Total: 65 as of 10:30 PM EDT 20121014
Session Time |
# & Type |
Board # |
Authors & Institutions |
Abstract Title |
Sat 10/13 1:00 PM |
45.14 |
D26 |
A. LEGENDRE1, F. PERNOT1, A. F. KELLER1, R. GREGET1, N. AMBERT1, J.-M. C. BOUTEILLER2,1, S. BISCHOFF1, T. W. BERGER2, *M. BAUDRY3,1; 1Rhenovia Pharma, Mulhouse, France; 2Biomed. Engin., USC, Los Angeles, CA; 3Western Univ. of Hlth. Sci., Pomona, CA |
Is LTP an all-or-none phenomenon
at glutamatergic synapses? A biosimulation approach incorporating
the search for cognitive enhancers |
Sun 10/14 8:00 AM |
144.24 |
D37 |
*A. MOHAN, C. STRICKER; Neurosci., Australian Natl. Univ., Canberra, Australia |
Short-term synaptic depression and neuronal spiking dynamics
together tune integration and coincidence detection properties of
neurons |
Sun 10/14 8:00 AM |
159.08 |
L4 |
*N. VLADIMIROV, Y. TU, R. D. TRAUB; Theoretical Physics, IBM TJ Watson Res. Ctr., Yorktown Heights, NY |
Fast ripples (200-300 Hz) simulated in axonal networks: role
of loops, spike failures and axonal gap junctions |
Sun 10/14 8:00 AM |
207.09 |
DDD33 |
R. L. ARLOW1,2, T. J. FOUTZ2, *C. C. MCINTYRE1; 1Biomed. Engin., Cleveland Clin. Fndn., Cleveland, OH; 2Case Western Reserve Univ., Cleveland, OH |
Theoretical principals underlying optogenetic stimulation of
the peripheral nervous system |
Sun 10/14 1:30 PM |
210.05 |
|
T. J. Sejnowski; Salk Institute, Howard Hughes Med Inst, La Jolla, CA. |
From cell to circuit: Hodgkin-Huxley models in computational
neuroscience |
236.03 |
C13 |
J. D. FINEBERG1, D. M. RITTER2,
*M. L. COVARRUBIAS2; |
Neurophysiological impact and modeling-independent elucidation
of inactivation pathways in A-type K+ channels |
|
Sun 10/14 1:00 PM |
238.02 |
C51 |
*J.-M. C. BOUTEILLER1,3, S. L. ALLAM1, E. Y. HU1, V. S. GHADERI2, A. LEGENDRE3, N. AMBERT3, R. GREGET3, M. SARMIS3, A. F. KELLER3, F. PERNOT3, S. BISCHOFF3, M. BAUDRY4,3, T. W. BERGER1,3; 1Biomed. Engin., USC, LOS ANGELES, CA; 2Electrical Engin., USC, Los Angeles, CA; 3Rhenovia Pharma, Mulhouse, France; 4Grad. Col. of Biomed. Sci., Western Univ. of Hlth. Sci., Pomona, CA |
Multi-scale modeling and simulation of the glutamatergic -
Gabaergic transmission: Influence of synaptic parameters on
neuronal spiking |
Sun 10/14 1:00 PM |
238.06 |
C55 |
*H. HU, P. JONAS; Inst. of Sci. and Technol. Austria (IST Austria), Klosterneuburg, Austria |
Robust initiation and propagation of action potentials in the
axon of fast-spiking, parvalbumin-expressing basket
cells |
Sun 10/14 1:00 PM |
238.11 |
C60 |
*T. BRANCO, M. HAUSSER; Wolfson Inst. for Biomed. Res., Univ. Col. London, London, United Kingdom |
Dendritic computation under in vivo-like
conditions |
Sun 10/14 1:00 PM |
238.13 |
C62 |
