1 / 66

Nervous System

Nervous System. Part 3: Integration & Control. Nervous Tissue. One of the 4 basic tissue types in the human body. 4 Functions: Known as the 4 C’s Communicates Commands Controls Coordinates. Types of Nervous Tissue Functions. Communication: Occurs through action potentials .

tmendez
Download Presentation

Nervous System

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Nervous System Part 3: Integration & Control

  2. Nervous Tissue • One of the 4 basic tissue types in the human body. • 4 Functions: Known as the 4 C’s • Communicates • Commands • Controls • Coordinates

  3. Types of Nervous Tissue Functions • Communication: Occurs through action potentials. • Action potentials: Electrical impulses triggered by ion flux. • Sensory Functions: Conveying information from external and internal stimuli to the CNS via afferent neurons. • Integrative Functions: Analyzing & storing sensory information; deciding on appropriate responses via interneurons. • Motor Functions: Responding to integrative decisions by carrying impulses from the CNS to the effectors in the organs via efferent neurons.

  4. Divisions of the Nervous System • Central Nervous System: Consists of the brain and spinal cord. • Peripheral Nervous System: Consists of all nervous tissue outside the brain & spinal cord – 2 subdivisions: • Autonomic Nervous System (ANS) • Sympathetic Nervous System • Parasympathetic Nervous System • Enteric Nervous System • Somatic Nervous System (SNS)

  5. Central Nervous System (CNS) • Structures: • Brain • Spinal Corn • Both will be talked about in detail in Chapter 11!

  6. Peripheral Nervous System (PNS) • Consists of all nervous tissue located outside of the CNS. • Includes Ganglia, which are small masses of nervous tissue. • Subdivisions: • Autonomic Nervous System (ANS) • Sympathetic Nervous System • Parasympathetic Nervous System • Enteric Nervous System • Somatic Nervous System (SNS)

  7. Autonomic Nervous System (ANS) • Consists of sensory neurons that pass information from the autonomic sensory receptors in the visceral organs & motor neurons to the CNS and back. • 2 Major Branches: • Sympathetic Nervous System: Triggers fight-or-flight response. • Parasympathetic Nervous System: Returns body to homeostasis when threat has passed.

  8. Enteric Nervous System (ENS) • Considered a “small brain” since it has so many neurons. • Some debate about its classification is still continuing. Right now it is classified as a subdivision of the peripheral nervous system, but receives most of its innervations from the autonomic nervous system so is also classified as a subdivision of the ANS.

  9. Somatic Nervous System (SNS) • Consists of the… • Sensory neurons passing information from receptors to the sensory areas of the CNS • Motor neurons passing impulses from the SNS to the skeletal muscles.

  10. Types of Neurons • 3 Basic Types of Neurons: • Sensory Neurons aka Afferent Neurons: Detect stimuli & carry impulses from the cranial or spinal nerves to the CNS. • Motor Neurons aka Efferent Neurons: Carry impulses away from the CNS from the brain to the spinal cord and PNS. • Interneurons aka Association Neurons: Located inside the CNS and perform nervous system integrative functions.

  11. Properties of Neurons • Properties shared by all neurons: • Excitability: Ability to respond to stimuli & changes in the environment that excites a sensory receptor, neuron, or muscle fiber. • Conductivity: The ability to produce and respond to electrical signals to aid in communication. • Secrete: The ability to secrete chemical neurotransmitters to aid in communication.

  12. The Nerve Cell • 3 Basic Parts: • Dendrites • Soma • Axon

  13. The Nerve Cell • Dendrites: Consists of many branches coming out of the soma of the cell. • Function to receive information from the synaptic clef. • Process: Fibers that run to dendrites and from axons.

  14. The Nerve Cell • Soma: The cell body consisting of a central nucleus surrounded by cytoplasm & containing standard organelles. • Nissl Bodies: Clusters of endoplasmic reticulum found in the soma.

  15. The Nerve Cell • Axon: The long, single-stranded portion of the neuron exiting from the opposite end of the soma from the dendrites. • Functions to transmit information to the synaptic clef. • Axon Hillock: The point of connection between the axon to the soma. • Axon Terminals: The tiny branches dividing off at the end of the axons. • Axoplasm: The cytoplasm of the axon.

  16. The Nerve Cell • Myelin Sheath: Thin layer of fat cells around the axon that greatly increases the speed of neural transmission. • Produced by Schwann Cells and Oligodendrocytes. • Nodes of Ranvier: Gaps in the myelin sheath that occur at regular intervals to help impulses “skip” between sections & therefore travel faster. • Salutatory Conduction: The process of signals “skipping” across the nodes of Ranvier to increase transmission speed.

