Post on 06-Mar-2018
Electrical Phenomenain
Biological Structures
Information transfer in the brain
Excitation conduction in the heart
Sensory information acquisition and processing
Nerve pulse conduction
Electromechanical activity
Electrical Phenomena in the Body
12/23/16 3
Electric Current
Conductors:
- presence of free electrons- low resistance to the current of electrons
Insulators:
- lack of free electrons- high resistance to the current of electrons
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Electric Current - Ohm’s Law
Unit: Coulomb/second (C/s) = Amperes (A)
I – current (A)R – resistance (Ω)
Power of the Electric Current (Watts)
For a voltage V (volt ) across resistor
Electrical circuit in of bodyTransport of ions (charges)
through cell membraneLipid bilayer membrane
Nuerons
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Biological Membranes as Parallel plate Capacitors
High resistance and a low dielectric constant
Capacitor
Plasmamembranefattyphospholipidbilayerinsulator
Capacitor
The property of the capacitor
Relationship between thecharge and the potentialdifference V across the plates
Dielectricpermittivity
Capacitance
Platearea
2212 ./1085.8 mNCx -
Diffusion across membranes
Non-charged particles/molecules• The concentration gradient is the main driving force
From high → low concentration• Diffusion of one compound is independent of others• When the net diffusion stops ?
- concentration on both sides is equal.- equilibrium is reached.- No net change (Net diffusion : diffusion on both directions is equal )
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Membrane Potential and Charged particles
Equilibrium(electrostatic force)
• Membranepotential:separationofoppositechargesacrosstheplasmamembrane.
• Allanimalcellsareelectricallypolarized(maintainvoltagedifferenceacrossthecell’splasmamembrane).Ihasanelectrochemicalgradient.
• Membranepotentialischaracterizedbyaslightexcessofpositivechargesoutsidethecellandnegativechargesinside
Equilibrium Potential (E) for ions
Intracellularfluid(Inside)
Extracellularfluid(Outside)
Inorganismsionsareresponsibleforcarryingchargeinbodyfluids• UnequaldistributionofkeyionsbetweenICFandECF.• Themembraneisimpermeaple tolargeICFproteinanions• Selectivemovementoftheseionsthroughplasmamembrane
NernstequationTemperature(K)Gasconstant
Faraday’sconstantIonvalence
Concentrationofionoutside
Concentrationofioninside
Example 1: Calculate the equilibrium potentials at normal bodytemperature for potassium K+ and sodium Na+ in neurons. Theconcentration of potassium is 5 mmol/L outside and 140 mmol/Linside. For sodium 1.5 mmol/L inside and 120 mmol/L outside.
Example 2: Calculate the equilibrium potentials at normal bodytemperature for calcium Ca2+ with typical external concentration of1.5 mM and internal concentration of 10-4mM
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Ion Distribution Across the Membrane
Resting Membrane Potential Vm
EquilibriumpotentialforsingleionRestingmembranepotentialbycontributionofseveralions
ECFECF ICF
(Goldman-Hodgkin-Katz Equation)
Relativemembranepermeabilities:easewithwhichionscrossthemembrane
Example4: calculatethemembranerestingpotentialforpartialpermeabilitiesof1,0.03,0.1forK,Na,andClionsrespectively
Currentamperes(A)
Conductanceinsiemens(S)
Membranevoltage(restingpotential)(V)
Equilibriumpotentialofionx
Whathappenstopassapulse/spikeSignaltransferinneuronswhenstimulated
IncreaseinthepermeabilityofNa+todepolarize
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Stimulating an excitable cellChanges in the Resting Membrane Potential
Whatistheperiodoftheactionpotential?
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Electrical Processes
Conductor Cell (neuron)
Cable Axon
Free electrons Electrochemical gradient
Zero potential Resting potential
Electrical current Ion current across along the cable the membrane
Battery (source) Pacemaker cell
• Exercise1: usetheconcentrationsbelowtocalculatetheequilibriumpotentialatnormalbodytemperatureofeachionfortheplasmamembraneandforthemembranewiththeinterstitialfluid.
Eercise 2: Typical Nernst equilibrium potential for Cl- (z =-1) at 37oC is -0.090 V. if laboratory results showed that extracellularchlorine was 120 mM find the intracellular concentration
(Think about it until next lecture)