IntroCompNeuro (Biol635, Math635, Biol432, Math430)

Introduction to Computational Neuroscience

Biol 635 / Math 635 / Biol432 / Math 430

Fall 2022

NJIT HONOR CODE:

Academic Integrity is the cornerstone of higher education and is central to the ideals of this course and the university. Cheating is strictly prohibited and devalues the degree that you are working on. As a member of the NJIT community, it is your responsibility to protect your educational investment by knowing and following the academic code of integrity policy that is found at: Academic Honor Code - University Policy on Academic Integrity.
Please note that it is my professional obligation and responsibility to report any academic misconduct to the Dean of Students Office. Any student found in violation of the code by cheating, plagiarizing or using any online software inappropriately will result in disciplinary action. This may include a failing grade of F, and/or suspension or dismissal from the university. If you have any questions about the code of Academic Integrity, please contact the Dean of Students Office at dos@njit.edu.

Instructor: Horacio G. Rotstein

E-mail: horacio at njit edu

Course Description:

A mathematical and computational introduction to the biophysical mechanisms that underlie physiological functions of single neurons and synapses. Topics include voltage-dependent channel gating mechanisms, the Hodgkin-Huxley model for membrane excitability, repetitive and burst firing, nerve impulse propagation in axons and dendrites, single- and multi-compartmental modeling, synaptic transmission, calcium handling dynamics and calcium dependent currents and processes, dynamical systems tools for the analysis of mechanisms of neural activity.

Textbook:

"An Introductory Course in Computational Neuroscience", by P. Miller - MIT PRess (2018), 1st edition, ISBN: 978-0260238256.
Codes for Figures and Tutorials

Recommended Books:

"Mathematical Foundations of Neuroscience", by G. B. Ermentrout & D. H. Terman - Springer (2010), 1st edition. ISBN 978-0-387-87707-5.

"Dynamical Systems in Neuroscience: The Geometry of Excitability and Bursting", by Eugene M. Izhikevich. The MIT Press, 2007. ISBN 0-262-09043-8

"Foundations of Cellular Neurophysiology", by Daniel Johnston and Samuel M.-S. Wu. The MIT Press, 1995. ISBN 0-262-10053-3.

"Biophysics of Computation - Information processing in single neurons", by Christof Koch. Oxford University Press, 1999. ISBN 0-19-510491-9.

"Theoretical Neuroscience: Computational and Mathematical Modeling of Neural Systems", by Peter Dayan and Larry F. Abbott. The MIT Press,2001. ISBN 0-262-04199-5

Class meets:

Mon & Wed: 1:00pm - 2:20pm
CKB 316

Midterm project presenttions:

TBA (in class)

Office hours:

Wed 4:00-5:30, CKB 420-D or by appointment.

Grading Policy:

Biol635 & Math635 (Graduate):
Homework/Miniprojects, quizzes & class participation: .................. 40%
Projects / Presentations: .................................................................... 30%
Midterm exam/project/presentation: ................................................ 30%
Biol432 & Math430 (Undergraduate):
Homework, quizzes & class participation: ....................................... 40%
Midterm exam: ................................................................................... 30%
Final Exam: ......................................................................................... 30%

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Please note that the University Drop Date deadline will be strictly enforced

Homework Policy
Homework will consist of modeling and simulations exercises on the topics discussed in class. Homework assignments will be posted on this course website (see below).

A number of assignments will be given out during the semester

Assignments must be submitted on canvas

Late homework will not be accepted

The source code used in your calculations MUST accompany the submitted homework

Upon request, students must be able to explain their results and codes

Class Policies:

Attendance and Participation:

Students must attend all classes.
Absences from class will inhibit your ability to fully participate in class discussions and problem solving sessions and, therefore, affect your grade
Tardiness to class is very disruptive to the instructor and students and will not be tolerated

Makeup Exam Policy: There will be no makeup exams, except in rare and extenuating situations where the student has a legitimate reason for missing an exam. The student must notify the NJIT Math office and the Instructor that he/she will miss an exam. In all cases, the student must present written verifiable proof of the reason for missing the exam, e.g., a doctor's note, police report, court notice, etc., clearly stating the date AND times of the mitigating problem.

Cellular Phones: All cellular phones, beepers and other electronic devices must be switched off during class and exam times (except when specifically allowed by the instructor).

Chatting in class using electronic devices will not be tolerated.

Course Material

Homework

Course Outline:

Week Topics of the Class Notes

1
Introduction to the course
Introduction to Computational Neuroscience and neural dynamics
Passive membrane properties - The passive membrane equation
LN-01
LN-02
LN-03

2
Ordinary differential equations (ODEs) - Review of analytical methods
Ordinary differential equations (ODEs) - Review of numerical methods
LN-04
Matlab Tutorial (KK)
ODE Templates (HGR)

3
Dynamics of the passive membrane equation LN-05

4
Integrate-and-fire models
The Hodgkin-Huxley model I

LN-06
LN-07

5
The Hodgkin-Huxley model II
The cable equation
LN-08

6
The cable equation II
Introduction to dynamical systems methods for neural models
Reduced one- and two-dimensional neural models

LN-09

7
One-dimensional neural models: Phase-space analysis I LN-10

8
Two-dimensional neural models: Phase-space analysis I LN-11

9
Two-dimensional neural models: Phase-space analysis II LN-11

10
Subthreshold oscillations: Two- and three-dimensional models
and
Subthreshold and suprathreshold resonance

11
Bursting: three-dimensional models LN-12

12
Synaptic Dynamics
Network Dynamics
LN-13
LN-14
LN-15

13
Project Presentations

14
Project Presentations

15
Project Presentations

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Department of Mathematical Sciences(DMS).
New Jersey Institute of Technology (NJIT).

Horacio
Last modified: Sun Oct 31 13:16:02 EDT 2010

*Week*	*Topics of the Class*	*Notes*
1	Introduction to the course Introduction to Computational Neuroscience and neural dynamics Passive membrane properties - The passive membrane equation	LN-01 LN-02 LN-03
2	Ordinary differential equations (ODEs) - Review of analytical methods Ordinary differential equations (ODEs) - Review of numerical methods	LN-04 Matlab Tutorial (KK) ODE Templates (HGR)
3	Dynamics of the passive membrane equation	LN-05
4	Integrate-and-fire models The Hodgkin-Huxley model I	LN-06 LN-07
5	The Hodgkin-Huxley model II The cable equation	LN-08
6	The cable equation II Introduction to dynamical systems methods for neural models Reduced one- and two-dimensional neural models	LN-09
7	One-dimensional neural models: Phase-space analysis I	LN-10
8	Two-dimensional neural models: Phase-space analysis I	LN-11
9	Two-dimensional neural models: Phase-space analysis II	LN-11
10	Subthreshold oscillations: Two- and three-dimensional models and Subthreshold and suprathreshold resonance
11	Bursting: three-dimensional models	LN-12
12	Synaptic Dynamics Network Dynamics	LN-13 LN-14 LN-15
13	Project Presentations
14	Project Presentations
15	Project Presentations