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Dr. Michael P. Gillespie Nervous Tissue Nervous System The nervous system is an intricate, highly organized network of billions of neurons and even more neuroglia. The nervous system has a mass of only 2 kg (4.5 lb), which comprises approximately 3% of total body weight. 2 Dr. Michael P. Gillespie Structures of the Nervous System (CNS) Brain (100 billion neurons) Spinal cord (100 million neurons) 3 Dr. Michael P. Gillespie Structures of the Nervous System (PNS) Spinal nerves (31 pairs) Cranial nerves (12 pairs) Ganglia (Masses of primarily neuron cell bodies) Enteric plexuses (networks of neurons in the GI tract) Sensory receptors (dendrites of sensory neurons) 4 Dr. Michael P. Gillespie 5 Dr. Michael P. Gillespie Functions of the Nervous System Sensory function – afferent neurons Sensory receptors detect internal and external stimuli Integrative function – interneurons The nervous system processes sensory information and coordinates responses. It perceives stimuli. Motor function – efferent neurons The cells contacted by these neurons are called effectors (muscles and glands) 6 Dr. Michael P. Gillespie Organization of the Nervous System Central nervous system Brain Spinal cord 7 Dr. Michael P. Gillespie Organization of the Nervous System Peripheral nervous system Cranial nerves and their branches Spinal nerves and their branches Ganglia Sensory receptors Somatic nervous system Autonomic nervous system Enteric nervous system 8 Dr. Michael P. Gillespie 9 Dr. Michael P. Gillespie 10 Dr. Michael P. Gillespie Somatic Nervous System (SNS) Sensory neurons. Motor neurons located in skeletal muscles. The motor responses can be voluntarily controlled; therefore this part of the PNS is voluntary. 11 Dr. Michael P. Gillespie Autonomic Nervous System (ANS) Sensory neurons from the autonomic sensory receptors in the viscera. Motor neurons located in smooth muscle, cardiac muscle and glands. These motor responses are NOT under conscious control; Therefore this part of the PNS is involuntary. 12 Dr. Michael P. Gillespie ANS Continued… The motor portion of the ANS consists of sympathetic and parasympathetic divisions. Both divisions typically have opposing actions. 13 Dr. Michael P. Gillespie 14 Dr. Michael P. Gillespie Enteric Nervous System (ENS) “The brain of the gut”. Functions independently of the ANS and CNS, but communicates with it as well. Enteric motor units govern contraction of the GI tract. Involuntary. 15 Dr. Michael P. Gillespie 16 Dr. Michael P. Gillespie Types of Nervous Tissue Cells Neurons. Sensing. Thinking. Remembering. Controlling muscular activity. Regulating glandular secretions. Neuroglia. Support, nourish, and protect neurons. 17 Dr. Michael P. Gillespie Neurons Have the ability to produce action potentials or impulses (electrical excitability) in response to a stimulus. An action potential is an electrical signal that propagates from one point to the next along the plasma membrane of a neuron. A stimulus is any change in the environment that is strong enough to initiate an action potential. 18 Dr. Michael P. Gillespie Parts of a Neuron Cell Body Dendrites Axon 19 Dr. Michael P. Gillespie Parts of a Neuron (Cell Body) Cell body (perikaryon or soma). Contains the nucleus surrounded by cytoplasm which contains the organelles. Clusters of rough ER called Nissl bodies (produce proteins to grow and repair damaged nerves) 20 Dr. Michael P. Gillespie Parts of a Neuron (Nerve Fiber) Nerve fiber – any neuronal process that emerges from the cell body of a neuron. Dendrites Axon 21 Dr. Michael P. Gillespie Parts of a Neuron (Dendrites) Dendrites (= little trees). The receiving (input) portion of a neuron. Short, tapering, and highly branched. 