SlideShare una empresa de Scribd logo

Pharmacology of peripheral nervous system

Satyajit Ghosh
Satyajit Ghosh

Pharmacology 4th semester

Educación
1 de 22
Descargar para leer sin conexión
PHARMACOLOGY OF PERIPHERAL NERVOUS SYSTEM SATYAJIT GHOSH B. PHARM 4TH SEMESTER
Autonomic Nervous System: General Consideration  Organisation and Function OF ANS: The ANS consists following nerve fibre: -  Sensory Information: Afferent Fibers and Reflex Arcs: - i. Afferent fibers from visceral structures are the first link in the reflex arcs of the autonomic system. With certain exceptions, such as local axon reflexes, most visceral reflexes are mediated through the CNS. ii. Visceral Afferent Fibers:  Information on the status of the visceral organs is transmitted to the CNS through two main sensory systems: a- the cranial nerve (parasympathetic) visceral sensory system b- the spinal (sympathetic) visceral afferent system.  The cranial visceral sensory system carries mainly mechanoreceptor and chemosensory information, whereas the afferents of the spinal visceral system principally convey sensations related to temperature and tissue injury of mechanical, chemical, or thermal origin.  Cranial visceral sensory information enters the CNS by four cranial nerves: the trigeminal (V), facial (VII), glossopharyngeal (IX), and vagus(X) nerves.  These four cranial nerves transmit visceral sensory information from the internal face and head (V); tongue (taste, VII); hard palate and upper part of the oropharynx (IX); and carotid body, lower part of the oropharynx, larynx, trachea, esophagus, and thoracic and abdominal organs (X), with the exception of the pelvic viscera. The visceral afferents from these four cranial nerves terminate topographically in the STN.
 Sensory afferents from visceral organs also enter the CNS from the spinal nerves. Those concerned with muscle chemo sensation may arise at all spinal levels, whereas sympathetic visceral sensory afferents generally arise at the thoracic levels where sympathetic preganglionic neurons are found.  In general, visceral afferents that enter the spinal nerves convey information concerned with temperature as well as nociceptive visceral inputs related to mechanical, chemical, and thermal stimulation.  Substance P and CGRP, present in afferent sensory fibers, dorsal root ganglia, and the dorsal horn of the spinal cord, communicate nociceptive stimuli from the periphery to the spinal cord and higher structures.  Central autonomic connections: i. There are no purely autonomic or somatic centres of integration, and extensive overlap occurs. Somatic responses always are accompanied by visceral responses and vice versa. ii. Autonomic reflexes can be elicited at the level of the spinal cord. The hypothalamus and the solitary tract nucleus (STN) generally are regarded as principal loci of integration of autonomic nervous system functions, which include regulation of body temperature, water balance, carbohydrate and fat metabolism, blood pressure, emotions, sleep, respiration, and reproduction. Signals are received through ascending spinobulbar pathways, the limbic system, neostriatum, cortex, and toa lesser extent other higher brain centers. iii. Stimulation of the STN and the hypothalamus activates bulbospinal pathways and hormonal output to mediate autonomic and motor responses. The hypothalamic nuclei that lie posteriorly and laterally are sympathetic in their main connections, whereas parasympathetic functions evidently are integrated by the midline nuclei in the region of the tuber cinereum and by nuclei lying anteriorly.
 Autonomic efferent: i. The output part of ANS has two divisions: the sympathetic division and the parasympathetic division. Most organ have dual innervation, i.e., they receive impulses from both sympathetic and parasympathetic division and the two divisions are functionally antagonistic. ii. The level of activity of innervated organ at a given moment is the algebraic sum of sympathetic and parasympathetic tone. iii. The sympathetic division is also known as fight – flight division. Sympathetic activity results in increased alertness and metabolic activities in order to prepare the body for an emergency situation. iv. The parasympathetic division is also known as rest – and – digest division because its activities conserve and restore body energy during time of rest or digesting a meal. v. Each division of ANS has two motor neurons 1- Preganglionic Neuron: It is the first motor neuron in any autonomic motor pathway. Its cell body is present in the brain or spinal cord; its axon exits the CNS as part of cranial or spinal nerve. The preganglionic neuron is a myelinated type B fibre extend to the autonomic ganglion, where it synapses with a post ganglionic neuron. 2- Postganglionic neuron: It is the second neuron of the autonomic motor pathway. Its cell body and dendrites are located in an autonomic ganglion, where it forms synapses with one or more presynaptic ganglion. The axon of post synaptic neuron is an unmyelinated type C fibre. that terminate in the visceral effector.  Divisions of the Peripheral Autonomic System: -  On the efferent side, the autonomic nervous system consists of two large divisions: a- the sympathetic or thoracolumbar outflow
b- the parasympathetic or craniosacral outflow.  The neurotransmitter of all preganglionic autonomic fibers, most postganglionic parasympathetic fibers, and a few postganglionic sympathetic fibers is ACh. Some postganglionic parasympathetic nerves use NO as a neurotransmitter and are termed nitrergic.  The majority of the postganglionic sympathetic fibers are adrenergic, in which the transmitter is NE. The terms cholinergic and adrenergic describe neurons that liberate ACh or NE, respectively.  Sympathetic Nervous System: - i. The cells that give rise to the preganglionic fibers of the sympathetic nervous system division lie mainly in the intermediolateral columns of the spinal cord and extend from the first thoracic to the second or third lumbar segment. ii. The axons from these cells are carried in the anterior (ventral) nerve roots and synapse, with neurons lying in sympathetic ganglia outside the cerebrospinal axis. iii. Sympathetic ganglia are found in three locations: paravertebral, prevertebral, and terminal. The 22 pairs of paravertebral sympathetic ganglia form the lateral chains on either side of the vertebral column. iv. The ganglia are connected to each other by nerve trunks and to the spinal nerves by rami communicantes. The white rami carry the preganglionic myelinated fibers that exit the spinal cord by the anterior spinal roots. The gray rami arise from the ganglia and carry postganglionic fibers back to the spinal nerves for distribution to sweat glands and pilomotor muscles and to blood vessels of skeletal muscle and skin. v. The prevertebral ganglia lie in the abdomen and the pelvis near the ventral surface of the bony vertebral column and consist mainly of the celiac (solar), superior mesenteric, aorticorenal, and inferior mesenteric ganglia. vi. The terminal ganglia are few in number, lie near the organs they innervate, and include ganglia connected with the urinary bladder, rectum and the cervical ganglia in the region of the neck.