  17. Classification of Neurons • Based on myelin: • Myelinated: Neurons that have a myelin sheath. • Unmyelinated: Neurons that do not have a myelin sheath. • Based on number of axons & dendrites: • Multipolar: Neurons that have a single axon and several dendrites – the most common! • Bipolar: Neurons with a single axon and single dendrite – found in the eye, inner ear, and olfactory region of the brain. • Unipolar: Neurons where the axon and dendrite have fused into a single process (axon) that branches in two directions. Primarily serves as a sensory neuron.

  18. Types of Matter • Gray Matter: Contains mainly nerve cell bodies and unmyelinated fibers. • Found in the outer layer of the brain. • Found in the inner layer of the spinal cord. • White Matter: Contains mainly myelinated axons and appears to be white. • Found on the inside of the brain. • Found on in the outer later of the spinal cord. Cerebeluum

  19. Synapses • Synapse: The point at which one neuron communicates with another. • Synaptic Cleft: The slight gap between two neurons where the synapse occurs. • Presynaptic Neuron: The neuron transmitting the signal through its axon. • Postsynaptic Neuron: The neuron receiving the signal through its dendrites.

  20. Synapses • Two types of synapses exist, named for their method of communication transmission. • Electrical Synapses: Electrical signals are directly transmitted between cells. • Gap Junctions convey electrical signals directly between adjacent cells. • Provide faster communication & can be produced in unison by a large number of neurons & muscle fibers. • More common in smooth muscle, cardiac muscle, and in embryos.

  21. Synapses • Chemical Synapses: Membranes do not touch, so signals do not pass directly. • Cells respond to neurotransmitters released from synaptic knobs into the synaptic cleft binding to receptor sites. • Steps: • The presynaptic cell translates the electrical impulse into a chemical signal. • The postsynaptic cell translates the chemical signal back into an electrical impulse. • Steps cause a synaptic delay close to 0.5 microseconds.

  22. Neuraglia • Neuroglia: Support cells of the nervous system. • Cells smaller than neurons and outnumbering them 50 to 1. They do not generate impulses but can divide & multiply. • Types of Neuroglia: • Schwann Cells: Cells located in the PNS that produce myelin. • Neurolemma aka Sheath of Schwann: Outer cytoplasmic layer of the Schwann cells containing its own nucleus. • Oligodendrocytes: Cells located in the CNS that produce myelin. • Astrocytes: Star-shaped cells that... • Provide nutrients • Help regulate the chemical environment • Absorb excess neurotransmitters • Assist in forming the blood-brain barrier

  23. Neuroglia • Types of Neuroglia: • Microglia: Macrophage cells that act as an immune response to protect the CNS from disease. • Ependymal Cells: Cells that line the brain. • Help circulate the cerebrospinal fluid in the CNS using cilia on the outside of the cells. • Satellite Cells: Help support the other cells of the PNS.

  24. Electrophysiology • Electrical Potential: The gradient difference in the concentration of charged particles between points. • Polarized: The term used to describe cells that have an electrical potential. • Depolarized: The term used to describe cells that do not have an electrical potential.

  25. Electrophysiology • Membrane Potential: The potential electrical voltage difference stored in the resting membrane. • Works the same way a car battery does! • Resting Membrane Potential: The amount of electrical charge built up as a result of…. • Negative ions lined up along the inside of the cell membrane • Positive ions lined up along the outside of the • Potassium (K+) ions leaking outward at a faster rate than Sodium (Na+) ions permeating inward • Resting Membrane Potential of a polarized neuron is -70mV (minivolts).

  26. Neural Communication • Neurons communicate through action potentials brought on by polarization & depolarization. • Ion Channels: Channels in the cell membrane that allow ions to move in and out of the cell to create the resting membrane potential. • Gates: The method of controlling ion passage.

  27. Neural Communication • 4 Types of Ion Channels: • Leakage Channels: Gates open and close randomly – regulated by normal permeability. • Voltage-Gated Channels: Open in response to a change in the membrane potential. • Voltage-gated sodium channels are blocked with local anesthetics, which prevents the pain signal from reaching the CNS. • Ligand-Gated Channels: Open and close in response to chemical stimuli – primarily regulated by neurotransmitters and hormones. • Mechanically Gated Channels: Open and close in response to outside mechanical stimulation. • Example: Auditory receptors in the ears stimulated by sound waves or physical pressure.

  28. Neural Communication • Local Potential or Graded Potential: Occurs when only a small deviation is found in the resting potential. • Only occurs due to the opening of a ligand-gated or mechanically-gated channel. • Potentials vary in size, are only effective for a short distance, and can be excitatory, inhibitory, & reversible.

  29. Action Potentials • Action Potentials aka Impulses: Generated along voltage-gated ion channels. • Consist of rapid changes in membrane voltage. • Triggered by depolarization of the cellular membrane.