22 Dr. Michael P. Gillespie Parts of a Neuron (Axon) Axon (= axis). Each nerve contains a single axon. The axon propagates nerve impulses toward another neuron, muscle fiber, or gland cell. Long, thin, cylindrical projection that often joins the cell body at a cone-shaped elevation called the axon hillock (= small hill). The part of the axon closest to the hillock is the initial segment. The junction between the axon hillock and the initial segment is the trigger zone (nerve impulses arise here). The cytoplasm of the axon is the axoplasm and is surrounded by a plasma membrane known as the axolemma (lemma = sheath). 23 Dr. Michael P. Gillespie 24 Dr. Michael P. Gillespie Synapse The synapse is the site of communication between two neurons or between a neuron and an effector cell. Synaptic end bulbs and varicosities contain synaptic vesicles that store a chemical neurotransmitter. 25 Dr. Michael P. Gillespie Axonal Transport Slow axonal transport. 1-5 mm per day. Travels in one direction only – from cell body toward axon terminals. Fast axonal transport. 200 – 400 mm per day. Uses proteins to move materials. Travels in both directions. 26 Dr. Michael P. Gillespie Structural Diversity of Neurons The cell body diameter can range in size from 5 micrometers (μm) (slightly smaller than a RBC) up to 135 μm (barely visible to the naked eye). Dendritic branching patterns vary. Axon length varies greatly as well. Some neurons have no axon, some are very short, and some run all the way from the toes to the lowest part of the brain. 27 Dr. Michael P. Gillespie Classification of Neurons Both Structural and Functional features are used to classify neurons. 28 Dr. Michael P. Gillespie Structural Classifications of Neurons Structurally, neurons are classified according to the number of processes extending from the cell body. 3 Structural Classes Multipolar neurons Bipolar neurons Unipolar neurons 29 Dr. Michael P. Gillespie Multipolar Neurons One axon and several dendrites. Most neurons of the brain and spinal cord are of this type. 30 Dr. Michael P. Gillespie Bipolar Neurons Bipolar neurons. One axon and one main dendrite. Retina of the eye, inner ear, and the olfactory areas of the brain. 31 Dr. Michael P. Gillespie Unipolar Neurons Unipolar neurons. The axon and the dendrite fuse into a single process that divides into two branches. The dendrites monitor a sensory stimulus such as touch, pressure, pain, heat, or stretching. Called psuedounipolar neurons. 32 Dr. Michael P. Gillespie 33 Dr. Michael P. Gillespie Functional Classification of Neurons Functionally, neurons are classified according to the direction in which the nerve impulse (action potential) is conveyed with respect to the CNS. 3 Functional Classes Sensory or afferent neurons Motor of efferent neurons Interneurons or association neurons 34 Dr. Michael P. Gillespie Sensory (Afferent) Neurons Either contain sensory receptors or are located adjacent to sensory receptors that are separate cells. Conveyed into the CNS through cranial or spinal nerves. Most are unipolar. 35 Dr. Michael P. Gillespie Motor (Efferent) Neurons Away from the CNS to effectors (muscles and glands). Most are multipolar. 36 Dr. Michael P. Gillespie Interneurons (Association Neurons) Mainly located within the CNS between sensory and motor neurons. They process sensory information and elicit a motor response. Most are multipolar. 37 Dr. Michael P. Gillespie Neuroglia Half the volume of the CNS. Generally, they are smaller than neurons, but 5 to 50 times more numerous. They can multiply and divide. Gliomas – brain tumors derived from glia. 38 Dr. Michael P. Gillespie Functions of Neuroglia To surround neurons and hold them in place. To supply nutrients and oxygen to neurons. To insulate one neuron from another. To destroy pathogens and remove dead neurons. To modulate neurotransmission. 39 Dr. Michael P. Gillespie Types of Neuroglia CNS Astrocytes Oligodendrocytes Microglia Ependymal cells PNS Schwann cells Satellite cells 40 Dr. Michael P. Gillespie Astrocytes (CNS) Star shaped cells with many processes. Largest and most numerous of the neuroglia. 