vii. Preganglionic fibers issuing from the spinal cord may synapse with the neurons of more than one sympathetic ganglion. Many of the preganglionic fibers from the fifth to the last thoracic segment pass through the paravertebral ganglia to form the splanchnic nerves. Most of the splanchnic nerve fibers do not synapse until they reach the celiac ganglion; others directly innervate the adrenal medulla. viii. Postganglionic fibers arising from sympathetic ganglia innervate visceral structures of the thorax, abdomen, head, and neck. The trunk and the limbs are supplied by the sympathetic fibers in spinal nerves. ix. The prevertebral ganglia contain cell bodies whose axons innervate the glands and smooth muscles of the abdominal and the pelvic viscera. x. Many of the upper thoracic sympathetic fibers from the vertebral ganglia form terminal plexuses, such as the cardiac, oesophageal, and pulmonary plexuses. The sympathetic distribution to the head and the neck (vasomotor, pupillodilator, secretory, and pilomotor) is by means of the cervical sympathetic chain and its three ganglia. xi. All postganglionic fibers in this chain arise from cell bodies located in these three ganglia.  Parasympathetic Nervous System: - i. The parasympathetic nervous system consists of preganglionic fibers that originate in the CNS and their postganglionic connections. The regions of central origin are the midbrain, the medulla oblongata, and the sacral part of the spinal cord. ii. The midbrain, or tectal, outflow consists of fibers arising from the Edinger-Westphal nucleus of the third cranial nerve and going to the ciliary ganglion in the orbit. iii. The medullary outflow consists of the parasympathetic components of the VII, IX, and X cranial nerves. The fibers in the VII (facial) cranial nerve form the chorda tympani, which innervates the ganglia lying on the submaxillary and sublingual glands. They also form the greater superficial petrosal nerve, which innervates the sphenopalatine ganglion.
iv. The autonomic components of the IX (glossopharyngeal) cranial nerve innervate the otic ganglia. Postganglionic parasympathetic fibers from these ganglia supply the sphincter of the iris (pupillary constrictor muscle), the ciliary muscle, the salivary and lacrimal glands, and the mucous glands of the nose, mouth, and pharynx. These fibers also include vasodilator nerves to these same organs. v. Cranial nerve X (vagus) arises in the medulla and contains preganglionic fibers, most of which do not synapse until they reach the many small ganglia lying directly on or in the viscera of the thorax and abdomen. In the intestinal wall, the vagal fibers terminate around ganglion cells in the myenteric and submucosal plexuses. vi. Thus, in the parasympathetic branch of the autonomic nervous system, preganglionic fibers are very long, whereas postganglionic fibers are very short. vii. The parasympathetic sacral outflow consists of axons that arise from cells in the second, third, and fourth segments of the sacral cord and proceed as preganglionic fibers to form the pelvic nerves (nervi erigentes). They synapse in terminal ganglia lying near or within the bladder, rectum, and sexual organs. The vagal and sacral outflows provide motor and secretory fibers to thoracic, abdominal, and pelvic organs.  Enteric Nervous System: - i. The processes of mixing, propulsion, and absorption of nutrients in the GI tract are controlled locally through a restricted part of the peripheral nervous system called the ENS. ii. The ENS comprises components of the sympathetic and parasympathetic nervous systems and has sensory nerve connections through the spinal and nodose ganglia. iii. The ENS is involved in sensorimotor control and thus consists of both afferent sensory neurons and a number of motor nerves and interneurons that are organized principally into two nerve plexuses: the myenteric (Auerbach) plexus and the submucosal (Meissner) plexus. iv. The myenteric plexus, located between the longitudinal and circular muscle layers, plays an important role in the contraction and relaxation of GI smooth muscle.
v. The submucosal plexus is involved with secretory and absorptive functions of the GI epithelium, local blood flow, and neuroimmune activities. vi. Parasympathetic preganglionic inputs are provided to the GI tract via the vagus and pelvic nerves. ACh released from preganglionic neurons activates nAChRs on postganglionic neurons within the enteric ganglia. vii. Excitatory preganglionic input activates both excitatory and inhibitory motor neurons that control processes such as muscle contraction and secretion/absorption. viii. Postganglionic sympathetic nerves also synapse with intrinsic neurons and generally induce relaxation. Sympathetic input is excitatory (contractile) at some sphincters. Information from afferent and preganglionic neural inputs to the enteric ganglia is integrated and distributed by a network of interneurons.
Comparison of the Somatic and Autonomic Nervous System Somatic Nervous System Autonomic Nervous System Sensory input From somatic senses and special senses Mainly from interoceptors; some from somatic senses and special senses. Control of motor output Voluntary control from cerebral cortex, with contributions from basal ganglia, cerebellum, brain stem, and spinal cord. Involuntary control from hypothalamus, limbic system, brain stem, and spinal cord; limited control from cerebral cortex. Motor neuron pathway One-neuron pathway: Somatic motor neurons extending from CNS synapse directly with effector. Usually two-neuron pathway: Preganglionic neurons extending from CNS, synapse with postganglionic neurons in autonomic ganglion, and postganglionic neurons extending from ganglion synapse with visceral effector. Alternatively, preganglionic neurons may extend from CNS to synapse with chromaffin cells of adrenal medullae. Neurotransmitters and hormones All somatic motor neurons release only acetylcholine (ACh). All sympathetic and parasympathetic preganglionic neurons release ACh. Most sympathetic postganglionic neurons release NE; those to most sweat glands release ACh. All parasympathetic postganglionic neurons release ACh. Chromaffin cells of adrenal medullae release epinephrine and norepinephrine. Effectors Skeletal muscle Smooth muscle, cardiac muscle, and glands. Responses. Contraction of skeletal muscle Contraction or relaxation of smooth muscle; increased or decreased rate and force of contraction of cardiac muscle; increased or decreased secretions of glands.
Comparison of Sympathetic and Parasympathetic Division Sympathetic (Thoracolumbar) Parasympathetic (Craniosacral) Distribution Wide regions of body: skin, sweat glands, arrector pili muscles of hair follicles, adipose tissue, smooth muscle of blood vessels. Limited mainly to head and to viscera of thorax, abdomen, and pelvis; some blood vessels. Location of preganglionic neuron cell bodies and site of outflow Lateral gray horns of spinal cord segments T1–L2. Axons of preganglionic neurons constitute thoracolumbar outflow. Nuclei of cranial nerves III, VII, IX, and X and lateral gray matter of spinal cord segments S2–S4. Axons of preganglionic neurons constitute craniosacral outflow. Associated ganglia Sympathetic trunk ganglia and prevertebral ganglia Terminal ganglia Ganglia locations Close to CNS and distant from visceral effectors Typically, near or within wall of visceral effectors. Axon length and divergence Preganglionic neurons with short axons synapse with many postganglionic neurons with long axons that pass to many visceral effectors. Preganglionic neurons with long axons usually synapse with four to five postganglionic neurons with short axons that pass to single visceral effector. White and gray rami communicantes Both present; white rami communicantes contain myelinated preganglionic axons; gray rami communicantes contain unmyelinated postganglionic axons. Neither present Neurotransmitters Preganglionic neurons release acetylcholine (ACh), which is excitatory and stimulates postganglionic neurons; most postganglionic neurons release norepinephrine (NE); postganglionic neurons that innervate most sweat glands and some blood vessels in skeletal muscle release ACh. Preganglionic neurons release ACh, which is excitatory and stimulates postganglionic neurons; postganglionic neurons release ACh. Physiological effects Fight-or-flight responses Rest-and-digest activities
