// P5IBc.p - for TraubIB_VP // Format of file : // x,y,z,dia are in microns, all other units are SI (Meter Kilogram Sec Amp) // In polar mode 'r' is in microns, theta and phi in degrees // Control line options start with a '*' // The format for each compartment parameter line is : //name parent r theta phi d ch dens ... //in polar mode, and in cartesian mode : //name parent x y z d ch dens ... // For channels, "dens" = maximum conductance per unit area of compartment // For spike elements, "dens" is the spike threshold // Coordinate mode *relative *cartesian *asymmetric // Specifying constants *set_compt_param RM 5.0 // 5.0 *set_compt_param RA 2.50 // 2.50 *set_compt_param CM 0.009 // 0.009 *set_compt_param EREST_ACT -0.07 // -0.075 *set_compt_param ELEAK -0.0666 // -0.075 //SOMA ************************************************************* // For the soma, use the leakage potential (-0.07 + 0.0106) for Em //*set_compt_param ELEAK -0.0594 // Actually, after Traub et al. J Neurophys 2003;89:909-921, will maintain // leakage potential at ELEAK -0.07 soma none 0 0 15 18 Ca_s8 -6.1304081E14 NaF8 2000 \ NaP8 1.6 KDR8 1700 \ KA8 200 K28 5 \ KM8 119 CaL8 1 \ CaH8 40 KCs8 160 \ AR8 1.0 KAHPs8 2.0 *set_compt_param CM 0.018 *set_compt_param RM 2.5 //APICAL DENDRITE COMPARTMENTS *************************************** // apdend1 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend1 soma 0 0 75 4 Ca_d8 -1.47129963E17 NaF8 3000 \ NaP8 2.4 KDR8 2400 \ KA8 160 K28 10 \ KM8 380 CaL8 2 \ CaH8 80 KCd8 320 \ AR8 2.0 KAHPd8 4 // apdend2 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend2 apdend1 0 0 75 3.8 Ca_d8 -1.54873652E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 80 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 320 \ AR8 2.0 KAHPd8 4.0 // apdend3 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend3 apdend2 0 0 75 3.6 Ca_d8 -1.63477742E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apdend4 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend4 apdend3 0 0 75 2.4 Ca_d8 -1.94730587E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apdend5 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend5 apdend4 0 0 75 3.2 Ca_d8 -2.06900497E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 40 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apdend6 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend6 apdend5 0 0 75 3 Ca_d8 -2.20693871E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 40 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apdend7 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend7 apdend6 0 0 75 2.8 Ca_d8 -2.36457724E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 40 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apdend8 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend8 apdend7 0 0 75 2.6 Ca_d8 -2.82942241E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 40 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apdend9 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend9 apdend8 0 0 75 2.4 Ca_d8 -3.06520752E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 40 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apdend10 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend10 apdend9 0 0 75 2 Ca_d8 -4.04611345E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 40 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apdend11 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend11 apdend10 0 0 75 1.6 Ca_d8 -5.51737374E17 NaF8 60 \ NaP8 0.048 KDR8 0 \ KA8 12 K28 10 \ KM8 112 CaL8 2 \ CaH8 20 KCd8 24 \ AR8 2.0 KAHPd8 4.0 // apdend12 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend12 apdend11 0 0 75 1.4 Ca_d8 -6.8309675E17 NaF8 60 \ NaP8 0.048 KDR8 0 \ KA8 12 K28 10 \ KM8 112 CaL8 2 \ CaH8 20 KCd8 24 \ AR8 2.0 KAHPd8 4.0 // apdend13 Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend13 apdend12 0 0 75 1.2 Ca_d8 -8.5827204E17 NaF8 60 \ NaP8 0.048 KDR8 0 \ KA8 12 K28 10 \ KM8 112 CaL8 2 \ CaH8 20 KCd8 24 \ AR8 2.0 KAHPd8 4.0 // apdend14aR Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend14aR apdend13 11.2 -19.5 55.6 1.1 Ca_d8 -1.00311682E18 NaF8 60 \ NaP8 0.048 KDR8 0 \ KA8 12 K28 10 \ KM8 112 CaL8 2 \ CaH8 54 KCd8 24 \ AR8 4.0 KAHPd8 4.0 // apdend14bR Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend14bR apdend14aR 11.2 -19.5 55.6 1.1 Ca_d8 -1.00321358E18 NaF8 60 \ NaP8 0.048 KDR8 0 \ KA8 12 K28 10 \ KM8 112 CaL8 2 \ CaH8 12 KCd8 24 \ AR8 4.0 KAHPd8 4.0 // apdend14cR Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend14cR apdend14bR 11.2 -19.5 55.6 1.1 Ca_d8 -1.00321358E18 NaF8 60 \ NaP8 0.048 KDR8 0 \ KA8 12 K28 10 \ KM8 112 CaL8 2 \ CaH8 12 KCd8 24 \ AR8 4.0 KAHPd8 4.0 // apdend14dR Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend14dR apdend14cR 11.2 -19.5 55.6 1.1 