H. HAYAKAWA1, T. KAMIJO1, Y. FUKUSIMA3, H. HAYASHI4, *E. HIDA2, T. AIHARA1; 1Grad. Sch. of Brain Sci., Tamagawa Univ., Tokyo, Japan; 2Tamagawa Univ., Machida 194, Japan; 3Fac. of Med. Welfare, Kawasaki Univ. of Med. Welfare, Kawasaki, Japan; 4Kyushu Inst. of Technol., Fukuoka, Japan |
Spatio-temporal interaction between lateral and medial
dendritic inputs in hippocampal granule cell. |
Sun 10/14 1:00 PM |
268.05 |
DD3 |
S. DRUCKMANN1, E. HAY2, *W. VAN GEIT3, F. SCHÜRMANN3, H. MARKRAM3, I. SEGEV2; 1Janelia Farm Res. Campus, Howard Hughes Med. Inst., Ashburn, VA; 2Dept. of Neurobio., The Hebrew Univ. of Jerusalem, Jerusalem, Israel; 3EPFL Blue Brain Project, Lausanne, Switzerland |
A unifying model of the neocortical column 5: Electrical cell
types |
Sun 10/14 1:00 PM |
268.06 |
DD4 |
W. VAN GEIT1, E. HAY2, J.-D. COURCOL1, S. DRUCKMANN3, J. KING1, F. SCHÜRMANN1, *Y. WANG4,5, H. MARKRAM1, I. SEGEV2; 1Blue Brain Project, Brain Mind Institute, EPFL, Lausanne, Switzerland; 2Dept. of Neurobio., The Hebrew Univ. of Jerusalem, Jerusalem, Israel; 3Janelia Farm Res. Campus, Howard Hughes Med. Inst., Ashburn, VA; 4Steward SEMC, Tufts Univ. Med. Sch., BOSTON, MA; 5Wenzhou Med. Col., Zhejiang, China |
A unifying model of the neocortical column 6:
Morpho-electrical cell types |
Sun 10/14 1:00 PM |
268.12 |
DD10 |
A. GIDON1, M. REIMANN2, F. SCHÜRMANN2, *I. SEGEV1, H. MARKRAM2; 1Inst. Of Life Sci., Jerusalem 91904, Israel; 2Blue Brain Project, Brain Mind Inst., EPFL, Lausanne, Switzerland |
A Unifying Model of the Neocortical Column 12: Coverage and
functional impact of synaptic inhibition in cortical
dendrites |
Sun 10/14 1:00 PM |
268.14 |
DD12 |
*M.-O. GEWALTIG1, V. DELATTRE1, S. HILL1, E. MULLER1, M. REIMANN1, F. SCHÜRMANN1, I. SEGEV2, W. MAASS3, H. MARKRAM1; 1Blue Brain Project, Brain Mind Institute, EPFL, Lausanne, Switzerland; 2Dept. of Neurobio., The Hebrew Univ. of Jerusalem, Jerusalem, Israel; 3Inst. for Theoretical Computer Sci., Technische Univ. Graz, Graz, Austria |
A unifying model of the neocortical column 14: Learned
functional properties |
Sun 10/14 1:00 PM |
268.15 |
DD13 |
F. DELALONDRE1, M. ABDELLAH1, C. AGUADO SANCHEZ1, A. BILGILI1, N. BUNCIC1, J.-D. COURCOL1, S. EILEMANN1, V. HAENEL1, S. L. HILL1, T. HEINIS2,1, J. B. HERNANDO3, M. HINES4, J. G. KING1, E. MULLER1, B. R. C. MAGALHAES1, G. MATEESCU1, J. MULLER1, K. MUTHURASA1, D. NACHBAUR1, L. PASTOR5, J. M. PENA3, *R. RANJAN1, M. W. REIMANN1, F. TAUHEED2,1, W. VAN GEIT1, A. AILAMAKI2, H. MARKRAM1, F. SCHÜRMANN1; 1Blue Brain Project, Brain Mind Institute, EPFL, Lausanne, Switzerland; 2Data-Intensive Applications and Systems Lab, EPFL, Lausanne, Switzerland; 3CeSViMa, Univ. Politecnica de Madrid, Madrid, Spain; 4Dept. of Neurobio., Yale Univ., New Haven, CT; 5Modeling and Virtual Reality Group, Univ. Rey Juan Carlos, Madrid, Spain |
