The Goldman-Hodgkin-Katz Equation

red curve

the derivative of a GHK function

gray curve

GHK function

green curve

Nernst function

temperature

283

potassium

permeability

1

intracellularconcentration

392

sodium

permeability

0.04

extracellularconcentration

462

intracellularconcentration

78

chlorine

permeability

0.45

extracellularconcentration

286

intracellularconcentration

104

The Goldman–Hodgkin–Katz voltage equation, used in cell membrane physiology, can be written

E

m

=±

RT

zF

ln

P

K

[

K

o

]+

P

Na

[

Na

o

]+

P

Cl

[

Cl

i

]

P

K

[

K

i

]+

P

Na

[

Na

i

]+

P

Cl

[

Cl

o

]

,

RT

zF

=±0.0000860.

The GHK equation is used to determine the resting membrane potential in real cells. It is a generalization of the Nernst equation. This Demonstration shows the Goldman–Hodgkin–Katz voltage function, plotted in gray, in terms of the argument

x=[

K

o

]

:

E

m

=±

RT

zF

ln

P

K

x+

P

Na

[

Na

o

]+

P

Cl

[

Cl

i

]

P

K

[

K

i

]+

P

Na

[

Na

i

]+

P

Cl

[

Cl

o

]

, where

E

m

is the membrane potential in volts;

R

is the ideal gas constant in joules per kelvin-mol;

T

is the temperature (Kelvin);

F

is Faraday's constant in coulombs/mol;

P

K

,

P

Na

,

P

Cl

are the permeabilities of the potassium, sodium, and chloride ions;

[

K

o

]

,

[

Na

o

]

,

[

Cl

o

]

are the extracellular concentrations of potassium, sodium, and chloride;

[

K

i

]

,

[

Na

i

]

,

[

Cl

i

]

are their intracellular concentrations.

Also shown are the derivatives of the GHK function (red) and the Nernst function (green),

E

m

=±

RT

zF

ln

x

[

K

i

]

. The region between the GHK and Nernst functions is shown filled.