Ca_d8 -1.00307944E18 NaF8 60 \ NaP8 0.048 KDR8 0 \ KA8 12 K28 10 \ KM8 112 CaL8 2 \ CaH8 12 KCd8 24 \ AR8 4.0 KAHPd8 4.0 // apdend14aL Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend14aL apdend13 -11.2 19.5 55.6 1.1 Ca_d8 -1.0030927E18 NaF8 60 \ NaP8 0.048 KDR8 0 \ KA8 12 K28 10 \ KM8 112 CaL8 2 \ CaH8 54 KCd8 24 \ AR8 4.0 KAHPd8 4.0 // apdend14bL Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend14bL apdend14aL -11.2 19.5 55.6 1.1 Ca_d8 -1.00322458E18 NaF8 60 \ NaP8 0.048 KDR8 0 \ KA8 12 K28 10 \ KM8 112 CaL8 2 \ CaH8 12 KCd8 24 \ AR8 4.0 KAHPd8 4.0 // apdend14cL Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend14cL apdend14bL -11.2 19.5 55.6 1.1 Ca_d8 -1.00322368E18 NaF8 60 \ NaP8 0.048 KDR8 0 \ KA8 12 K28 10 \ KM8 112 CaL8 2 \ CaH8 12 KCd8 24 \ AR8 4.0 KAHPd8 4.0 // apdend14dL Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apdend14dL apdend14cL -11.2 19.5 55.6 1.1 Ca_d8 -1.0030782E18 NaF8 60 \ NaP8 0.048 KDR8 0 \ KA8 12 K28 10 \ KM8 112 CaL8 2 \ CaH8 12 KCd8 24 \ AR8 4.0 KAHPd8 4.0 //APICAL OBLIQUE DENDRITE COMPARTMENTS *************************************** // apobdistRa Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobdistRa apdend3 42.4 42.4 0.0 1.24 Ca_d8 -8.1574073E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 160 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 320 \ AR8 2.0 KAHPd8 4.0 // apobdistRb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobdistRb apobdistRa 42.4 42.4 0.0 1.24 Ca_d8 -8.1574094E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apobdistRc Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobdistRc apobdistRb 42.4 42.4 0.0 1.24 Ca_d8 -8.1574321E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apobdistLa Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobdistLa apdend3 -42.4 -42.4 0.0 1.24 Ca_d8 -8.1574073E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 160 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 320 \ AR8 2.0 KAHPd8 4.0 // apobdistLb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobdistLb apobdistLa -42.4 -42.4 0.0 1.24 Ca_d8 -8.1574094E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apobdistLc Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobdistLc apobdistLb -42.4 -42.4 0.0 1.24 Ca_d8 -8.1574321E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apobmidRa Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobmidRa apdend2 42.4 -42.4 0.0 1.24 Ca_d8 -8.1574073E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 160 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 320 \ AR8 2.0 KAHPd8 4.0 // apobmidRb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobmidRb apobmidRa 42.4 -42.4 0.0 1.24 Ca_d8 -8.1574094E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apobmidRc Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobmidRc apobmidRb 42.4 -42.4 0.0 1.24 Ca_d8 -8.1574321E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apobmidLa Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobmidLa apdend2 -42.4 42.4 0.0 1.24 Ca_d8 -8.1574073E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 160 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 320 \ AR8 2.0 KAHPd8 4.0 // apobmidLb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobmidLb apobmidLa -42.4 42.4 0.0 1.24 Ca_d8 -8.1574094E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apobmidLc Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobmidLc apobmidLb -42.4 42.4 0.0 1.24 Ca_d8 -8.1574321E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apobproxRa Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobproxRa apdend1 42.4 42.4 0.0 1.24 Ca_d8 -8.1574073E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 160 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 320 \ AR8 2.0 KAHPd8 4.0 // apobproxRb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobproxRb apobproxRa 42.4 42.4 0.0 1.24 Ca_d8 -8.1574094E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apobproxRc Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobproxRc apobproxRb 42.4 42.4 0.0 1.24 Ca_d8 -8.1573867E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apobproxLa Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobproxLa apdend1 -42.4 -42.4 0.0 1.24 Ca_d8 -8.1574073E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 160 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 320 \ AR8 2.0 KAHPd8 4.0 // apobproxLb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobproxLb apobproxLa -42.4 -42.4 0.0 1.24 Ca_d8 -8.1574094E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // apobproxLc Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 apobproxLc apobproxLb -42.4 -42.4 0.0 1.24 Ca_d8 -8.1573867E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 //BASAL DENDRITE COMPARTMENTS ************************************************ // basalLsupera Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalLsupera soma -26.8 -46.3 -27.2 1.7 Ca_d8 -5.40919039E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 160 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 320 \ AR8 2.0 KAHPd8 4.0 // basalLsuperb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalLsuperb basalLsupera -26.8 -46.3 -27.2 1.7 Ca_d8 -5.40918077E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // basalLsuperc Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalLsuperc basalLsuperb -26.8 -46.3 -27.2 1.7 Ca_d8 -5.40917321E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // basalLmida Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalLmida soma -19.3 33.4 -46.0 1.7 Ca_db8 -5.4091897E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 160 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCdb8 320 \ AR8 2.0 KAHPdb8 4.0 // basalLmidb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalLmidb basalLmida -19.3 33.4 -46.0 1.7 Ca_d8 -5.40919417E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // basalLmidc Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalLmidc basalLmidb -19.3 33.4 -46.0 1.7 Ca_d8 -5.40919967E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // basalRsupera Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalRsupera soma 26.8 46.3 -27.2 1.7 Ca_d8 -5.40919039E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 160 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 320 \ AR8 2.0 KAHPd8 4.0 // basalRsuperb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalRsuperb basalRsupera 26.8 46.3 -27.2 1.7 Ca_d8 -5.40919417E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // basalRsuperc Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalRsuperc basalRsuperb 26.8 46.3 -27.2 1.7 Ca_d8 -5.40919967E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // basalRmida Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalRmida soma 19.3 -33.4 -46.0 1.7 Ca_db8 -5.40918901E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 160 K28 10 \ KM8 380.0 CaL8 2 \ CaH8 80 KCdb8 320 \ AR8 2.0 KAHPdb8 4.0 // basalRmidb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalRmidb basalRmida 19.3 -33.4 -46.0 1.7 Ca_d8 -5.40919417E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // basalRmidc Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basalRmidc basalRmidb 19.3 -33.4 -46.0 1.7 Ca_d8 -5.4091952E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // basaldeepa Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basaldeepa soma 0 0 -60.0 1.7 Ca_db8 -5.40918764E17 NaF8 1500 \ NaP8 1.2 KDR8 1500 \ KA8 160 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCdb8 320 \ AR8 2.0 KAHPdb8 4.0 // basaldeepb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basaldeepb basaldeepa 0 0 -60.0 1.7 Ca_d8 -5.40919417E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // basaldeepc Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 basaldeepc basaldeepb 0 0 -60.0 1.7 Ca_d8 -5.40919967E17 NaF8 300 \ NaP8 0.24 KDR8 0 \ KA8 12 K28 10 \ KM8 380.8 CaL8 2 \ CaH8 80 KCd8 10 \ AR8 2.0 KAHPd8 4.0 // Specifying constants for axonal compartment RMCM=0.0014 (0.0009) *set_compt_param RM 0.10 // (0.10) *set_compt_param RA 1.00 // (1.00) *set_compt_param CM 0.009 // (0.009) *set_compt_param EREST_ACT -0.07 // -0.075 *set_compt_param ELEAK -0.066 // -0.075 //AXONAL COMPARTMENTS *************************************** // axona Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 // Differs from Traub et al., in that axon is vertical axona soma 0 0 -25 1.8 NaF8 4500 \ NaP8 0.0 KDR8 4500 \ KA8 6 K28 5 \ KM8 300 CaL8 0 \ CaH8 0 \ AR8 0 // axonb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 // Differs from Traub et al., in that axon is vertical axonb axona 0 0 -50 1.4 NaF8 4500 \ NaP8 0.0 KDR8 4500 \ KA8 6 K28 5 \ KM8 300 CaL8 0 \ CaH8 0 \ AR8 0 // axonLa Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 // Differs from Traub et al., in that axon is vertical axonLa axonb -8.7 0 -49.2 1.0 NaF8 4500 \ NaP8 0.0 KDR8 4500 \ KA8 6 K28 5 \ KM8 300 CaL8 0 \ CaH8 0 \ AR8 0 // axonLb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 // Differs from Traub et al., in that axon is vertical axonLb axonLa -8.7 0 -49.2 1.0 NaF8 4500 \ NaP8 0.0 KDR8 4500 \ KA8 6 K28 5 \ KM8 300 CaL8 0 \ CaH8 0 \ AR8 0 // axonRa Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 // Differs from Traub et al., in that axon is vertical axonRa axonb 8.7 0 -49.2 1.0 NaF8 4500 \ NaP8 0.0 KDR8 4500 \ KA8 6 K28 5 \ KM8 300 CaL8 0 \ CaH8 0 \ AR8 0 // axonRb Fig 1. Traub et al., J Neurophysiol 2003;89:909-921 // Differs from Traub et al., in that axon is vertical axonRb axonRa 8.7 0 -49.2 1.0 NaF8 4500 \ NaP8 0.0 KDR8 4500 \ KA8 6 K28 5 \ KM8 300 CaL8 0 \ CaH8 0 \ AR8 0