41 Dr. Michael P. Gillespie Astrocytes (CNS) Functions Support neurons. Processes wrap around capillaries to create a blood-brain barrier. Regulate growth, migration and interconnection among neurons in the embryo. Maintain chemical environment for impulse transmission Influence formation of neural synapses. 42 Dr. Michael P. Gillespie Astrocytes (CNS) 43 Dr. Michael P. Gillespie Astrocytes (CNS) 44 Dr. Michael P. Gillespie Astrocytes (CNS) 45 Dr. Michael P. Gillespie Oligodendrocytes (CNS) Similar to astrocytes, but smaller with fewer processes. Function Form and maintain the myelin sheath around the CNS axons. 46 Dr. Michael P. Gillespie Oligodendrocytes (CNS) 47 Dr. Michael P. Gillespie Microglia (CNS) Small cells with slender processes giving off numerous spine like projections. Specialized macrophages. Function Phagocytosis. 48 Dr. Michael P. Gillespie Microglia (CNS) 49 Dr. Michael P. Gillespie Ependymal Cells (CNS) Cuboidal to columnar cells. They line the cavities of the CNS and make up the walls of the ventricles. Possess microvilli and cilia. Functions Produce cerebrospinal fluid (CSF) Assist in circulation of CSF Possibly monitor CSF Thought to act as neural stem cells. 50 Dr. Michael P. Gillespie Ependymal Cells (CNS) 51 Dr. Michael P. Gillespie CNS Neuroglia 52 Dr. Michael P. Gillespie Schwann Cells (PNS) Encircle PNS axons to forma sheath around them. One Schwann cell per axon. Function Form myelin sheath around PNS neurons Assist in axon regeneration Have phagocytic activity and clear cellular debris. 53 Dr. Michael P. Gillespie Schwann Cells (PNS) 54 Dr. Michael P. Gillespie Satellite Cells (PNS) Small cells that surround neurons in sensory, sympathetic and parasympathetic ganglia. Functions Help to regulate the chemical environment. Highly sensitive to injury and inflammation and appear to contribute to pathological states such as chronic pain. 55 Dr. Michael P. Gillespie Myelination The myelin sheath is a lipid and protein covering. It is produced by the neuroglia. The sheath electrically insulates the axon of a neuron. The sheath increases the speed of nerve impulse conduction. The amount of myelin increases from birth on. Axons without a covering are unmyelinated. Axons with a covering are myelinated. 56 Dr. Michael P. Gillespie Myelination Continued… Two types of neuroglial cells produce myelination. Schwann cells – located in the PNS. Oligodendrocytes – located in the CNS. 57 Dr. Michael P. Gillespie Neurolemma (Sheath of Schwann) The neurolemma (sheath of Schwann) is the outer nucleated cytoplasmic layer of the Schwann cell. It encloses the myelin sheath. It is only found around the axons of the PNS. If the axon is injured, the neurolemma forms a regeneration tube that guides and stimulates re-growth of the axon. 58 Dr. Michael P. Gillespie Nodes of Ranvier The nodes of Ranvier are gaps in the myelin sheath at intervals along the axon. Each Schwann cell wraps one axon segment between two nodes. The electrical impulse jumps from node to node to speed up the propagation Nodes of Ranvier are present in the CNS, but fewer in number. 59 Dr. Michael P. Gillespie Demyelination Demyelination is the loss or destruction of the myelin sheaths around axons. It occurs as the result of disorders such as multiple sclerosis or Tay-Sachs disease. Radiation and chemotherapy can also damage the myelin sheath. Demyelination can deteriorate the affected nerves. 60 Dr. Michael P. Gillespie 61 Dr. Michael P. Gillespie Collections of Nervous Tissue Neuronal cell bodies are grouped in clusters. Axons of neurons are grouped in bundles. Nervous tissue is grouped in gray and white matter. 62 Dr. Michael P. Gillespie Clusters of Neuronal Cell Bodies Ganglion – cluster of neuronal cell bodies in the PNS. Associated with the cranial and spinal nerves. Nucleus – cluster of neuronal cell bodies in the CNS. 63 Dr. Michael P. Gillespie Bundles of Axons Nerve – a bundle of axons in the PNS. Cranial nerves connect the brain to the periphery. Spinal nerves connect the spinal cord to the periphery. Tract – a bundle of axons in the CNS. Tracts interconnect neurons in the spinal cord and brain. 