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BME 6938 Neurodynamics

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BME 6938 Neurodynamics Instructor: Dr Sachin S Talathi – PowerPoint PPT presentation

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Title: BME 6938 Neurodynamics


1
BME 6938Neurodynamics
  • Instructor Dr Sachin S Talathi

2
Recap-2D linear dynamical system-Explicit solution
OR
3
Recap- Eigen values for 2D system
4
Classification Scheme for fixed points
  • We saw how to get explicit solution to any
    2-dimensional linear ODE.
  • However if we are interested in global properties
    of the trajectories explicit solutions are
    unnecessary
  • The eigen values of A give us all the information
    about the stability properties of the fixed
    points of the system and we can devise
    classification scheme based on the eigenvalues
    for the system

5
Classification Scheme for fixed points
  • Case I saddle node
  • Case II
  • (a) either stable or
    unstable node
  • (b) either stable or unstable spiral
  • (c) border line between nodes
    and spirals
  • Case III one of the eigenvalues
    is zero no isolated fixed point but a series of
    fixed points (centers)

6
Summary of the classification scheme
Degenerate nodes
7
Dynamics around fixed point based on previous
analysis
8
Invariant Manifolds
  • The eigenvectors of A corresponding to the cases
    with non-degenerate eigenvalues considered
    earlier represent invariant manifolds for the
    dynamical system.
  • Eg. Lets say the phase space is 2 dimensional
    made up of dynamical variables x and y. If
    initial condition is on x-axis and the flow as
    the system evolves remains on x-axis then x-axis
    is the invariant manifold of the dynamical
    system.
  • In other words, orbits that start on the manifold
    remain in it.

Refer to class notes for more details on
Invariant manifolds
9
Examples of Invariant Manifold
  • Invariant manifolds of saddle (1-Dimensional
    manifolds)
  • Spirals (II-Dimensional manifolds)

10
Linear Stability Analysis for Nonlinear
Two-Dimensional System
Evaluated at the fixed point (x, y)
11
Few comments
  • The Linearized system does represent the dynamics
    of the nonlinear system locally around the fixed
    point correctly (Stable manifold theorem or the
    Hartman-Grobman Theorem) when the real part of
    eigenvalues are non-zero.
  • Fixed point in these case are referred to as the
    hyperbolic fixed points. The contribution from
    nonlinear higher order terms is negligible
    locally around hyperbolic fixed points.
  • Nonhyperbolic fixed points are those for which
    the real part of eigenvalue is zero. They are
    more sensitive to higher order nonlinear terms
    eg Centers Bifurcation points etc..

12
Stable and Unstable Manifolds of Saddle
Unstable manifold v1
Stable manifold v2
Stable manifold of saddle is also referred to as
the seperatrix since it separates the phase
plane into different regions of long term behavior
13
Revisit a simple example
We saw the phase space for this system earlier
in our class. Lets Revisit and now Identify the
stable and unstable manifolds of the saddle node
(This time using XPPAUTO)
14
Important of stable manifold of saddle in
Neurodynamics
Note Threshold is not a single voltage
value. It is a curve in Phase space defined by
the Stable manifold Of saddle
Ex3.ode with parameters for type 1
neuron-gtGenerate above figure
15
Homoclinic and Heteroclinic Trajectories
A trajectory is homoclinic if it originates from
and terminates at the same equilibrium point
A trajectory is heteroclinic if it originates at
one equilibrium and terminates at a different
equilibrium point
16
Heteroclinic and Homoclinic orbits in Neuron model
Homoclinic Orbit Ex3.ode (High Threshold fast
(tau0.152) K current)
Heteroclinic Orbit Ex3.ode (High threshold
K-current)
17
Transition to Spiking
Saddle Node Bifurcation
Hopf Bifurcation
18
Saddle Node Bifurcation in Phase Space
I3
I10
I4.51
19
Hopf Bifurcation in Phase Space
20
Minimal models for spiking
  • Minimal (conductance based) model for neuronal
    dynamics is a model that satisfies the following
    two criteria
  • It has a limit cycle attractor
  • If one removes any current or gating variable,
    the model only has fixed point equilibrium
    attractors
  • Any conductance based model is either a minimal
    model or can be reduced to a minimal model by
    appropriately removing the gating variables

