Lecture 2 Neurophysiology I PDF
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G. Bedecarrats
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Summary
This document provides an overview of Neurophysiology I, focusing on nerve cell function, synaptic transmission, and membrane potentials. It describes different neuron types and glial cells, explaining their roles in the nervous system. The lecture also reviews the maintenance of resting membrane potential (RMP) and action potentials.
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Neurophysiology I: Nerve Cell Function/Synaptic Transmission ANSC 3080 G. Bedecarrats Learning Objectives Define the structure and function of different classes of neurons Explain the mechanisms in forming membrane potentials Describe the events and properties o...
Neurophysiology I: Nerve Cell Function/Synaptic Transmission ANSC 3080 G. Bedecarrats Learning Objectives Define the structure and function of different classes of neurons Explain the mechanisms in forming membrane potentials Describe the events and properties of action potentials Describe and explain synaptic transmission Nervous System Organization Afferent Efferent Efferent Nervous System Composition Nervous tissue is composed of two types of cells: Neurons: They are “the” nerve cells able to transmit information Composed of a cell body and processes (axons and dendrites) Axon = info moves away from cell body Dendrite = info moves towards cell body Cell body = integrates in- and outgoing information Neurons can be categorized based on the number of processes: Multipolar, mainly in CNS (top) Pseudounipolar, mainly in PNS (middle) Bipolar, mainly sensory organs (bottom) Neurons also classified by function Sensory (afferent): from PNS to CNS Motor (efferent): from CNS to muscles and glands Interneurons (association): relay info between neurons within the CNS Specialized “receptors”: transducers = convert stimuli to signal Glial cells: non-neuronal cells; 10X more abundant than neurons (oligodendrocytes, astrocytes, ependymal cells, microglia) Provide structural support to nervous tissue Participate in myelin formation (oligodendrocytes) Secrete glutamate: can modulate excitatory level of neurons (astrocytes) Some possess phagocytic activity (microglia) Contact both blood vessels and neurons = transport of nutrients neurons do not store glucose or Oxygen Glial cells from a rabbit brain observed using a confocal microscope developed by Molecular Dynamics, Inc. White / Grey Matter Grey matter corresponds to cell bodies White matter corresponds to bundles of neuron processes with the white appearance due to myelin sheaths Nerves = bundles of axons; run from or to the CNS Cell bodies of sensory neurons are located in clusters named ganglia (outside of the CNS) Cell bodies of motor nerves are located in well-defined area of the CNS (brain and spinal cord) Myelin Sheaths (oligodendritic in CNS, Schwann cells in PNS) Myelin = white lipid (sphingomyelin) around nerve fibers Glial cells wrapped around an axon Looses its cytoplasm = layers of lipids Only in white matter (not all fibers) Electrical insulator Interruptions = nodes of Ranvier (every 1-2 mm). Denuded axon points will allow depolarisation = transmission of action potential (AP) Transmission of AP faster in myelinated fibers Membrane Potential Every cell of the body possesses a membrane potential = Resting Membrane Potential (RMP) RMP results from a difference in charge across the cell membrane (between cytosol and extracellular fluid) Inside of membrane negative RELATIVE to outside Absolute value differs between cell type and depends on the amount of charges, ion channels and the thickness of the membrane Average RMP in a nerve cells around –70 to –90 mV Intra- and extracellular compartments are electroneutral In the cytosol, negative charges carried by large organic molecules are attracted to the membrane by positive charges on the outside. What maintains the RMP? Combination of: 1. Selective permeability (passive based on diffusion). 2. Na+/K+ pump (3 Na+ out 2 K+ in) 3. Large anions trapped on the inner surface of membrane Maintenance of the RMP Selective permeability (diffusion): Passive leakage of ions through channels (concentration gradient) Resting membrane permeable to K+, barely permeable to Na+, Ca2+ and Cl- positive charges accumulate outside Ion pumps: Concentration of ions remains relatively constant inside the cell needs to compensate for diffusion leakage Na+/K+ pump: pumps 3 Na+ out and brings 2 K+ in Goes against concentration gradients and for Na+, against the membrane polarity (outside already positive relative to inside) Requires a lot of energy up to 40% of ATP availability Note: neurons do not store glucose or O2 constant supply needed Excitable Cells Cells that can generate electrical impulses (Action Potentials) They need to be stimulated Chemical, electrical or physical stimulations induce a change in membrane potential to reach a THRESHOLD provoking the opening of voltage gated ion channels If Na+ channels open (or Ca2+ in certain nerve endings and smooth and cardiac muscle cells), Na+ rushes inside