/
hh_temperature_excite.m
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hh_temperature_excite.m
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%********************************************************************
%-------------HH model use Runge-Kutta method .m-------------------
%axon diameter=2(um);T=18.5(centidegree)(291.5K);length of the axon=0.9(cm)
%The position of electropole [0.3,0.6](cm)
%********************************************************************
clear;
%Define global constants
v_l = 10.589; %in mV
V_rest=-70; %in mv
gl = 0.3; %in /kohm*cm^2 **also gmax_l
%c0 = 0.824; %in microfarad/cm^2
dt = 0.001; %in ms
gna=120.0;%in /kohm*cm^2 **also gmax_l
gk=36.0;%in /kohm*cm^2 **also gmax_l
v_na=115.0 ;%in mV
v_k=-12.0;%in mV
d=2;
d=d/10000; %in cm **axon_diameter
dx=0.025; %in cm
ro_i = .0345; %in KOhm*cm
%ro_i = .0145; %in KOhm*cm
ro_e = .3; %in KOhm*cm
x0 = 0.1; %in cm
z0 = 0.1; %in cm
x1 = 0.6; %in cm
z1 = 0.1; %in cm
global R;
R=(4*ro_i*dx*dx)/d;
global T;
T=18.5;
%k1=3.0^((T-6.3)/10);
%create matricies bounded by time and space inputs
%npoints = input('length of the axon (cm): ');
npoints=0.9;
npoints=npoints/dx;
stop= input('period of time to run test(ms): ');
%stop=0.125;
stop=stop/dt;
M=zeros(npoints+1,stop);
H=zeros(npoints+1,stop);
N=zeros(npoints+1,stop);
kv1=zeros(npoints+2,stop);
kv2=zeros(npoints+2,stop);
kv3=zeros(npoints+2,stop);
kv4=zeros(npoints+2,stop);
km1=zeros(npoints+1,stop);
km2=zeros(npoints+1,stop);
km3=zeros(npoints+1,stop);
km4=zeros(npoints+1,stop);
kn1=zeros(npoints+1,stop);
kn2=zeros(npoints+1,stop);
kn3=zeros(npoints+1,stop);
kn4=zeros(npoints+1,stop);
kh1=zeros(npoints+1,stop);
kh2=zeros(npoints+1,stop);
kh3=zeros(npoints+1,stop);
kh4=zeros(npoints+1,stop);
V=zeros(npoints+2,stop);
Ve=zeros(npoints+2,stop);
TT=zeros(npoints+2,stop+1);
TT1=zeros(npoints+2,stop+1);
DTT=zeros(npoints+2,stop);
K1=zeros(npoints+2,stop);
CC=zeros(npoints+2,stop);
dCC=zeros(npoints+2,stop);
Ic=zeros(npoints+2,stop);
%test stimulation current
I= zeros(1,stop);
%Amp= input('input test stimulation intensity(uA):');
Amp=0;
Pw=0.1; %pulsewidth in ms
Pw=Pw/dt;
St=0.1/dt;
for i=St:St+Pw
I(i)=-1*Amp;
end
%block stimulation current
Ib= zeros(1,stop);
%Ampb= input('input block stimulation intensity(uA):');
%Frqb= input('input block stimulation frequency(kHz):');
for i=1:stop
Ib(i)=0;
end
%Prdb=1/(Frqb*dt);
%Prdb=round(Prdb/2);
%for i=(Prdb+1):Prdb*2:stop
% for j=i:(i+Prdb-1)
% Ib(j)=Ampb;
% end
%end
%calculate external voltages
ts=1;
while ts<=stop,
for step=1:npoints+2,
Ve(step,ts)=(ro_e*I(ts))/(4*pi*((((step-2)*dx-x0)^2)+z0^2)^0.5);
Ve(step,ts)= Ve(step,ts)+(ro_e*Ib(ts))/(4*pi*((((step-2)*dx-x1)^2)+z1^2)^0.5);
end
ts=ts+1;
end
%define initial conditions at time 1 for v and gate variables
V(:,1)=0;
M(:,1)=0.053;
H(:,1)=0.596;
N(:,1)=0.318;
TT(:,:)= T;
Tr = input('rising time for temperature stim(ms): ');
Tr = Tr/dt;
Tw = input('width for temperature stim(cm): ');
Tw = Tw/dx;
Tm = input('maximum temperature change(C): ');
k = input('temperature coefficiency(KuF/cm^2): ');
Tc=31;
c0=1-k/(Tc-18.5);
ts=20;
while ts<=stop,
for step=1:npoints+1,
TT1(step,ts)=Tm*exp(-(step-0.45/dx)^2/(2*Tw^2));
end
ts=ts+1;
end
ts=20;
while ts<=(Tr+20),
for step=1:npoints+1,
TT(step,ts)=T+TT1(step,ts)*(ts-20)/(Tr);
end
ts=ts+1;
end
while ts<=stop,
for step=1:npoints+1,
TT(step,ts)=T+TT1(step,ts)*exp(-(ts-(Tr+20))/(100/dt));
end
ts=ts+1;
end
for step=1:npoints+1,
TT(step,stop+1)= TT(step,stop);
end
for i=2:npoints+1
for j=2:stop+1
K1(i-1,j-1)=3^((TT(i-1,j-1)-6.3)/10);
DTT(i-1,j-1)=(TT(i-1,j)-TT(i-1,j-1))/dt;
CC(i-1,j-1)=c0+(k/(Tc-TT(i-1,j-1)));
dCC(i-1,j-1)=k*DTT(i-1,j-1)/((Tc-TT(i-1,j-1))^2);
end
end
t=2;
while t<=stop,
%start caculating k1
for step=2:npoints+1;
v=V(step,t-1);
v1=V(step-1,t-1);
v3=V(step+1,t-1);
ve=Ve(step,t-1);
ve1=Ve(step-1,t-1);
ve3=Ve(step+1,t-1);
m=M(step-1,t-1);
n=N(step-1,t-1);
h=H(step-1,t-1);
k1=K1(step-1,t-1);
C=CC(step-1,t-1);
dC=dCC(step-1,t-1);
[kv,I_na,I_k,I_l,Ii]=fv1(v1,v,v3,ve1,ve,ve3,m,n,h,R,C,dC);
kv1(step-1,t-1)=kv;
Ina(step-1,t-1)=I_na;
Ik(step-1,t-1)=I_k;
Il(step-1,t-1)=I_l;
I_in(step-1,t-1)=Ii;
Ic(step-1,t-1)=CC(step-1,t-1)*((V(step-1,t)-V(step-1,t-1))/dt)+...