EFFECT OF SYMPATHETIC AND PARASYMPATHETIC DIVISION OF ANS Visceral Effector Effect of Sympathetic stimulation (α, β – Adrenergic Receptor) Effect of Parasympathetic Stimulation (Muscarinic ACh receptor) GLANDS Adrenal medullae Secretion of epinephrine and norepinephrine (nicotinic ACh receptors). No Innervation Lacrimal (tear) Slight secretion of tears (α). Secretion of tear Pancreas Inhibits secretion of digestive enzymes and the hormone insulin (α2) Promotes secretion of the hormone glucagon (β2) Secretion of digestive enzymes and the hormone insulin. Posterior pituitary Secretion of ADH (β1) No innervation. Pineal Increases synthesis and release of melatonin (β) No innervation. Sweat Increases sweating in most body regions (muscarinic ACh receptors) Sweating on palms and soles (α1) No innervation Adipose tissue Lipolysis (β1) Release of fatty acids into blood (β1 and β3) No innervation Liver Glycogenolysis Gluconeogenesis Decreased bile secretion (α and β2) Glycogen synthesis Increased bile secretion Kidney, Juxtaglomerular Cell Secretion of renin (β1) No innervation HEART Cardiac Muscle Increased Ionotropic Action Increased Chronotropic Action Increased Dromotropic Action Increased Heart Rate, C.O, B.P (β1) Decreased Ionotropic Action Decreased Chronotropic Action Decreased Dromotropic Action Decreased Heart Rate, C.O, B.P (M2) SMOOTH MUSCLE Iris, radial muscle Contraction → dilation of pupil (α1) No innervation Iris, circular muscle No innervation Contraction → constriction of pupil Ciliary muscle of eye Relaxation to adjust shape of lens for distant vision (β2). Contraction for close vision Lungs, bronchial muscle Relaxation → airway dilation (β2), Decreases bronchial mucus secretion Contraction → airway constriction, Increases bronchial mucus secretion
Gallbladder and ducts Relaxation to facilitate storage of bile in the gallbladder (β2). Contraction → release of bile into small intestine Stomach and intestine Decreased motility and tone (α1, α2, β2), Contraction of sphincters (α1) Decreased Peristalsis Increased motility and tone Relaxation of sphincters Increased Peristalsis Spleen Contraction and discharge of stored blood into general circulation (α1). No innervation Ureter Increases motility (α1). Increases motility (?). Urinary bladder Relaxation of muscular wall (β2) Contraction of internal urethral sphincter (α1). Contraction of muscular wall Relaxation of internal urethral sphincter Uterus Inhibits contraction in nonpregnant women (β2); Promotes contraction in pregnant women (α1). Minimal effect Sex organs In males: contraction of smooth muscle of vas deferens, prostate, and seminal vesicle resulting in ejaculation (α1). Vasodilation; erection of clitoris (females) and penis (males). Hair follicles, arrector pili muscle Contraction → erection of hairs resulting in goose bumps (α1) No innervation VASCULAR SMOOTH MUSCLE Salivary gland arterioles Vasoconstriction, which decreases secretion of saliva (α1) Vasodilation → Increases secretion of saliva Gastric gland arterioles Vasoconstriction, which inhibits secretion (α1) Secretion of Gastric juice Intestinal gland arterioles Vasoconstriction, which inhibits secretion (α1) Secretion of Intestinal juice Coronary (heart) arterioles Relaxation → vasodilation (β2) contraction → vasoconstriction (α1, α2) contraction → vasoconstriction (muscarinic Ach receptors) Contraction → Vasoconstriction Skin and mucosal arterioles Contraction → vasoconstriction (α1) Vasodilation Skeletal muscle arterioles Contraction → vasoconstriction (α1) relaxation → vasodilation (β2) relaxation → vasodilation (muscarinic ACh receptors) No Innervation Abdominal viscera arterioles Contraction → vasoconstriction (α1, β2) No Innervation Brain arterioles Slight contraction → vasoconstriction (α1) No Innervation Kidney arterioles Constriction of blood vessels → decreased urine volume (α1) No Innervation Systemic veins Contraction → Constriction (α1) Relaxation → Dilation (β2) No Innervation
 Neurohumoral Transmission: - I. Neurohumoral transmission refers to the transmission of impulse through synapse and neuro – effector junction by release of humoral or chemical substance. II. Neurohumoral transmitter a substance must fulfil the following criteria: 1. It should be present in the presynaptic neurone (usually along with enzymes synthesizing it). 2. It should be released in the medium following nerve stimulation. 3. Its application should produce responses identical to those produced by nerve stimulation. 4. Its effects should be antagonized or potentiated by other substances which similarly alter effects of nerve stimulation.  Steps in Neurohumoral Transmission: -  Axonal Conduction: - 1. Conduction refers to the passage of an electrical impulse along an axon or muscle fiber. At rest, the interior of axon is about 70 mV negative to the exterior. 2. In response to depolarization to a threshold level, an action potential is initiated at a local region of the membrane. The action potential consists of two phases. a- The initial phase is caused by a rapid increase in the permeability and inward movement of Na+ through voltage-sensitive Na+ channels, and a rapid depolarization from the resting potential continues to a positive overshoot. b- The second phase results from the rapid inactivation of the Na+ channel and the delayed opening of a K+ channel, which permits outward movement of K+ to terminate the depolarization. 3. The transmembrane ionic currents produce local circuit currents such that adjacent resting channels in the axon are activated, and excitation of an adjacent portion of the axonal membrane occurs, leading to propagation of the action potential without decrement along the axon.
4. The region that has undergone depolarization remains momentarily in a refractory state. With the exception of the local anaesthetics, few drugs modify axonal conduction in the doses employed therapeutically. 5. The puffer fish poison, tetrodotoxin, and a close congener found in some shellfish, saxitoxin, selectively block axonal conduction by blocking the voltage-sensitive Na+ channel and preventing the increase in Na+ permeability associated with the rising phase of the action potential. 6. In contrast, batrachotoxin, an extremely potent steroidal alkaloid secreted by a South American frog, produces paralysis through a selective increase in permeability of the Na+ channel, which induces a persistent depolarization. 7. Scorpion toxins are peptides that also cause persistent depolarization by inhibiting the inactivation process.  Junctional Transmission: - The term transmission refers to the passage of an impulse across a synaptic or neuroeffector junction. The arrival of the action potential at the axonal terminals initiates a series of events that trigger transmission of an excitatory or inhibitory biochemical message across the synapse or neuroeffector junction. These events are the following: 1. Storage and release of transmitter: -  The nonpeptide (small-molecule) neurotransmitters, such as biogenic amines, are largely synthesized in the region of the axonal terminals and stored there in synaptic vesicles.  Neurotransmitter transport into storage vesicles is driven by an electrochemical gradient generated by the vesicular proton pump (vesicular ATPase).  Synaptic vesicles cluster in discrete areas underlying the presynaptic plasma membrane, termed active zones. Proteins in the vesicular membrane (e.g., synapsin, synaptophysin, synaptogyrin) are involved in development and trafficking of the storage vesicle to the active zone.
 The processes of priming, docking, fusion, and exocytosis involve the interactions of proteins in the vesicles and plasma membranes and the rapid entry of extracellular Ca2+ and its binding to synaptotagmins. Life Cycle of a Storage Vesicle, Molecular Mechanism of Exocytosis: -  Fusion of the storage vesicle and plasma membrane involves formation of a multiprotein complex that includes proteins in the membrane of the synaptic vesicle, proteins embedded in the inner surface of the plasma membrane, and several cytosolic components.  These proteins are referred to as SNARE proteins. Through the assembly of these proteins, vesicles draw near the membrane (priming, docking), spatially prepared for the next step, which the entry of Ca2+ initiates.  When Ca2+ enters with the action potential, fusion and exocytosis occur rapidly. After fusion, the chaperone ATPase N-ethylmaleamide sensitive factor (NSF) and its soluble NSF attachment protein, synaptosome-associated Protein (SNAP) adapters catalyse dissociation of the SNARE complex.