64 Dr. Michael P. Gillespie Gray and White Matter The white matter consists of aggregations of primarily myelinated and some unmyelinated axons. (Myelin is whitish in color) The gray matter consists of neuronal cell bodies, dendrites, unmyelinated axons, axon terminals, and neuroglia. (Nissl bodies impart a gray color) 65 Dr. Michael P. Gillespie 66 Dr. Michael P. Gillespie Electrical Signals in Neurons Neurons are electrically excitable and communicate with one another using 2 types of electrical signals. Graded potentials (short distance communication). Action potentials ((long distance communication). The plasma membrane exhibits a membrane potential. The membrane potential is an electrical voltage difference across the membrane. 67 Dr. Michael P. Gillespie Electrical Signals in Neurons The voltage is termed the resting membrane potential. The flow of charged particles across the membrane is called current. In living cells, the flow of ions constitutes the electrical current. 68 Dr. Michael P. Gillespie Ion Channels The plasma membrane contains many different kinds of ion channels. The lipid bilayer of the plasma membrane is a good electrical insulator. The main paths for flow of current across the membrane are ion channels. 69 Dr. Michael P. Gillespie Ion Channels When ion channels are open, they allow specific ions to move across the plasma membrane down their electrochemical gradient. Ions move from greater areas of concentration to lesser areas of concentration. Positively charged cations move towards a negatively charged area and negatively charged anions move towards a positively charged area. As they move, they change the membrane potential. 70 Dr. Michael P. Gillespie Ion Channel “Gates” Ion channels open and close due to the presence of “gates”. The gate is part of a channel protein that can seal the channel pore shut or move aside to open the pore. 71 Dr. Michael P. Gillespie Types of Ion Channels Leakage channels Ligand-gated channel Mechanically gated channel Voltage gated channel 72 Dr. Michael P. Gillespie Leakage Channels Leakage channels – gates randomly alternate between open and closed positions. More potassium ion (K+) leakage channels than sodium (Na+) leakage channels. The potassium ion leakage channels are leakier than the sodium ion leakage channels. 73 Dr. Michael P. Gillespie Ligand-gated Channel Ligand-gated channels – open and close in response to a specific chemical stimulus. Neurotransmitters, hormones, and certain ions can act as the chemical stimulus that opens or closes these channels. 74 Dr. Michael P. Gillespie Mechanically Gated Channel Mechanically gated channels – opens or closes in response to mechanical stimulation. Vibration, touch, pressure, or tissue stretching can all distort the channel from its resting position, opening the gate. 75 Dr. Michael P. Gillespie Voltage-gated Channel Voltage-gated channels – opens in response to a change in membrane potential (voltage). These channels participate in the generation and conduction of action potentials. 76 Dr. Michael P. Gillespie 77 Dr. Michael P. Gillespie 78 Dr. Michael P. Gillespie Gradients Concentration Gradient – A difference in the concentration of a chemical from one place to another. Electrochemical Gradient – The combination of the effects of the concentration gradient and the membrane potential. 79 Dr. Michael P. Gillespie 80 Dr. Michael P. Gillespie Transport Across the Membrane Passive Transport – does not require cellular energy. Substances move down their concentration or electrochemical gradients using only their own kinetic energy. Active Transport – requires cellular energy in the form of ATP. 81 Dr. Michael P. Gillespie 3 Types of Passive Transport Diffusion through the lipid bilayer. Diffusion through membrane channels. Facilitated diffusion. 82 Dr. Michael P. Gillespie Diffusion Materials diffuse from areas of high concentration to areas of low concentration. The move down their concentration gradient. Equilibrium – molecules are mixed uniformly throughout the solution. 