A unifying model of the neocortical column 15: High
performance computing and software development challenges |
Sun 10/14 1:00 PM |
268.18 |
DD16 |
*E. LOGETTE1, R. RANJAN1, S. PETITPREZ1, G. KHAZEN2, F. SCHÜRMANN1, H. MARKRAM1; 1Brain Mind Institute, Ecole Polytechnique Fédérale De Lausanne (EPFL), Lausanne, Switzerland; 2Computer Sci. & Mathematics Dept., Lebanese American Univ., Byblos, Lebanon |
A unifying model of the neocortical column 18: Refining 2, the
channelome and channelpedia |
Sun 10/14 1:00 PM |
269.03 |
EE1 |
*C. E. SCHOONOVER1, J. C. TAPIA2, V. SCHILLING3, V. C. WIMMER4, R. BLAZESKI2, C. A. MASON2, R. M. BRUNO2; 1Neurobio. & Behavior, Columbia Univ., NEW YORK, NY; 2Neurosci., Columbia University, Col. of Physicians and Surgeons, New York, NY; 3Max Planck Inst., Heidelberg, Germany; 4Howard Florey Institute, Univ. of Melbourne, Parkville, Australia |
Spatial distribution and efficacy of thalamocortical synapses
onto layer 4 excitatory neurons |
Sun 10/14 1:00 PM |
272.11 |
HH13 |
*C. GUNAY1, F. H. SIELING2, L. DHARMAR1, W.-H. LIN3, R. MARLEY3, R. A. BAINES3, A. A. PRINZ1; 1Biol., Emory Univ., ATLANTA, GA; 2Biomed. Engin., Georgia Inst. Tech. and Emory Univ., ATLANTA, GA; 3Fac. of Life Sci., Univ. of Machester, Manchester, United Kingdom |
A computational model of an identified larval Drosophila
motoneuron for studying functional changes in ion channels as a
result of genetic modification |
275.02 |
KK11 |
*G. L. CHADDERDON III1, S. A. NEYMOTIN1,
C. C. KERR1,3, J. T. FRANCIS1, W. W.
LYTTON1,2,4; |
Dopamine-based reinforcement learning of virtual arm reaching
task in a spiking model of motor cortex |
|
Sun 10/14 1:00 PM |
280.14 |
QQ13 |
*J. A. VARELA1, J. WANG1, J. CHRISTIANSON2, S. MAIER2, D. COOPER1; 1Inst. for Behavioral Genet., 2Psychology and Neurosci., Univ. of Colorado, Boulder, CO |
Control over stress, but not stress per se increases
prefrontal cortical pyramidal neuron excitability. |
Sun 10/14 1:00 PM |
300.03 |
DDD47 |
*S. F. LEMPKA, C. C. MCINTYRE; Cleveland Clin., Cleveland, OH |
Theoretical analysis of local field potential
recordings |
Sun 10/14 1:00 PM |
300.06 |
DDD50 |
*C. WARRENDER, J. B. AIMONE, C. TEETER, R. SCHIEK; Sandia Natl. Labs., ALBUQUERQUE, NM |
Population activity in large recurrent
networks |
Sun 10/14 1:00 PM |
301.08 |
DDD82 |
*H. A. GEERTS, A. SPIROS, P. ROBERTS; |
Re-engineering AD symptomatic drugs research &
development: failure analysis of dimebon using quantitative
systems pharmacology |
301.11 |
EEE1 |
*M. CAPOGROSSO1,2, S. RASPOPOVIC1,2,
L. BASSI LUCIANI1, N. WENGER3, P.
MUSIENKO3,4, G. COURTINE3, S. MICERA2,1;