 During the resting state, there is continual slow release of isolated quanta of the transmitter; this produces electrical responses (miniature end-plate potentials or mepps) at the postjunctional membrane that are associated with the maintenance of the physiological responsiveness of the effector organ.  The action potential causes the synchronous release of several hundred quanta of neurotransmitter. In the exocytosis process, the contents of the vesicles, including enzymes and other proteins, are discharged to the synaptic space.  Synaptic vesicles may either fully exocytose with complete fusion or form a transient, nanometer-size pore that closes after transmitter has escaped, “kiss-and-run” exocytosis.  In full-fusion exocytosis, the pit formed by the vesicle’s fusing with the plasma membrane is clathrin-coated and retrieved from the membrane via endocytosis and transported to an endosome for full recycling.  During kiss-and-run exocytosis, the pore closes, and the vesicle is immediately and locally recycled for reuse in neurotransmitter repackaging. Modulation of Transmitter Release: -  A number of autocrine and paracrine factors may influence the exocytotic process, including the released neurotransmitter itself.  Adenosine, DA, glutamate, GABA, prostaglandins, and enkephalins influence neurally mediated release of neurotransmitters. Receptors for these factors exist in the membranes of the soma, dendrites, and axons of neurons: A- Soma-dendritic receptors, when activated, primarily modify functions of the soma-dendritic region, such as protein synthesis and generation of action potentials. B- Presynaptic receptors, when activated, modify functions of the terminal region, such as synthesis and release of transmitters. Two main classes of presynaptic receptors have been identified on most neurons:
a- Heteroreceptors are presynaptic receptors that respond to neurotransmitters, neuromodulators, or neurohormones released from adjacent neurons or cells. For example, NE can influence the release of ACh from parasympathetic neurons by acting on α2A, α2B, and α2C receptors, whereas ACh can influence the release of NE from sympathetic neurons by acting on M2 and M4 receptors. b- Autoreceptors are receptors located on axon terminals of a neuron through which the neuron’s own transmitter can modify transmitter synthesis and release. For example, NE released from sympathetic neurons may interact with α2A and α2C receptors to inhibit neurally released NE. Similarly, ACh released from parasympathetic neurons may interact with M2 and M4 receptors to inhibit neurally released ACh. 2. Interaction of the transmitter with postjunctional receptors and production of the postjunctional potential: -  The transmitter diffuses across the synaptic cleft and combines with specialized receptors on the postjunctional membrane; results in a localized increase in the ionic permeability, or conductance, of the membrane.  With certain exceptions, one of three types of permeability change can occur:  Generalized increase in the permeability to cations (notably Na+ but occasionally Ca2+ ), resulting in a localized depolarization of the membrane, that is, an EPSP.  Selective increase in permeability to anions, usually Cl– , resulting in stabilization or actual hyperpolarization of the membrane, which constitutes an IPSP.  Increased permeability to K+ . Because the K+ gradient is directed out of the cell, hyperpolarization and stabilization of the membrane potential occur (an IPSP).
 Electric potential changes associated with the EPSP and IPSP at most sites are the results of passive fluxes of ions down their concentration gradients. The changes in channel permeability that cause these potential changes are specifically regulated by the specialized postjunctional receptors for the neurotransmitter that initiates the response.  These receptors may be clustered on the effector cell surface, as seen at the NMJs of skeletal muscle and other discrete synapses, or distributed more uniformly, as observed in smooth muscle. These high-conductance, ligand-gated ion channels usually permit passage of Na+ or Cl– ; K+ and Ca2+ are involved less frequently.  In the presence of an appropriate neurotransmitter, the channel opens rapidly to a high-conductance state, remains open for about a millisecond, and then closes. A short square-wave pulse of current is observed as a result of the channel’s opening and closing. The summation of these events gives rise to the EPSP.  The ligand-gated channels belong to a superfamily of ionotropic receptor proteins that includes the nicotinic, glutamate, and certain 5HT3 and purine receptors, which conduct primarily Na+ , cause depolarization, and are excitatory; and GABA acid and glycine receptors, which conduct Cl– , cause hyperpolarization, and are inhibitory.  Neurotransmitters also can modulate the permeability of K+ and Ca2+ channels indirectly. In these cases, the receptor and channel are separate proteins, and information is conveyed between them by G proteins. 3. Initiation of postjunctional activity: -  If an EPSP exceeds a certain threshold value, it initiates a propagated action potential in a postsynaptic neuron or a muscle action potential in skeletal or cardiac muscle by activating voltage-sensitive channels in the immediate vicinity.  In certain smooth muscle types in which propagated impulses are minimal, an EPSP may increase the rate of spontaneous depolarization, cause Ca2+ release, and enhance muscle tone; in gland cells, the EPSP initiates secretion through Ca2+ mobilization.  An IPSP, which is found in neurons and smooth muscle but not in skeletal muscle, will oppose excitatory potentials.
4. Destruction or dissipation of the transmitter: -  When impulses can be transmitted across junctions at frequencies up to several hundred per second, there must be an efficient means of disposing of the transmitter following each impulse.  At cholinergic synapses involved in rapid neurotransmission, high and localized concentrations of AChE are available for this purpose. When AChE activity is inhibited, removal of the transmitter is accomplished principally by diffusion. Under these circumstances, the effects of released ACh are potentiated and prolonged.  Rapid termination of NE occurs by a combination of simple diffusion and reuptake by the axonal terminals of most of the released NE. Termination of the action of amino acid transmitters results from their active transport into neurons and surrounding glia. Peptide neurotransmitters are hydrolysed by various peptidases and dissipated by diffusion.  Cotransmission: i. Cotransmission is defined as control of a single target cell by two or more substances released from one neuron in response to the same neuronal event. ii. In the ANS besides the primary transmitters like ACh and NA, neurones also release purines (ATP, adenosine), peptides (vasoactive intestinal peptide (VIP), neuropeptide-Y (NPY), substance P, enkephalins, somatostatin, etc.), nitric oxide and prostaglandins as cotransmitters. iii. In most autonomic cholinergic neurons’ VIP is associated with ACh, while ATP is associated with both ACh and NA. The transmitter at some parasympathetic sites is N0. and these are called nitrergic nerves. iv. Vascular adrenergic nerves contain NPY which causes long lasting vasoconstriction. v. The cotransmitter is stored in the same neurone but in distinct synaptic vesicles or locations. However, ATP is stored with NA in the same vesicle. On being released by nerve impulse the cotransmitter may serve to regulate the presynaptic release of the primary transmitter and/or postsynaptic sensitivity to it (neuromodulator role).
vi. The time-course of action of the primary transmitter and the cotransmitter is usually different. The cotransmitter VIP of parasympathetic neurones produces a slow and long-lasting response, while another one (NO) has an intermediate time-course of action between VIP and ACh (fast acting). Similarly, in sympathetic neurones, the cotransmitter PY is slower acting and ATP faster ac ting than NA.

