsky, Sompolinsky’s research goal is to uncover the fundamental principles of the organization, the dynamics and the function Google +
Haim of the brain, viewing the brain through multiscale lenses, spanning the molecular, the cellular, and the circuit levels. (https://scholar.google.com/citations?user=T8o_MdkAAAAJ&hl=en)
To achieve this goal, Sompolinsky has developed new theoretical approaches to computational neuroscience based on the
principles and methods of statistical physics, and physics of dynamical and stochastic systems.
(http://neurophysics.huji.ac.il/)
Sur, Mriganka The Sur laboratory studies the development, plasticity and dynamics of circuits in the cerebral cortex of the brain. The Lab (https://www.surlab.org/sur-publications/) +
developing brain requires a genetic blueprint but is also acutely sensitive to experience and the environment. The adult
brain responds to external stimuli, and modulates these responses by internal states such as attention, through dynamic
changes in information transmission and processing. (https://www.surlab.org/)
Tenenbaum, Current research in our group explores the computational basis of many aspects of human cognition: learning concepts, Google +
Joshua judging similarity, inferring causal connections, forming perceptual representations, learning word meanings and (https://scholar.google.com/citations?hl=en&user=rRJ9wTJMUB8C&view_
syntactic principles in natural language, noticing coincidences and predicting the future, inferring the mental states ofop=list_works&sortby=pubdate)
other people, and constructing intuitive theories of core domains, such as intuitive physics, psychology, biology, or
social structure. (http://web.mit.edu/cocosci/josh.html)
 
 
 
License
 
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To the extent possible under law, Eli Selkin (https://eliselkin.com) has waived all copyright and related or neighboring rights to this work.
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