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Membrane potentials
- 1. MEMBRANE POTENTIALS AND ACTION POTENTIALS BY Prof. Dr. Nusrat Tariq
- 2. INTRODUCTION Electrical potentials exist across the membranes of virtually all cells of the body. Some cells, such as nerve and muscle cells, generate rapidly changing electrochemical impulses at their membranes. These impulses are used to transmit signals along the nerve or muscle membranes.
- 3. BASIC PHYSICS OF MEMBRANE POTENTIALS
- 4. Membrane potentials are caused by ion concentration differences across a selectively permeable membrane
- 6. DIFFUSION POTENTIAL A diffusion potential is the potential difference generated across a membrane because of a concentration difference of an ion. • It can be generated only if the membrane is permeable to the ion. • The size of the diffusion potential depends on the size of the concentration gradient. • The sign of the diffusion potential depends on whether the diffusing ion is positively or negatively charged.
- 7. EQUILIBRIUM POTENTIAL The equilibrium potential is the diffusion potential that exactly balances (opposes) the tendency for diffusion caused by a concentration difference. At electrochemical equilibrium, the chemical and electrical driving forces that act on an ion are equal and opposite, and no more net diffusion of the ion occurs.
- 8. Nernst equation The Nernst equation is used to calculate the equilibrium potential at a given concentration difference of a permeable ion across a cell membrane. It tells us what potential would exactly balance the tendency for diffusion down the concentration gradient or at what potential would the ion be at electrochemical equilibrium?
- 9. NERNST EQUATION Used to calculate the Nernst potential for any univalent ion at the normal body temperature of 98.6°F (37°C). where EMF is electromotive force and z is the electrical charge of the ion (e.g., +1 for K+).
- 10. CALCULATION WITH THE NERNST EQUATION Sample: If the intracellular Na+ is 15 mM and the extracellular Na+ is 150 mM, what is the equilibrium potential for Na+?
- 12. GOLDMAN-HODGKIN-KATZ EQUATION The Goldman Equation is used to calculate the diffusion potential when the membrane is permeable to several different ions. When a membrane is permeable to several different ions, the diffusion potential that develops depends on three factors: (1) the polarity of the electrical charge of each ion (2) the permeability of the membrane (P) to each ion (3) the concentrations (C) of the respective ions on the inside (i) and outside (o) of the membrane.
- 13. GOLDMAN-HODGKIN-KATZ EQUATION Goldman equation gives the calculated membrane potential on the inside of the membrane when two univalent positive ions, sodium (Na+) and potassium (K+), and one univalent negative ion, chloride (Cl−), are involved.
- 15. TO BE CONTINUED