Recomendados

Neurohumoral transmission in CNS
Neurohumoral transmission in CNSNeurohumoral transmission in CNS
Neurohumoral transmission in CNSSanchit Dhankhar
 
UNIT III_cholinergic neurotransmitter agonist
UNIT III_cholinergic neurotransmitter agonistUNIT III_cholinergic neurotransmitter agonist
UNIT III_cholinergic neurotransmitter agonistSONALI PAWAR
 
Neurohumoral Transmission in CNS
Neurohumoral Transmission in CNSNeurohumoral Transmission in CNS
Neurohumoral Transmission in CNSRaveena Chauhan
 
CHOLINERGIC BLOCKERS(CHOLINOLYTICS)
CHOLINERGIC BLOCKERS(CHOLINOLYTICS)CHOLINERGIC BLOCKERS(CHOLINOLYTICS)
CHOLINERGIC BLOCKERS(CHOLINOLYTICS)kencha swathi
 
ORGANSATION & FUNCTIONS OF ANS
ORGANSATION & FUNCTIONS OF ANSORGANSATION & FUNCTIONS OF ANS
ORGANSATION & FUNCTIONS OF ANSHeena Parveen
 
Sympatholytic medicinal chemistry b. pharm.
Sympatholytic medicinal chemistry b. pharm. Sympatholytic medicinal chemistry b. pharm.
Sympatholytic medicinal chemistry b. pharm. AZCPh
 
CNS STIMULANTS & NOOTROPICS (COGNITION ENHANCERS) for B.Pharm & Pharm.D
CNS STIMULANTS & NOOTROPICS (COGNITION ENHANCERS) for B.Pharm & Pharm.DCNS STIMULANTS & NOOTROPICS (COGNITION ENHANCERS) for B.Pharm & Pharm.D
CNS STIMULANTS & NOOTROPICS (COGNITION ENHANCERS) for B.Pharm & Pharm.DKameshwaran Sugavanam
 