83 Dr. Michael P. Gillespie 84 Dr. Michael P. Gillespie Factors Influencing Diffusion Steepness of the concentration gradient. Temperature. Mass of the diffusing substance, Surface area. Diffusion distance. 85 Dr. Michael P. Gillespie Resting Membrane Potential The resting membrane potential occurs due to a buildup of negative ions in the cytosol along the inside of the membrane and positive ions in the extracellular fluid along the outside of the membrane. The potential energy is measured in millivolts (mV). 86 Dr. Michael P. Gillespie Resting Membrane Potential In neurons, the resting membrane potential ranges from – 40 to –90 mV. Typically –70 mV. The minus sign indicates that the inside of the cell is negative compared to the outside. A cell that exhibits a membrane potential is polarized. The potential exists because of a small buildup of negative ions in the cytosol along the inside of the membrane and positive ions in the extracellular fluid along the membrane. 87 Dr. Michael P. Gillespie 88 Dr. Michael P. Gillespie Electrochemical Gradient An electrical difference and a concentration difference across the membrane. 89 Dr. Michael P. Gillespie Factors Producing the Resting Membrane Potential Unequal distribution of ions in the ECF and cytosol. Inability of most anions to leave the cell. Electrogenic nature of the Na+/K+ ATPases. 90 Dr. Michael P. Gillespie Unequal distribution of ions in the ECF and cytosol. ECF is rich in Na+ and CL- ions. Cytosol has the cation K+ and the dominant anions are phosphates attached to ATP and amino acids in proteins. The plasma membrane has more K+ leakage channels than Na+ leakage channels. 91 Dr. Michael P. Gillespie Inability of most anions to leave the cell. The anions are attached to large nondiffusable molecules such as ATP and large proteins. 92 Dr. Michael P. Gillespie Electrogenic nature of the Na+/K+ ATPases. Membrane permeability to Na+ is very low because there are very few sodium leakage channels. Sodium ions do slowly diffuse into the cell, which would eventually destroy the resting membrane potential. Na+/K+ ATPases pump sodium back out of the cell and bring potassium back in. They pump out 3 Na+ for every 2 K+ they bring in. 93 Dr. Michael P. Gillespie Graded Potentials A graded potential is a small deviation from the resting membrane potential. It makes the membrane either more polarized (more negative inside) or less polarized (less negative inside). Most graded potentials occur in the dendrites or cell body. 94 Dr. Michael P. Gillespie Graded Potentials Hyperpolarizing graded potential make the membrane more polarized (inside more negative). Depolarizing graded potential make the membrane less polarized (inside less negative). Graded potentials occur when ligand-gated or mechanically gated channels open or close. Mechanically gated and ligand-gated channels are present in sensory neurons. Ligand-gated channels are present in interneurons and motor neurons. 95 Dr. Michael P. Gillespie Graded Potentials Graded potentials are graded because they vary in amplitude (size) depending on the strength of the stimulus. The amplitude varies depending upon how many channels are open and how long they are open. The opening and closing of channels produces a flow of current that is localized. 96 Dr. Michael P. Gillespie Graded Potentials The charge spreads a short distance and dies out (decremental conduction). The charge can become stronger and last longer by adding with other graded potentials (Summation). 97 Dr. Michael P. Gillespie Types of Graded Potentials Post-synaptic potentials – a graded potential that occurs in the dendrites or cell body of a neuron in response to a neurotransmitter. Receptor potentials and generator potentials – graded potentials that occur in sensory receptors and sensory neurons. 