|
Selectivity of a multi electrode array for epidural electrical
stimulation of the spinal cord: a rat computational
model. |
|
301.16 |
EEE6 |
*C. KERR1,2, S. J. VAN ALBADA3,
S. A. NEYMOTIN1,4, G. L. CHADDERDON1, P. A.
ROBINSON2,5, W. W. LYTTON1,6; |
Effects of basal ganglia on cortical computation: A hybrid
network/neural field model |
|
301.18 |
EEE8 |
*S. A. NEYMOTIN1,2,4, G. L. CHADDERDON3,
C. C. KERR3,5, J. T. FRANCIS3, W. W.
LYTTON3,6; |
Reinforcement learning of 2-joint virtual arm reaching in
computer model of sensory and motor cortex |
|
Sun 10/14 1:00 PM |
301.28 |
EEE18 |
*R. A. MCDOUGAL1, M. L. HINES1, W. W. LYTTON2,3; 1Neurobio., Yale Univ., New Haven, CT; 2Physiol. & Pharmacol., SUNY Downstate Med. Ctr., Brooklyn, NY; 3Kings County Hosp., Brooklyn, NY |
Calcium-electrical interactions: An example of
reaction-diffusion in the neuron simulator. |
301.29 |
EEE19 |
*M. A. SHERIF1,2,3, J. M. BARRY4,
S. A. NEYMOTIN2, W. W. LYTTON2,5,3;
|
CPP alters cross-frequency coupling between theta and gamma in
CA1 in rats: Simulation and experiment |
|
Mon 10/15 8:00 AM |
335.07 |
E6 |
*T. M. MORSE, N. T. CARNEVALE, C. Q. CHIU, G. M. SHEPHERD, M. J. HIGLEY; Neurobio., Yale Univ. Sch. Med., New Haven, CT |
Compartmentalized synaptic inhibition of spines in a model
dendrite |
Mon 10/15 8:00 AM |
338.03 |
E51 |
*S. BALAKRISHNAN, R. A. PEARCE; Anesthesiol., Univ. Wisconsin, Madison, Madison, WI |
NEURON model of 16-site extracellular theta oscillations in
the CA1 region of the hippocampus: A CSD
analysis |
Mon 10/15 8:00 AM |
340.01 |
F2 |
S. D. BERGER1, S. M. BAER2, *S. M. CROOK3; 1Interdisciplinary Neurosci. PhD Program, 2Sch. of Mathematical and Statistical Sci., 3Sch. of Mathematics & Statistics, Arizona State Univ., TEMPE, AZ |
Estimation of electrical properties of dendrites with branches
using a continuum modeling formulation |
340.05 |
F6 |
*S. ASHHAD, R. NARAYANAN; |
The A-type potassium current regulates ER calcium release
through inositol triphosphate receptors in a hippocampal
pyramidal cell model |
|
Mon 10/15 8:00 AM |
340.08 |
F9 |
*C. D. ROMAIN1,2,3, R. D. CAZE1,2,3, M. D. HUMPHRIES1,3,4, B. S. GUTKIN1,3; 1ENS, Paris, France; 2Paris 7 Diderot, Paris, France; 3INSERM U960, Paris, France; 4Univ. of Sheffield, Sheffield, United Kingdom |
A broadly tuned saturating dendritic branch is sufficient to
expand single neuron computation capacity |
Mon 10/15 8:00 AM |
340.16 |
F17 |
*S. J. COX1,2, K. HEDRICK1, R. DEWELL2, F. GABBIANI1,2; 1Rice Univ., HOUSTON, TX; 2Baylor Col. of Med., Houston, TX |
Biophysical model of HCN channels and their role in collision
avoidance |
Mon 10/15 8:00 AM |
340.18 |
F19 |
J. K. KIM, *C. D. FIORILLO; Bio and Brain Engin., KAIST, Daejeon, Korea, Republic of |
A-type potassium channels as a mechanism for predictive
homeostasis of membrane excitability |
Mon 10/15 8:00 AM |
395.13 |
DDD82 |
*D. KIM1, D. PARE2, S. S. NAIR1; 1Dept. of Electrical and Computer Engg, Univ. of Missouri- Columbia, Columbia, MO; 2Ctr. for Mol. and Behavioral Neurosci., Rutgers State Univ., Newark, NJ |
Formation of distinct cell populations in the lateral amygdala
after auditory fear conditioning - A computational
model |
Mon 10/15 8:00 AM |
395.14 |
DDD83 |
D. KIM, S. PRANIT, Y. CHEN, *S. S. NAIR; Electrical & Computer Engin., Univ. Missouri-Columbia, COLUMBIA, MO |
Development of reduced order biologically realistic cell
models |
Mon 10/15 8:00 AM |
395.15 |
DDD84 |
*C. FRANKLIN, A. HUMMOS, V. S. K. GUNTU, S. S. NAIR; Univ. of Missouri, Columbia, MO |
A biologically realistic computational model of the
hippocampus |
Mon 10/15 8:00 AM |
397.14 |
EEE36 |
*G. J. YU, B. S. ROBINSON, P. HENDRICKSON, D. SONG, T. W. BERGER; USC, Los Angeles, CA |
Significance of topographically constrained connectivity for a
large-scale model of the hippocampus |
Mon 10/15 8:00 AM |
397.15 |
EEE37 |
*P. HENDRICKSON, G. J. YU, B. S. ROBINSON, D. SONG, T. W. BERGER; USC, Los Angeles, CA |