Biosynthesis & Metabolism of catecholamine
Biosynthesis & Metabolism of catecholamineBiosynthesis & Metabolism of catecholamine
Biosynthesis & Metabolism of catecholamineDrParthiban1
 

Recomendados

Neurohumoral transmission in CNS
Neurohumoral transmission in CNSNeurohumoral transmission in CNS
Neurohumoral transmission in CNSSanchit Dhankhar
 
UNIT III_cholinergic neurotransmitter agonist
UNIT III_cholinergic neurotransmitter agonistUNIT III_cholinergic neurotransmitter agonist
UNIT III_cholinergic neurotransmitter agonistSONALI PAWAR
 
Neurohumoral Transmission in CNS
Neurohumoral Transmission in CNSNeurohumoral Transmission in CNS
Neurohumoral Transmission in CNSRaveena Chauhan
 
CHOLINERGIC BLOCKERS(CHOLINOLYTICS)
CHOLINERGIC BLOCKERS(CHOLINOLYTICS)CHOLINERGIC BLOCKERS(CHOLINOLYTICS)
CHOLINERGIC BLOCKERS(CHOLINOLYTICS)kencha swathi
 
ORGANSATION & FUNCTIONS OF ANS
ORGANSATION & FUNCTIONS OF ANSORGANSATION & FUNCTIONS OF ANS
ORGANSATION & FUNCTIONS OF ANSHeena Parveen
 
Sympatholytic medicinal chemistry b. pharm.
Sympatholytic medicinal chemistry b. pharm. Sympatholytic medicinal chemistry b. pharm.
Sympatholytic medicinal chemistry b. pharm. AZCPh
 
CNS STIMULANTS & NOOTROPICS (COGNITION ENHANCERS) for B.Pharm & Pharm.D
CNS STIMULANTS & NOOTROPICS (COGNITION ENHANCERS) for B.Pharm & Pharm.DCNS STIMULANTS & NOOTROPICS (COGNITION ENHANCERS) for B.Pharm & Pharm.D
CNS STIMULANTS & NOOTROPICS (COGNITION ENHANCERS) for B.Pharm & Pharm.DKameshwaran Sugavanam
 
Biosynthesis & Metabolism of catecholamine
Biosynthesis & Metabolism of catecholamineBiosynthesis & Metabolism of catecholamine
Biosynthesis & Metabolism of catecholamineDrParthiban1
 
parasympathomimetics drugs
parasympathomimetics drugs parasympathomimetics drugs
parasympathomimetics drugsMr. MOHD FAHAD
 
Sympathomimetic agents: SAR of Sympathomimetic agents
Sympathomimetic agents: SAR of Sympathomimetic agentsSympathomimetic agents: SAR of Sympathomimetic agents
Sympathomimetic agents: SAR of Sympathomimetic agentsSubham Kumar Vishwakarma
 
ALCOHOL & DISULFIRAM - PHARMACOLOGY
ALCOHOL & DISULFIRAM - PHARMACOLOGYALCOHOL & DISULFIRAM - PHARMACOLOGY
ALCOHOL & DISULFIRAM - PHARMACOLOGYKameshwaran Sugavanam
 
NEUROHUMORAL TRANSMISSION
NEUROHUMORAL TRANSMISSIONNEUROHUMORAL TRANSMISSION
NEUROHUMORAL TRANSMISSIONHeena Parveen
 
Centrally acting muscle relaxant
Centrally acting muscle relaxant Centrally acting muscle relaxant
Centrally acting muscle relaxant Sujit Karpe
 
Acetylcholine ppt
Acetylcholine pptAcetylcholine ppt
Acetylcholine pptAbhishekJoshi312
 
kinetics of protein binding.pptx
kinetics of protein binding.pptxkinetics of protein binding.pptx
kinetics of protein binding.pptxGitanjaliMehetre1
 
PHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdf
PHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdfPHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdf
PHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdfRupaSingh83
 
BIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSION
BIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSIONBIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSION
BIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSIONWasiu Adeseji
 
Neurohumoral transmission in ans final fully1cl f
Neurohumoral transmission in ans final fully1cl fNeurohumoral transmission in ans final fully1cl f
Neurohumoral transmission in ans final fully1cl frahulsharma3589
 
Drugs used in myasthenia gravis and galucoma
Drugs used in myasthenia gravis and galucomaDrugs used in myasthenia gravis and galucoma
Drugs used in myasthenia gravis and galucomaAshviniGovande
 
Organisation of ans
Organisation of ansOrganisation of ans
Organisation of ansSmita Jain
 
Hallucinogens pharmacology
Hallucinogens pharmacologyHallucinogens pharmacology
Hallucinogens pharmacologyKoppala RVS Chaitanya
 
Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)
Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)
Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)Yogesh Tiwari
 
Neurohumoral transission in CNS
Neurohumoral transission in CNSNeurohumoral transission in CNS
Neurohumoral transission in CNSDekollu Suku
 
Unit 1 General Pharmacology (As per PCI syllabus)
Unit 1 General Pharmacology (As per PCI syllabus)Unit 1 General Pharmacology (As per PCI syllabus)
Unit 1 General Pharmacology (As per PCI syllabus)Mirza Anwar Baig
 
SAR and Synthesis of adrenergic blockers
SAR and Synthesis of adrenergic blockersSAR and Synthesis of adrenergic blockers
SAR and Synthesis of adrenergic blockersDrParthiban1
 
DRUG METABOLISM-MEDICINAL CHEMISTRY
DRUG METABOLISM-MEDICINAL CHEMISTRYDRUG METABOLISM-MEDICINAL CHEMISTRY
DRUG METABOLISM-MEDICINAL CHEMISTRYNavdha Soni
 
Unit 3 Drugs Affecting PNS (As per PCI syllabus)
Unit 3 Drugs Affecting PNS (As per PCI syllabus)Unit 3 Drugs Affecting PNS (As per PCI syllabus)
Unit 3 Drugs Affecting PNS (As per PCI syllabus)Mirza Anwar Baig
 
Parasympatholytic drugs
Parasympatholytic drugsParasympatholytic drugs
Parasympatholytic drugsShagufta Farooqui
 
