# FIG 3C: V-Is properties # Written by Hojeong Kim ## [soma equations] dvs/dt=(I_s+ins(vs,snam,snah,scam,scah,snapm,vca)+outs(vs,skdr)-gms*(vs-(vl+vrest))+gc*(vd-vs)/parea)/cms # inward voltage-gated current ins(vs,snam,snah,scam,scah,snapm,vca)=-sina(vs,snam,snah)-sica(vs,scam,scah,vca)-sinap(vs,snapm) sina(vs,snam,snah)=sgna*snam**3*snah*(vs-(vna+vrest)) dsnam/dt=alpha_m(vs)*(1-snam)-beta_m(vs)*snam alpha_m(vs)=anamc*(vs-anamv)/(exp(-(vs-anamv)/anama)+anamb) beta_m(vs)=bnamc*(vs-bnamv)/(exp((vs-bnamv)/bnama)+bnamb) dsnah/dt=(snahinf(vs)-snah)/snahtau(vs) snahinf(vs)=1.0/(1.0+exp((vs-snahth)/snahslp)) snahtau(vs)=snahc/(exp((vs-snahv)/snaha)+exp(-(vs-snahv)/snahb)) sica(vs,scam,scah,vca)=sgca*scam**2*scah*(vs-(vca+vrest)) dscam/dt=(scaminf(vs)-scam)/camtau dscah/dt=(scahinf(vs)-scah)/cahtau scaminf(vs)=1.0/(1.0+exp(-(vs-camth)/camslp)) scahinf(vs)=1.0/(1.0+exp((vs-cahth)/cahslp)) vca=(1000*R*Temp/Zca/Fe)*log(CAo/sca) dsca/dt=-f*alpha*sica(vs,scam,scah,vca)-f*kca*sca sinap(vs,snapm)=sgnap*snapm**3*(vs-(vna+vrest)) dsnapm/dt=alphasnapm(vs)*(1-snapm)-betasnapm(vs)*snapm alphasnapm(vs)=anapmc*(vs-anapmv)/(exp(-(vs-anapmv)/anapma)+anapmb) betasnapm(vs)=bnapmc*(vs-bnapmv)/(exp((vs-bnapmv)/bnapma)+bnapmb) # outward voltage-gated currents outs(vs,skdr)=-sikdr(vs,skdr)-sikca(vs) sikdr(vs,skdr)=sgkdr*skdr**4*(vs-(vk+vrest)) dskdr/dt=(skdrinf(vs)-skdr)/skdrtau(vs) skdrinf(vs)=1.0/(1.0+exp(-(vs-skdrth)/skdrslp)) skdrtau(vs)=skdrc/(exp((vs-skdrv)/skdra)+exp(-(vs-skdrv)/skdrb)) sikca(vs)=sgkca*(sca/(sca+kd))*(vs-(vk+vrest)) ## [dendrite equations] dvd/dt=(ind(vd,dcal)-gmd*(vd-(vl+vrest))+gc*(vs-vd)/(1.0-parea))/cmd # inward voltage-gated current ind(vd,dcal)=-dgcal*dcal*(vd-(vdcal+vrest)) ddcal/dt=(dcalinf(vd)-dcal)/dcaltau dcalinf(vd)=1.0/(1.0+exp(-(vd-dcalth)/dcalslp)) ## [cable parameters] gms(mS/cm^2),gmd(mS/cm^2),gc(mS/cm^2),cms(uF/cm^2),cmd(uF/cm^2) p gms=0.143, gmd=0.131, gc=0.211, cms=1.058, cmd=0.915, parea=0.492 ## [active parameters] # reversal and resting potentials p vna=120.0,vk=-10.0,vl=0.0,vdcal=130.0,vrest=-70 # constants p kd=0.0005,f=0.01,kca=8.0,alpha=1 p R=8.31441,Temp=309.15,Zca=2,Fe=96485.309,CAo=2 # [soma]: v(mV),t(ms),g(mS/cm^2) p sgna=26.75,anamc=-0.4,anamv=-49,anama=5,anamb=-1.0 p bnamc=0.4,bnamv=-25,bnama=5,bnamb=-1.0 p snahth=-58.0,snahslp=7.0,snahv=-60.0,snaha=15.0,snahb=16.0,snahc=30.0 p sgkdr=6.2,skdrth=-31.0,skdrslp=15.0,skdrv=-50.0,skdra=40.0,skdrb=50.0,skdrc=5.0 p sgca=0.008,camth=-25.0,camslp=5.0,camtau=15.0 p cahth=-43.0,cahslp=5.0,cahtau=50.0 p sgkca=0.54 p sgnap=0.00086,anapmc=-0.0353,anapmv=-21.4,anapma=5,anapmb=-1.0 p bnapmc=0.000883,bnapmv=-25.7,bnapma=5,bnapmb=-1.0 # [dendrite]: v(mV),t(ms),g(mS/cm^2) p dgcal=0.124,dcalth=-43.0,dcalslp=6.0,dcaltau=60.0 ## [initial conditions] # soma vs(0)=-70.0 snam(0)=0.001 snah(0)=0.5829 scam(0)=0.004199 scah(0)=0.9219 sca(0)=0.0001 skdr(0)=0.1239 snapm(0)=0.001 # dendrites vd(0)=-70.0 dcal(0)=0.001 ## [current stimulation at soma]: mA/cm^2 p i0=0,m=6.33,t_m=5000 I_s=i0+m-(m/t_m)*abs(t-t_m) ## [simulation outputs]: V(mV), I(nA) aux Vsoma=vs aux Iapp=I_s*3.16 ## [simulation environment] @ maxstor=2000000 @ total=10000 @ method=gear, toler=0.009, dtmax=0.5 @ NPLOT=2, XP=t, YP=Vsoma, XP2=t, YP2=Iapp @ xlo=0, xhi=10000, ylo=-80, yhi=40 @ bound=10000 @ create=1 done