98 Dr. Michael P. Gillespie 99 Dr. Michael P. Gillespie Action Potentials An action potential or impulse is a sequence of events that decrease and reverse the membrane potential and eventually restore it to its resting state. Depolarizing phase – the resting membrane potential becomes less negative, reaches zero, and then becomes positive. Repolarizing phase – restores the resting membrane potential to -70 mV. 100 Dr. Michael P. Gillespie Threshold Threshold – depolarization reaches a certain level (about –55 mV), voltage gated channels open. A weak stimulus that does not bring the membrane to threshold is called a sub-threshold stimulus. A stimulus that is just strong enough to depolarize a membrane is called a threshold stimulus. Several action potentials will from in response to a supra- threshold stimulus. Action potentials arise according to an all or none principal. 101 Dr. Michael P. Gillespie 102 Dr. Michael P. Gillespie Depolarizing Phase A depolarizing graded potential or some other stimulus causes the membrane to reach threshold. Voltage-gated ion channels open rapidly. The inflow of positive Na+ ions changes the membrane potential from –55mv to +30 mV. K+ channels remain largely closed. About 20,000 Na+ enter through the gates. Millions are present in the surrounding fluid. Na+/K+ pumps bail them out. 103 Dr. Michael P. Gillespie Repolarizing Phase While Na+ channels are opening during depolarization, K+ channels remain largely closed. The closing of Na+ channels and the slow opening of K+ channels allows for repolarization. K+ channels allow outflow of K+ ions. 104 Dr. Michael P. Gillespie 105 Dr. Michael P. Gillespie Refractory Period The refractory period is the period of time after an action potential begins during which an excitable cell cannot generate another action potential. Absolute refractory period – a second action potential cannot be initiated, even with a very strong stimulus. Relative refractory period – an action potential can be initiated, but only with a larger than normal stimulus. 106 Dr. Michael P. Gillespie Propagation of Nerve Impulses Unlike the graded potential, the impulse in the action potential is not detrimental (it does not die out). The impulse must travel from the trigger zone to the axon terminals. This process is known as propagation or conduction. The impulse spreads along the membrane. As Na+ ions flow in, they trigger depolarization which opens Na+ channels in adjacent segments of the membrane. 107 Dr. Michael P. Gillespie 2 Types of Propagation Continuous Conduction – step by step depolarization and repolarization of each segment of the plasma membrane. Saltatory Conduction – a special mode of action potential propagation along myelinated axons. The action potential “leaps” from one Node of Ranvier to the next. 108 Dr. Michael P. Gillespie Continuous and Saltatory Conduction Few ion channels are present where there is myelin. Nodes of Ranvier – areas where there is no myelin – contain many ion channels. The impulse “jumps” from node to node. This speeds up the propagation of the impulse. This is a more energy efficient mode of conduction. 109 Dr. Michael P. Gillespie 110 Dr. Michael P. Gillespie Neurotoxins & Local Anesthetics Neurotoxins produce poisonous effects upon the nervous system. Local anesthetics are drugs that block pain and other somatic sensations. These both act by blocking the opening of voltage-gated Na+ channels and preventing propagation of nerve impulses. 111 Dr. Michael P. Gillespie Factors That Affect Speed of Propagation 1. Amount of myelination - Myelinated axons conduct impulses faster than unmyelinated ones. 2. Axon diameter - Larger diameter axons propagate impulses faster than smaller ones. 3. Temperature – Axons propagate action potentials at lower speeds when cooled. 112 Dr. Michael P. Gillespie Classification of Nerve Fibers A fibers. Largest diameter. Myelinated. Convey touch, pressure, position, thermal sensation. 113 Dr. Michael P. Gillespie Classification of Nerve Fibers B fibers. Smaller diameter than A fibers. Myelinated. Conduct impulses from the viscera to the brain and spinal cord (part of the ANS). 