Anatomy of autonomic nervous system
Anatomy of autonomic nervous systemAnatomy of autonomic nervous system
Anatomy of autonomic nervous systemMBBS IMS MSU
 
AUTONOMIC NERVOUS SYSTEM
AUTONOMIC NERVOUS SYSTEMAUTONOMIC NERVOUS SYSTEM
AUTONOMIC NERVOUS SYSTEMSado Anatomist
 

Más contenido relacionado

La actualidad más candente

parasympathomimetics drugs
parasympathomimetics drugs parasympathomimetics drugs
parasympathomimetics drugsMr. MOHD FAHAD
 
Sympathomimetic agents: SAR of Sympathomimetic agents
Sympathomimetic agents: SAR of Sympathomimetic agentsSympathomimetic agents: SAR of Sympathomimetic agents
Sympathomimetic agents: SAR of Sympathomimetic agentsSubham Kumar Vishwakarma
 
NEUROHUMORAL TRANSMISSION
NEUROHUMORAL TRANSMISSIONNEUROHUMORAL TRANSMISSION
NEUROHUMORAL TRANSMISSIONHeena Parveen
 
Centrally acting muscle relaxant
Centrally acting muscle relaxant Centrally acting muscle relaxant
Centrally acting muscle relaxant Sujit Karpe
 
kinetics of protein binding.pptx
kinetics of protein binding.pptxkinetics of protein binding.pptx
kinetics of protein binding.pptxGitanjaliMehetre1
 
PHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdf
PHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdfPHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdf
PHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdfRupaSingh83
 
BIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSION
BIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSIONBIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSION
BIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSIONWasiu Adeseji
 
Neurohumoral transmission in ans final fully1cl f
Neurohumoral transmission in ans final fully1cl fNeurohumoral transmission in ans final fully1cl f
Neurohumoral transmission in ans final fully1cl frahulsharma3589
 
Drugs used in myasthenia gravis and galucoma
Drugs used in myasthenia gravis and galucomaDrugs used in myasthenia gravis and galucoma
Drugs used in myasthenia gravis and galucomaAshviniGovande
 
Organisation of ans
Organisation of ansOrganisation of ans
Organisation of ansSmita Jain
 
Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)
Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)
Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)Yogesh Tiwari
 
Neurohumoral transission in CNS
Neurohumoral transission in CNSNeurohumoral transission in CNS
Neurohumoral transission in CNSDekollu Suku
 
Unit 1 General Pharmacology (As per PCI syllabus)
Unit 1 General Pharmacology (As per PCI syllabus)Unit 1 General Pharmacology (As per PCI syllabus)
Unit 1 General Pharmacology (As per PCI syllabus)Mirza Anwar Baig
 
SAR and Synthesis of adrenergic blockers
SAR and Synthesis of adrenergic blockersSAR and Synthesis of adrenergic blockers
SAR and Synthesis of adrenergic blockersDrParthiban1
 
DRUG METABOLISM-MEDICINAL CHEMISTRY
DRUG METABOLISM-MEDICINAL CHEMISTRYDRUG METABOLISM-MEDICINAL CHEMISTRY
DRUG METABOLISM-MEDICINAL CHEMISTRYNavdha Soni
 
Unit 3 Drugs Affecting PNS (As per PCI syllabus)
Unit 3 Drugs Affecting PNS (As per PCI syllabus)Unit 3 Drugs Affecting PNS (As per PCI syllabus)
Unit 3 Drugs Affecting PNS (As per PCI syllabus)Mirza Anwar Baig
 

La actualidad más candente (20)

parasympathomimetics drugs
parasympathomimetics drugs parasympathomimetics drugs
parasympathomimetics drugs
 
Sympathomimetic agents: SAR of Sympathomimetic agents
Sympathomimetic agents: SAR of Sympathomimetic agentsSympathomimetic agents: SAR of Sympathomimetic agents
Sympathomimetic agents: SAR of Sympathomimetic agents
 
ALCOHOL & DISULFIRAM - PHARMACOLOGY
ALCOHOL & DISULFIRAM - PHARMACOLOGYALCOHOL & DISULFIRAM - PHARMACOLOGY
ALCOHOL & DISULFIRAM - PHARMACOLOGY
 
NEUROHUMORAL TRANSMISSION
NEUROHUMORAL TRANSMISSIONNEUROHUMORAL TRANSMISSION
NEUROHUMORAL TRANSMISSION
 
Centrally acting muscle relaxant
Centrally acting muscle relaxant Centrally acting muscle relaxant
Centrally acting muscle relaxant
 
Acetylcholine ppt
Acetylcholine pptAcetylcholine ppt
Acetylcholine ppt
 
kinetics of protein binding.pptx
kinetics of protein binding.pptxkinetics of protein binding.pptx
kinetics of protein binding.pptx
 
PHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdf
PHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdfPHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdf
PHARMACOLOGY OF DRUGS ACTING ON PERIPHERAL NERVOUS SYSTEM.pdf
 
BIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSION
BIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSIONBIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSION
BIOSYNTHESIS OF ACETYLCHOLINE IN CNS AND CHOLINERGIC TRANSMISSION
 
Neurohumoral transmission in ans final fully1cl f
Neurohumoral transmission in ans final fully1cl fNeurohumoral transmission in ans final fully1cl f
Neurohumoral transmission in ans final fully1cl f
 
Drugs used in myasthenia gravis and galucoma
Drugs used in myasthenia gravis and galucomaDrugs used in myasthenia gravis and galucoma
Drugs used in myasthenia gravis and galucoma
 
Organisation of ans
Organisation of ansOrganisation of ans
Organisation of ans
 
Hallucinogens pharmacology
Hallucinogens pharmacologyHallucinogens pharmacology
Hallucinogens pharmacology
 
Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)
Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)
Narcotic and Nonnarcotic analgesic(Medicinal Chemistry)
 
Neurohumoral transission in CNS
Neurohumoral transission in CNSNeurohumoral transission in CNS
Neurohumoral transission in CNS
 
Unit 1 General Pharmacology (As per PCI syllabus)
Unit 1 General Pharmacology (As per PCI syllabus)Unit 1 General Pharmacology (As per PCI syllabus)
Unit 1 General Pharmacology (As per PCI syllabus)
 