21
Constructing a Mimimal model for Neuronal Dynamics
  • Mixture of one amplifying and one resonant gating
    variable with a leak current results in a minimal
    model
  • Amplifying Gating Variable Provide positive
    feedback through the interaction with membrane
    voltage. Eg. Activation gating variable of sodium
    channel carrying inward current (m-gating in HH
    model)
  • Resonant Gating Variable Provide negative
    feedback through the interaction with membrane
    voltage. Eg. Activation gating variable of the
    potassium channel carrying outward
    current(n-gating in HH model)

22
Amplifying vs. Resonating Gate Variables
  • Does the following make sense?
  • To generate a spike we need
  • fast positive feedback and
  • slow negative feedback

What if we have slow positive feedback? Act as a
low pass filter No effect on fast frequencies
and amplifying slow fluctuations.
What if we have fast negative feedback? It will
damp input fluctuations. Stabilize the fixed
point of the system
23
Minimal models
  • Activation Inward (AI) Amplify
  • Activation Outward (AO) Resonate
  • In-Activation Inward (II) Resonate
  • In-Activation Outward (IO) Amplify

Currents
Minimal Models
Total of 6 minimal models (and not 4)
24
Commonly observed minimal models
INa,pIK model
25
Dynamic repertoire for INa-pIK model
Low threshold K currents Hopf- bifurcation
High threshold K currents Saddle node
bifurcation
26
INa,t Model
Mechanism for spiking
27
Dynamic repertoire for INa-t model
  • Note
  • V- Nullcline looks like a
  • cubic parabola
  • 2. h-axis is flipped
  • to preserve counter clock
  • wise rotation
  • 3. For right choice of parameters
  • we can get both saddle node and
  • Hopf Bifurcations

28
Seminal paper by Rinzel and Ermentrout
  • Read the paper by Rinzel and Ermentrout that
    explains most of the ideas we have studied so far
    for exploring the dynamics of neuronal models.
  • Read sections 1 through 3 in the paper and
    reproduce the results using XPPAUTO (Homework)

29
HH model Revisited
  • HH Equation for membrane dynamics of giant squid
    axon

Parameter Values
gNa 120 mS/cm2
gK 36 mS/cm2
gL 0.3 mS/cm2
ENa 55 mV
EK -72 mV
EL -50 mV
Vm -60 mV
30
Typical Bifurcation Structure in HH model
31
Reducing HH model
  • Original HH model is 4 dimensional.
  • We have learned tools to study the dynamics
    exhibited by two dimensional neuron models
    (Remember the minimal models)
  • Lets try to reduce the 4-D HH model to 2-D HH
    model without sacrificing the Bifurcation
    Structure around the transition to spiking state

32
Reducing HH model
  • Step 1. Note the m-gate dynamics is much faster
    than the h and n gate dynamics
  • Replace

33
Reducing HH model
  • Step 2. Note
  • Replace

34
The Reduced HH model is
Parameter Values
gNa 120 mS/cm2
gK 36 mS/cm2
gL 0.3 mS/cm2
ENa 55 mV
EK -72 mV
EL -50 mV
Vm -60 mV
Does the reduced HH model represent a minimal
model?
35
Lets look at the shapes of AP in full and reduced
HH model
36
Hodgkin Classification of Excitability
  • Class 1 (Type 1) Excitability
  • Action potentials can be generated with
    arbitrarily low frequency. The Frequency
    increases by increasing the applied current
  • Class 1 excitability is seen when the rest
    potential disappears through saddle node
    bifurcation (mostly true)
  • Class II (Type II) Excitability
  • Action potentials are generated in certain
    frequency bands that are relatively insensitive
    in the strength of applied current
  • Class II excitability is seen when the rest
    potential disappears through Hopf bifurcation
    (again mostly true)

37
Hodgkin Classification
38
Bifurcations in 2D neuron models-Phase Space
Class I
Bistable
Class II
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