the cell (gradient concentration) potential less negative, then inverted (positive) = DEPOLARIZATION Subsequent opening of K +channels results in an outflow of K+ returning the potential to RMP = REPOLARIZATION Generation of Action Potentials in Neurons First, an initial depolarization (stimulation) needs to reach threshold to provoke the opening of Na+ voltage gated channels = Depolarization After about 0.5 ms, opened Na+ channels close rapidly K+ voltage gated channels then open (delayed compared to Na+ channels) outflow of K+ = Repolarization K+ voltage gated channels then progressively close, outflow of K+ continues after reaching the RMP = Hyperpolariztion Once all gated channels are closed, ions rejoin their respective compartments by diffusion and Na+/K+ pumps Neurons cannot be re-stimulated until RMP is restored = REFRACTORY PERIOD FYI: Typical voltage gated Na+ channel Two gates: activation and inactivation gates Activation gate is electrically charged a) Resting: activation gate closed, inactivation gate opened b) Depolarization: activation gate opens, inactivation gate remains opened c) After short delay: closing of the inactivation gate d) Repolarization: Activation gate closes but the inactivation takes more time to reopen (new depolarization not possible = refractory period) Ion Gated Channels Several types of gated channels: Voltage-gated channels Ligand-gated channels: binding sites for neurotransmitters Each channel is composed of several subunits, and has various degrees of specificity All-or-none Rule Nerve cells follow the all- or-none rule When threshold is met an AP is generated The amplitude of the AP is fixed for that cell Intensity encoded by the frequency of Aps, not the amplitude Conduction of Action Potential Depolarization and repolarization processes (AP) propagate along the cell membrane Need for the change in potential to reach threshold on the nearby microdomain to trigger opening of gated channels In unmyelinated axons: In myelinated axons: AP occurs the same way but only at the nodes of Ranvier Myelin prevents ion leakage, current jumps from one node to the other = SALTATORY conduction Velocity increased as less membrane affected = less energy required to transport ions Nerve velocity depends on dissipation of current Thickness of myelin Diameter of the fiber (thicker = faster) Range from 100 to 0.5 m/sec and from 2500 to 250 impulses/sec Synaptic Transmission Continuity of signal between a neuron and other neurons or between a neuron and target cells such as skeletal muscles (neuromuscular synapse) Cell membrane made of phospholipids = electric insulator A gap exists between pre- and post-synaptic cell membranes = synaptic gap or cleft Rarely, direct continuity in electric impulse = gap junction (cardiac and some smooth muscles) In vertebrates, neuronal synapses = predominantly CHEMICAL synapses Neurotransmitters Molecules able to transmit information from a neuron: convert the electrical signal (AP) into a chemical signal Released by pre-synaptic neuron into the gap Bind to specific receptors on post-synaptic membrane Elicit a response Classified based on their molecular size and composition Small molecules: Synthesized in the nerve terminals by specific enzymes Amino Acid derivatives; Biogenic amines Neuropeptides (3-40 AA): Synthesized in the cell body Packaged in secretory vesicles Transported to the site of release FYI General Mechanism of Action (case of the neuromuscular synapse) Postsynaptic folding is common in neuromuscular synapse (not in interneurons) = increases surface Acetylcholine (ACh) = neuromuscular synapse transmitter 1. Action potential (AP) 2. AP opens voltage gated Ca2+ channels = in-flux of Ca2+ 3. Ca2+ triggers exocytosis 4. Diffusion in the cleft 5. Binding to specific receptors 6. Ion channels open on post-synaptic membrane = depolarization 7. Neurotransmitter inactivated termination of signal FYI Quinn, M. Chapter 8 Muscle Physiology. Slide 28 http://slideplayer.com/slide/4428030/ Termination of Transmission For small molecules: Picked back up by presynaptic neuron via endocytosis and recycled for next time Deactivated in the cleft by enzymes released by post- synaptic cell (ie Acetycholine Esterase) For neuropeptides: After binding to its receptor, can be internalized by post-synaptic cell via endocytosis and be degraded by cellular enzymes Broken down by extracellular peptidase in the gap Receptor can be desensitized Integration of Multiple Synapses Between Neurons In the case of neuro-muscular synapse, 1 neuron = AP = muscle cell depolarization In neuron-neuron synapse: 1 neuron can receive impulse from multiple other neurons Synapses can be either excitatory or inhibitory 1 impulse does not always lead to a response (need to reach threshold) Excitatory synapse = depolarization = entry of Na+ Inhibitory synapse = hyperpolarization = entry of Cl - and/or outflow of K+ A & B = excitatory; C = inhibitory a) Excitatory postsynaptic potential (EPS) not sufficient to reach threshold; needs 3 impulses b) Needs impulse from A and B for EPS to reach threshold c) C able to decrease EPS and block excitatory action of A+B