114 Dr. Michael P. Gillespie Classification of Nerve Fibers C fibers. Smallest diameter. Unmyelinated. Conduct some sensory impulses and pain impulses from the viscera. Stimulate the heart, smooth muscle, and glands (part of ANS). 115 Dr. Michael P. Gillespie Encoding Intensity of a Stimulus A light touch feels different than a firmer touch because of the frequency of impulses. The number of sensory neurons recruited (activated) also determines the intensity of the stimulus. 116 Dr. Michael P. Gillespie Signal Transmission at Synapses Presynaptic neuron – the neuron sending the signal. Postsynaptic neuron – the neuron receiving the message. Axodendritic – from axon to dendrite. Axosomatic – from axon to soma. Axoaxonic – from axon to axon. 117 Dr. Michael P. Gillespie Types of Synapses Electrical synapse Chemical synapse 118 Dr. Michael P. Gillespie Electrical Synapses Action potentials conduct directly between adjacent cells through gap junctions. 119 Dr. Michael P. Gillespie Electrical Synapses Tubular connexons act as tunnels to connect the cytosol of the two cells. Advantages. Faster communication than a chemical synapse. Synchronization – they can synchronize the activity of a group of neurons or muscle fibers. In the heart and visceral smooth muscle this results in coordinated contraction of these muscle fibers. 120 Dr. Michael P. Gillespie Chemical Synapses The plasma membranes of a presynaptic and postsynaptic neuron in a chemical synapse do not touch one another directly. The space between the neurons is called a synaptic cleft which is filled with interstitial fluid. A neurotransmitter must diffuse through the interstitial fluid in the cleft and bind to receptors on the postsynaptic neuron. The synaptic delay is about 0.5 msec. 121 Dr. Michael P. Gillespie 122 Dr. Michael P. Gillespie Removal of Neurotransmitter Diffusion. Enzymatic degradation. Uptake by cells. Into the cells that released them (reuptake). Into neighboring glial cells (uptake). 123 Dr. Michael P. Gillespie Spatial and Temporal Summation of Postsynaptic Potentials A typical neuron in the CNS receives input from 1000 to 10,000 synapses. Integration of these inputs is known as summation. 124 Dr. Michael P. Gillespie Spatial and Temporal Summation of Postsynaptic Potentials Spatial summation – summation results from buildup of neurotransmitter released by several presynaptic end bulbs. Temporal summation – summation results from buildup of neurotransmitter released by a single presynaptic end bulb 2 or more times in rapid succession. 125 Dr. Michael P. Gillespie Neural Circuits Diverging circuit –single presynaptic neuron influences several postsynaptic neurons (i.e. muscle fibers or gland cells). Converging circuit – several presynaptic neruons influence a single post-synaptic neuron (results in a stronger signal). 126 Dr. Michael P. Gillespie Neural Circuits Reverberating circuit – Branches from later neurons stimulate earlier ones (may last for seconds to hours) (breathing, coordinated muscular activities, waking up, short-term memory). Parallel after-discharge circuit – a presynaptic neuron stimulates a group of neurons that all interact with a common postsynaptic cell (quick stream of impulses) (mathematical calculations). 127 Dr. Michael P. Gillespie Neural Circuits 128 Dr. Michael P. Gillespie Neurogenesis in the CNS Birth of new neurons. From undifferentiated stem cells. Epidermal growth factor stimulates growth of neurons and astrocytes. Minimal new growth occurs in the CNS. Inhibition from glial cells. Myelin in the CNS. 129 Dr. Michael P. Gillespie Damage and Repair in the PNS Axons and dendrites may undergo repair if the cell body is intact, if the Schwann cells are functional, and if scar tissue does not form too quickly. Wallerian degeneration. Schwann cells adjacent to the site of injury grow torwards one another and form a regeneration tube. 130 Dr. Michael P. Gillespie 131 Dr. Michael P. Gillespie