Creation of a large-scale, biologically realistic model of the
hippocampus |
Mon 10/15 8:00 AM |
397.16 |
EEE38 |
*B. ROBINSON, G. J. YU, P. HENDRICKSON, D. SONG, T. W. BERGER; Biomed. Engin., USC, Los Angeles, CA |
Incorporation of synaptic plasticity rules in a large-scale
model of the hippocampus |
Mon 10/15 1:00 PM |
433.02 |
C21 |
*V. SEKULIC1,3, J. J. LAWRENCE4,5, F. K. SKINNER3,2,1; 1Physiol., 2Med. (Neurology), Univ. of Toronto, Toronto, ON, Canada; 3Toronto Western Res. Inst., Univ. Hlth. Network, Toronto, ON, Canada; 4Biomed. and Pharmaceut. Sci., 5NIH COBRE Ctr. for Structural and Functional Neurosci., Univ. of Montana, Missoula, MT |
Using model databases to determine dendritic distributions of
Ih channels in oriens-lacunosum/moleculare hippocampal
interneurons |
Mon 10/15 1:00 PM |
435.13 |
C56 |
*C.-L. HSU, Y. KIM, N. SPRUSTON; Janelia Farm Res. Campus, Howard Hughes Med. Inst., Ashburn, VA |
A crucial role of dendritic voltage-gated sodium channels in
calcium signaling and long-term potentiation induction in the
tuft dendrites of hippocampal CA1 pyramidal
neurons |
435.15 |
C58 |
*S. P. VAIDYA, D. JOHNSTON; |
HCN channels contribute to the spatial synchrony of theta
frequency synaptic inputs in CA1 pyramidal neurons |
|
Mon 10/15 1:00 PM |
477.25 |
LL14 |
F. LOCATELLI1, S. SUBRAMANIYAM1, F. PRESTORI1,2, S. SOLINAS2, *L. MAPELLI1, S. MASETTO1, E. D'ANGELO1,2; 1Dept of Neurosci., Univ. of Pavia, Pavia, Italy; 2IRCCS C. Mondino, Pavia, Italy |
Multiple bursting evoked by mossy fiber bundle stimulation in
unipolar brush cells: Experimental evidence and computational
modeling |
477.26 |
LL15 |
*C. RÖSSERT1, P. DEAN1, S.
SOLINAS2, E. D’ANGELO2, J. PORRILL1;
|
Analysis of a detailed model of granular layer processing: can
it support the computations required by the adaptive filter model
of the cerebellum? |
|
477.28 |
LL17 |
*E. D'ANGELO1,2, P. LOMBARDO1, D.
GANDOLFI1,3, J. MAPELLI3, S. SOLINAS2;
|
Theta-frequency resonance in the cerebellum granular layer
circuit |
|
Tue 10/16 8:00 AM |
532.07 |
B34 |
*A. KELLER1, N. AMBERT1, A. LEGENDRE1, F. PERNOT1, R. GREGET1, J.-M. C. BOUTEILLER1,2, T. W. BERGER2,1, M. BAUDRY1,3, S. BISCHOFF1; 1Rhenovia Pharma, Mulhouse, France; 2Biomed. Engin., USC, Los Angeles, CA; 3Grad. Col. of Biomed. Sci., Western Univ. of Hlth. Sci., Pomona, CA |
Why are nicotinic receptor agonists failing in clinical
trials? Lessons from biosimulation of alpha7 neuronal nicotinic
receptors. |
Tue 10/16 8:00 AM |
540.16 |
D47 |
Y. SWEENEY1, *M. H. HENNIG2; 1Doctoral Training Ctr. in Neuroinformatics and Computat. Neurosci., Univ. of Edinburgh, Edinburgh, United Kingdom; 2Edinburgh Univ., Edinburgh, United Kingdom |
Modeling homeostatic control of intrinsic excitability in
single neurons |
Tue 10/16 8:00 AM |
540.25 |
D56 |
*W. R. HOLMES, X. LI; Biol. Sci., Ohio Univ., Athens, OH |
Modeling the role of morphology in frequency-dependent action
potential failures in CA3 pyramidal cell axons |
Tue 10/16 8:00 AM |
577.30 |
MM6 |
*P. S. SAMARTH1, J. L. RANSDELL2, D. J. SCHULZ2, S. S. NAIR1; 1Electrical Engin., 2Biol. Sci., Univ. of Missouri Columbia, Columbia, MO |
Compensation mechanisms to preserve single cell and network
outputs |
648.19 |
F6 |
*C. M. WEAVER1, J. M. AMATRUDO2,
J. L. CRIMINS2, J. I. LUEBKE2;
|
Highly distinctive structural and physiological properties of
layer 2/3 pyramidal neurons in the primary visual versus
dorsolateral prefrontal cortices of rhesus monkey |
|
Tue 10/16 1:00 PM |
677.11 |
KK11 |
*J. A. HOKANSON1, C. AYERS1, R. GAUNT2, D. WEBER2; 1Bioengineering, 2Physical Med. & Rehabil., Univ. of Pittsburgh, Pittsburgh, PA |
Nonlinear recruitment of primary afferent neurons from
simultaneous stimulation. |
Tue 10/16 1:00 PM |
711.08 |
FFF38 |
*M. J. BEZAIRE, I. SOLTESZ; Anat. & Neurobio., Univ. of California At Irvine, Irvine, CA |
Interneuron type-specific contributions to CA1 network
activity in a data-driven computer model |
711.10 |
FFF40 |
*L. JIN1, B. F. BEHABADI2, B.
