Summary

This document provides an overview of nerve function, including the structure and function of neurons, neurotransmitters, and synapses. It describes different types of neurons, action potentials, and the process of neural communication.

Full Transcript

Nerve and how it Functions nction of the Ner vous Syste sensory input motor input sensory receptor effector integration uron Interaction & Integrati sensory neuron interneu...

Nerve and how it Functions nction of the Ner vous Syste sensory input motor input sensory receptor effector integration uron Interaction & Integrati sensory neuron interneuron sensory receptors effector motor neuron Neuroglia Typical Neuron dendrite cell body Myelin sheath axon Synapse Myelin Sheath & Shwann Cell Nodes of Ranvier Schwann Axon Cells Types of Neurons unipolar bipolar multipolar Dorsal root eye, ear, & olfactory most abundant type in CNS ganglion cells Information must be transmitted  within each neuron  and between neurons  The membrane surrounds the neuron.  It is composed of lipid and protein.  There is an electrical charge across the membrane.  This is the membrane potential.  The resting potential (when the cell is not firing) is a 70mV difference between the inside and the outside. + + + + + outside - - - - - inside Resting potential of neuron = -70mV  Ions are electrically-charged molecules e.g. sodium (Na+), potassium (K+), chloride (Cl-).  The resting potential exists because ions are concentrated on different sides of the membrane. ◦ Na+ and Cl- outside the cell. ◦ K+ and organic anions inside the cell. Na + Na + Cl- Na+ Na+ Cl- outside Organic anions (-) inside K + Organic anions (-) K+ Organic anions (-)  Na+ ions are actively transported (this uses energy) to maintain the resting potential.  The sodium-potassium pump (a membrane protein) exchanges three Na+ ions for two K+ ions. Na+ Na+ Na+ outside inside K+ K+  The action potential is a rapid depolarization of the membrane.  It starts at the axon hillock and passes quickly along the axon.  The membrane is quickly repolarized to allow subsequent firing.  When partial depolarization reaches the activation threshold, voltage-gated sodium ion channels open.  Sodium ions rush in.  The membrane potential changes from -70mV to +40mV. Na+ + - - Na+ Na+ +  Sodium ion channels close and become refractory.  Depolarization triggers opening of voltage-gated potassium ion channels.  K+ ions rush out of the cell, repolarizing and then hyperpolarizing the membrane. Na+ K+ K+ + Na+ Na+ K+ -  The action potential is “all-or-none”.  It is always the same size.  Either it is not triggered at all - e.g. too little depolarization, or the membrane is “refractory”;  Or it is triggered completely.  The action potential begins with a partial depolarization (e.g. from firing of another neuron ) [A].  When the excitation threshold is reached there is a sudden large depolarization [B].  This is followed rapidly by repolarization [C] and a brief hyperpolarization [D].  There is a refractory period immediately after the action potential where no depolarization can occur [E] +40 Membrane [C] potential 0 [B] [E] (mV) [A] [D] excitation threshold -70 0 1 2 3 Time (msec)  Passive conduction will ensure that adjacent membrane depolarizes, so the action potential “travels” down the axon.  But transmission by continuous action potentials is relatively slow and energy- consuming (Na+/K+ pump).  A faster, more efficient mechanism has evolved: saltatory conduction.  Myelination provides saltatory conduction.  Most mammalian axons are myelinated.  The myelin sheath is provided by oligodendrocytes and Schwann cells.  Myelin is insulating, preventing passage of ions over the membrane.  Myelinated regions of axon are electrically insulated.  Electrical charge moves along the axon rather than across the membrane.  Action potentials occur only at unmyelinated regions: nodes of Ranvier. Myelin sheath Node of Ranvier  Information is transmitted from the presynaptic neuron to the postsynaptic cell.  Chemical neurotransmitters cross the synapse, from the terminal to the dendrite or soma.  The synapse is very narrow, so transmission is fast.  An action potential causes neurotransmitter release from the presynaptic membrane.  Neurotransmitters diffuse across the synaptic cleft.  They bind to receptors within the postsynaptic membrane, altering the membrane potential. extracellular fluid terminal synaptic cleft presynaptic membrane postsynaptic membrane dendritic spine  Ca2+ causes vesicle membrane to fuse with presynaptic membrane.  Vesicle contents empty into cleft: exocytosis.  Neurotransmitter diffuses across synaptic cleft. Ca2+  Synaptic activity at ionotropic receptors is fast and brief (milliseconds).  Acetylcholine (Ach) works in this way at nicotinic receptors.  Neurotransmitter binding changes the receptor’s shape to open an ion channel directly. ACh ACh  Opening of ion channels which leads to depolarization makes an action potential more likely, hence “excitatory PSPs”: EPSPs. ◦ Inside of post-synaptic cell becomes less negative. ◦ Na+ channels (NB remember the action potential) ◦ Ca2+. (Also activates structural intracellular changes -> learning.) + Na+ Ca2+ outside - inside  Opening of ion channels which leads to hyperpolarization makes an action potential less likely, hence “inhibitory PSPs”: IPSPs. ◦ Inside of post-synaptic cell becomes more negative. ◦ K+ (NB remember termination of the action potential) ◦ Cl- (if already depolarized) Cl- + outside - inside K+ For the synapse to work properly, six basic events need to happen:  Production of the Neurotransmitters ◦ Synaptic vesicles (SV)  Storage of Neurotransmitters ◦ SV  Release of Neurotransmitters  Binding of Neurotransmitters ◦ Lock and key  Generation of a New Action Potential  Removal of Neurotransmitters from the Synapse ◦ reuptake  PSPs are small. An individual EPSP will not produce enough depolarization to trigger an action potential.  IPSPs will counteract the effect of EPSPs at the same neuron.  Summation means the effect of many coincident IPSPs and EPSPs at one neuron.  If there is sufficient depolarization at the axon hillock, an action potential will be triggered. axon hillock

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