  30. Action Potentials • Stimuli triggers the start of the neural process. • Depolarization occurs as the resting membrane voltage changes toward threshold level. • Threshold is reached when the voltage rises enough to open the voltage-gated ion channels. • Typically occurs at -55mV (minivolts) in neurons.

  31. Action Potentials • Gates Open: • Sodium Gates open quickly, allowing an inrush of sodium ions. • Potassium Gates open slowly, causing a trickle of potassium ions into the cell. • Sodium Influx only lasts a few 10,000’s of a second and causes: • Membrane to reach +30mV (minivolts) • Sodium gates to close • Potassium gates to fully open • Repolarization occurs as the potassium levels rapidly drop, causing the voltage to drop back to -55mV (minivolts).

  32. Action Potentials • Refractory Period: The amount of time necessary for the cell to return to its resting state via repolarization. • Absolute Refractory Period: The period when the repolarization is less than one-third complete and cannot generate another action potential, no mater what stimuli occur. • Relative Refractory Period: Once repolarization is one-third complete, stimuli considerably stronger than the threshold stimulus can produce an action potential.

  33. Action Potentials • All-Or-Nothing Law: An action potential will occur once the voltage level reaches threshold, no matter what. • It will always be the same size • The signal will always travel down the entire length of the neuron • The action potential will not fire until it reaches threshold, and will always fire once it does.

  34. Methods of Conduction • Continuous Conduction: When an impulse travels around 2m/sec (meters per second) down an unmyelinated neuron. • Saltatory Conduction: When an impulse travels around 120m/sec down a myelinated neuron. • The impulse “jumps” from new action potentials generated at each node of Ranvier.

  35. Neurotransmitters • Neurotransmitters: Chemical signals transmitted and interpreted by the nervous system. • Neuroreceptors: Sites located on the postsynaptic neuron that binds to neurotransmitters. • Binding causes an influx of Sodium (Na+) which depolarizes the neuron and fires of an action potential. • Synaptic Vesicles: Sacs on the knobs on the end of the axons that are used to store neurotransmitters.

  36. Neural Integration • Excitatory Postsynaptic Potential (EPSP) aka Excitatory Neurotransmitters: Brings the charge closer to threshold being reached by depolarizing the membrane. • The larger the number of EPSPs the higher the change that the threshold will be reached. • Effect of EPSPs must be grater than the effect of the IPSPs. • Inhibitory Postsynaptic Potential (IPSP) aka Inhibitory Neurotransmitters: Takes the charge farther away from threshold by hyperpolarizing the membrane.

  37. Neural Integration • Summation: The process of a neuron integrating the information from thousands of synapses providing incoming information at a time. • Trigger Zone: The point of reception for the summation of incoming signals. • Two forms of summation: • Temporal Summation: A single presynaptic neuron generates enough EPSPs in short intervals, allowing signals to build up before the first ones decay. • Spatial Summation: EPSPs from several different postsynaptic neurons are added up to reach the threshold. • Facilitation: When neurons enhance the effects of other neurons. • Inhibition: When neurons inhibit or suppress the effects of other neurons.

  38. Neurotransmitters • Over 100 neurotransmitters found in the body & categorized into 3 basic categories of small-molecule neurotransmitters: • Acetylcholine • Amino acids • Biogenic amines

  39. Acetylcholine • ACh is the most studied neurtransmitter • Acts as an excitatory or inhibitory neurotransmitter depending on the synapse it is in. • Ionotropif Effect: ACh binding to ligand-gated channelscauses enough of a local action potential to fire the neuron. • Acetylcholinesterase (AChE): A second neurotransmitter released to deactivate Ach when it is no longer needed.

  40. Amino Acids • Act as neurotransmitters in the CNS. • Two important amino acids: • Glutamate: Excitatory neurotransmitter. • Excitotoxisity: Occurs when too high a level of glutamate is present in the NS – leads to neural death. • Due to lack of oxygen or inadequate blood supply. • Seen in stroke victims. • Aspartate: Another excitatory neurotransmitter linked to glutamate.

  41. Biogenic Amines • Modified amino acids that are both excitatory & inhibitory. • Catecholamine: An amino acid with a catechol ring (6 carbons and 2 hydroxyl groups). • Biogenic amines are typically made of these. • This category includes: • Norepinephrine: Catecholamine responsible for arousal, dreaming & mood. • Dopamine: Catecholamine that contributes to emotions, addictive behaviors, pleasures, & muscle tone. • Serotonin: NOT a catecholamine – involved in sensory perception, mood control, appetite, temperature regulation, and sleep.

  42. Prozac Nation • Selective Serotonin Reuptake Inhibiter (SSRI): Stops the uptake of the neurotransmitter serotonin & increases the “good mood” by allowing the serotonin to stick around the synapse longer. • Prozac!

More Related