MEL3; |
Dimensionality of Dendritic Computation |
|
Tue 10/16 1:00 PM |
711.14 |
FFF44 |
*C. SCHNEIDER, M. CASE, I. SOLTESZ; Anat. and Neurobio., Univ. of California, Irvine, Irvine, CA |
Enlargement and improvement of a computational model of the
rat dentate gyrus |
711.16 |
FFF46 |
*P. D. ROBERTS1, A. SPIROS1, H.
GEERTS2; |
A biophysical computational model to guide drug development
for disorders involving the basal ganglia |
|
Tue 10/16 1:00 PM |
712.07 |
FFF67 |
*O. WALCH1, S. FAUGHT1, C. HU2, D. FORGER1, K. WONG2; 1Mathematics, 2Opthalmology and Visual Sci., Univ. of Michigan, Ann Arbor, MI |
Modeling the electrophysiology of intrinsically photosensitive
retinal ganglion cells |
Wed 10/17 8:00 AM |
759.13 |
M9 |
*K. GUNALAN1,2, A. M. NOECKER2, K. TALJAN1,2, K. E. SAKAIE3, C. C. MCINTYRE1,2; 1Biomed. Engin., Case Western Reserve Univ., Cleveland, OH; 2Biomed. Engin., 3Diagnos. Radiology, Cleveland Clin. Fndn., Cleveland, OH |
Hyperdirect pathway activation and its association with
clinical outcomes from subthalamic deep brain stimulation in
Parkinson’s disease |
761.06 |
N12 |
*L. M. ZITELLA, K. MOHSENIAN, C. GLOECKNER, M. D.
JOHNSON; |
A computational modeling study comparing pedunculopontine
nucleus stimulation in human and non-human
primates |
|
761.07 |
N13 |
*B. A. TEPLITZKY1, A. T. CONNOLLY1,
J. A. BAJWA2, F. M. K. SURI3, A. I.
QURESHI3, M. D. JOHNSON4,1; |
An endovascular approach to deep brain stimulation:
Computational modeling of anatomical targets |
|
Wed 10/17 8:00 AM |
761.12 |
N18 |
*Y. XIAO, M. JOHNSON; Biomed. Engin., Univ. of Minnesota, Minneapolis, MN |
Algorithms for localizing deep brain stimulation leads in
vivo |
Wed 10/17 8:00 AM |
792.19 |
XX2 |
*C. K. OVERSTREET1, J. D. KLEIN2, S. I. HELMS TILLERY1; 1Sch. of Biol. and Hlth. Systems Engin., 2Interdisciplinary Grad. Program in Neurosci., Arizona State Univ., Tempe, AZ |
Excitation of distinct pools of somatosensory neurons via
intracortical microstimulation |
Wed 10/17 1:00 PM |
859.08 |
I3 |
*F. J. PERNOT1, R. GREGET1, S. BISCHOFF1, J.-M. C. BOUTEILLER1,2, M. BAUDRY1,3; 1RHENOVIA PHARMA, Mulhouse, France; 2Biomed. Engin., USC, Los Angeles, CA; 3Grad. Col. of Biomed. Sci., Western Univ. of Hlth. Sci., Pomona, CA |
Development of a striatum modeling and simulation platform to
identify treatments for Huntington’s disease |