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Neurons: Anatomy & Physiology Review: Chapter 2 of textbook. Information from prerequisite classes, that I assume you know. Neurons Basic functional unit of N.S. Specialized cell All cells have same basic properties information processing Transmits Integrates Stores Regulation of behavior ~ Dendrites & soma Receive & Integrate information ~ Stimuli Axon carries information away from soma Electrical signal Axon terminal releases chemical message neurotransmitter (NT) ~ Neuronal Membrane Common Cellular Properties Compartmentalization Semipermeable Fluid Mosaic Model Phospholipids Proteins ~ Phospholipid Bilayer Hydrophilic heads Hydrophobic tails Membrane Proteins: Ionophores Ions Channels Nongated Gated mechanically -gated electrically-gated (voltage-gated) chemically -gated ~ Membrane Proteins NT INSIDE OUTSID E Membrane is polarized More negative particles inside than out unequal distribution of ions Bioelectric Potential like a battery Potential for ion movement current ~ Resting Membrane Potential + Na Cl outside + + + + + + + + + + + Membrane - - - - - - - - - - inside A + K Forces That Move Ions Concentration (C) particles in fluid move from area of high to area of low concentration diffusion, random movement Electrostatic (E) ions = charged particles like charges repel opposite charges attract ~ Organic anions Membrane impermeable Opposing electrical force not required Vm = -65 mV A C Chloride ion Cl C Vm = -65 mV E ECl- = - 65 mV Concentration gradient equal to electrostatic gradient. *No net movement at resting potential ~ Potassium ion E Vm = -65 mV + K C EK = - 75 mV Concentration gradient greater than electrostatic gradient. Leaks out neuron ~ + Na Sodium ion C Vm = -65 mV ENa+ = +55 mV Concentration gradient and electrostatic gradient into neuron. ~ E Neural Communication Neural Signaling Inside neuron Electrical signal 2 types of current Postsynaptic potentials dendrites & soma Action potential (AP) carries information down axon triggers NT release into synapse ~ Postsynaptic Potentials - PSPs Chemically-gated ion channels Graded Summation Passive current (electrotonic) Fast Decremental Relatively long-lasting 10 - 100 msec ~ EPSPs Excitatory Postsynaptic Potential Depolarization (+) Em becomes more positive more likely to trigger AP Na+ influx ~ IPSPs Inhibitory Postsynaptic Potential similar to EPSPs EXCEPT opposite hyperpolarization (-) Em becomes more negative less likely to trigger AP K+ efflux ~ Integration EPSPs & IPSPs summate become stronger or cancel each other Net stimulation determines message excitation or inhibition ~ Postsynaptic Potentials Soma & Dendrites Chemically-gated channels Passive current Graded Summation EPSP Excitatory Depolarization Na+ influx AP more likely IPSP Inhibitory Hyperpolarization K+ efflux AP less likely Action Potentials Large and rapid change in membrane potential Occurs in axon only voltage-gated channels triggered by EPSPs at axon hillock threshold potential ~ +40 0 Vm -60 -70 -80 Time +40 0 Vm Depolarization Na+ influx -60 -70 -80 Time +40 0 Repolarization K+ efflux Vm -60 -70 -80 Time +40 Afterhyperpolarization 0 Vm K+ efflux -60 -70 -80 Time AP Characteristics Voltage-gated channels All or none Self-propagated regenerated Non-decremental Slow Short-lived change in Em 1-2 msec ~ Frequency Code Pattern = Intensity of stimulus # APs per second Place = type of stimulus Visual, auditory, pain, etc. Brain area that receives signal ~ Injected Current 0 mV -65 mV Time Subthreshold stimulus Moderate stimulus Strong stimulus PSPs Graded Summation chemical-gated longer duration 10-100 msec passive spread instantaneous decremental vs APs All-or-none voltage-gated short 1-2 msec propagated slow nondecremental