(V(step-1,t-1)-70)*dCC(step-1,t-1);
km1(step-1,t-1)=fm(v,m,k1);
kn1(step-1,t-1)=fn(v,n,k1);
kh1(step-1,t-1)=fh(v,h,k1);
end
%start caculate k2
for step=2:npoints+1;
k1=K1(step-1,t-1);
C=CC(step-1,t-1);
dC=dCC(step-1,t-1);
v=V(step,t-1)+dt*kv1(step,t-1)/2;
v1=V(step-1,t-1)+dt*kv1(step-1,t-1)/2;
v3=V(step+1,t-1)+dt*kv1(step+1,t-1)/2;
ve=Ve(step,t-1);
ve1=Ve(step-1,t-1);
ve3=Ve(step+1,t-1);
m=M(step-1,t-1)+dt*km1(step-1,t-1)/2;
n=N(step-1,t-1)+dt*kn1(step-1,t-1)/2;
h=H(step-1,t-1)+dt*kh1(step-1,t-1)/2;
kv2(step-1,t-1)=fv(v1,v,v3,ve1,ve,ve3,m,n,h,R,C,dC);
km2(step-1,t-1)=fm(v,m,k1);
kn2(step-1,t-1)=fn(v,n,k1);
kh2(step-1,t-1)=fh(v,h,k1);
end
%start caculate k3
for step=2:npoints+1;
k1=K1(step-1,t-1);
C=CC(step-1,t-1);
dC=dCC(step-1,t-1);
v=V(step,t-1)+dt*kv2(step,t-1)/2;
v1=V(step-1,t-1)+dt*kv2(step-1,t-1)/2;
v3=V(step+1,t-1)+dt*kv2(step+1,t-1)/2;
ve=Ve(step,t-1);
ve1=Ve(step-1,t-1);
ve3=Ve(step+1,t-1);
m=M(step-1,t-1)+dt*km2(step-1,t-1)/2;
n=N(step-1,t-1)+dt*kn2(step-1,t-1)/2;
h=H(step-1,t-1)+dt*kh2(step-1,t-1)/2;
kv3(step-1,t-1)=fv(v1,v,v3,ve1,ve,ve3,m,n,h,R,C,dC);
km3(step-1,t-1)=fm(v,m,k1);
kn3(step-1,t-1)=fn(v,n,k1);
kh3(step-1,t-1)=fh(v,h,k1);
end
%start caculate k4
for step=2:npoints+1;
k1=K1(step-1,t-1);
C=CC(step-1,t-1);
dC=dCC(step-1,t-1);
v=V(step,t-1)+dt*kv3(step,t-1);
v1=V(step-1,t-1)+dt*kv3(step-1,t-1);
v3=V(step+1,t-1)+dt*kv3(step+1,t-1);
ve=Ve(step,t-1);
ve1=Ve(step-1,t-1);
ve3=Ve(step+1,t-1);
m=M(step-1,t-1)+dt*km3(step-1,t-1);
n=N(step-1,t-1)+dt*kn3(step-1,t-1);
h=H(step-1,t-1)+dt*kh3(step-1,t-1);
kv4(step-1,t-1)=fv(v1,v,v3,ve1,ve,ve3,m,n,h,R,C,dC);
km4(step-1,t-1)=fm(v,m,k1);
kn4(step-1,t-1)=fn(v,n,k1);
kh4(step-1,t-1)=fh(v,h,k1);
end
%caculate v,m,n,h,p
for step=1:npoints;
V(step+1,t)=V(step+1,t-1)+dt*(kv1(step,t-1)+2*kv2(step,t-1)+...
2*kv3(step,t-1)+kv4(step,t-1))/6;
M(step,t)=M(step,t-1)+dt*(km1(step,t-1)+2*km2(step,t-1)+...
2*km3(step,t-1)+km4(step,t-1))/6;
N(step,t)=N(step,t-1)+dt*(kn1(step,t-1)+2*kn2(step,t-1)+...
2*kn3(step,t-1)+kn4(step,t-1))/6;
H(step,t)=H(step,t-1)+dt*(kh1(step,t-1)+2*kh2(step,t-1)+...
2*kh3(step,t-1)+kh4(step,t-1))/6;
end
V(1,t)=V(2,t);V(npoints+2,t)=V(npoints+1,t);
plot(V(:,t))
axis([1,npoints+2,-100,120]);
drawnow;
t=t+1
end
%end of updating v, m, and h
%plot(v(:,:))
section_long=ones(1,stop);
figure(2);
for section_number=2:2:36
line(section_long*(section_number-2)/40,(1:stop)/1000,V(section_number,:),'Color','k');
end
axis([[0 0.9] 0 stop/1000 0 300])
xlabel('cm');
ylabel('ms');
%zlabel('mv');
view(35,65);