SAR and Synthesis of adrenergic blockers
SAR and Synthesis of adrenergic blockersSAR and Synthesis of adrenergic blockers
SAR and Synthesis of adrenergic blockers
 
DRUG METABOLISM-MEDICINAL CHEMISTRY
DRUG METABOLISM-MEDICINAL CHEMISTRYDRUG METABOLISM-MEDICINAL CHEMISTRY
DRUG METABOLISM-MEDICINAL CHEMISTRY
 
Unit 3 Drugs Affecting PNS (As per PCI syllabus)
Unit 3 Drugs Affecting PNS (As per PCI syllabus)Unit 3 Drugs Affecting PNS (As per PCI syllabus)
Unit 3 Drugs Affecting PNS (As per PCI syllabus)
 
Parasympatholytic drugs
Parasympatholytic drugsParasympatholytic drugs
Parasympatholytic drugs
 

Similar a Pharmacology of peripheral nervous system

Anatomy of autonomic nervous system
Anatomy of autonomic nervous systemAnatomy of autonomic nervous system
Anatomy of autonomic nervous systemMBBS IMS MSU
 
AUTONOMIC NERVOUS SYSTEM
AUTONOMIC NERVOUS SYSTEMAUTONOMIC NERVOUS SYSTEM
AUTONOMIC NERVOUS SYSTEMSado Anatomist
 
Human Anatomy and Physiology 1 - Chapter 7 and 8.pptx
Human Anatomy and Physiology 1 - Chapter 7 and 8.pptxHuman Anatomy and Physiology 1 - Chapter 7 and 8.pptx
Human Anatomy and Physiology 1 - Chapter 7 and 8.pptxRuchithChandeepa
 
Invertebrates nervous-system-by-resty-samosa
Invertebrates nervous-system-by-resty-samosaInvertebrates nervous-system-by-resty-samosa
Invertebrates nervous-system-by-resty-samosaResty Samosa
 
NERVOUS_SYSTEM.pptx
NERVOUS_SYSTEM.pptxNERVOUS_SYSTEM.pptx
NERVOUS_SYSTEM.pptxRishavDhar3
 
Chap 10 the peripheral nervous system
Chap 10 the peripheral nervous systemChap 10 the peripheral nervous system
Chap 10 the peripheral nervous systemSr Anne Ponnattil
 
The parasympathetic nervous system
The parasympathetic nervous systemThe parasympathetic nervous system
The parasympathetic nervous systemAashiSingla2
 
Neurological Basis Of Behavior Presentation.pptx
Neurological Basis Of Behavior Presentation.pptxNeurological Basis Of Behavior Presentation.pptx
Neurological Basis Of Behavior Presentation.pptxMahekShaikh72
 
Lec. 20 nervous system.ppt
Lec. 20 nervous system.pptLec. 20 nervous system.ppt
Lec. 20 nervous system.pptRajuPanse
 
The nervous system
The nervous systemThe nervous system
The nervous systemMukul Kumar
 
Module 2 biological bases of behaviour
Module 2 biological bases of behaviourModule 2 biological bases of behaviour
Module 2 biological bases of behaviourShanique wallace
 

Similar a Pharmacology of peripheral nervous system (20)

Anatomy of autonomic nervous system
Anatomy of autonomic nervous systemAnatomy of autonomic nervous system
Anatomy of autonomic nervous system
 
AUTONOMIC NERVOUS SYSTEM
AUTONOMIC NERVOUS SYSTEMAUTONOMIC NERVOUS SYSTEM
AUTONOMIC NERVOUS SYSTEM
 
Cns 8
Cns 8Cns 8
Cns 8
 
Human Anatomy and Physiology 1 - Chapter 7 and 8.pptx
Human Anatomy and Physiology 1 - Chapter 7 and 8.pptxHuman Anatomy and Physiology 1 - Chapter 7 and 8.pptx
Human Anatomy and Physiology 1 - Chapter 7 and 8.pptx
 
Invertebrates nervous-system-by-resty-samosa
Invertebrates nervous-system-by-resty-samosaInvertebrates nervous-system-by-resty-samosa
Invertebrates nervous-system-by-resty-samosa
 
NERVOUS_SYSTEM.pptx
NERVOUS_SYSTEM.pptxNERVOUS_SYSTEM.pptx
NERVOUS_SYSTEM.pptx
 
Nervous system
Nervous systemNervous system
Nervous system
 
Chap 10 the peripheral nervous system
Chap 10 the peripheral nervous systemChap 10 the peripheral nervous system
Chap 10 the peripheral nervous system
 
Anatomy of ns
Anatomy of nsAnatomy of ns
Anatomy of ns
 
7. ans 08-09
7. ans 08-097. ans 08-09
7. ans 08-09
 
The parasympathetic nervous system
The parasympathetic nervous systemThe parasympathetic nervous system
The parasympathetic nervous system
 
Neurological Basis Of Behavior Presentation.pptx
Neurological Basis Of Behavior Presentation.pptxNeurological Basis Of Behavior Presentation.pptx
Neurological Basis Of Behavior Presentation.pptx
 
Nervous system1
Nervous system1Nervous system1
Nervous system1
 
Trigeminal nerve
Trigeminal nerveTrigeminal nerve
Trigeminal nerve
 
Lec. 20 nervous system.ppt
Lec. 20 nervous system.pptLec. 20 nervous system.ppt
Lec. 20 nervous system.ppt
 
The nervous system
The nervous systemThe nervous system
The nervous system
 
INTRODUCTION TO NEURO NURSING
INTRODUCTION TO NEURO NURSINGINTRODUCTION TO NEURO NURSING
INTRODUCTION TO NEURO NURSING
 
The autonomic nervous
The autonomic nervousThe autonomic nervous
The autonomic nervous
 
Trigeminal nerve ppt
Trigeminal nerve pptTrigeminal nerve ppt
Trigeminal nerve ppt
 
Module 2 biological bases of behaviour
Module 2 biological bases of behaviourModule 2 biological bases of behaviour
Module 2 biological bases of behaviour
 

Más de Satyajit Ghosh

Thin layer chromatographic analysis of Beta Lactam Antibiotics
Thin layer chromatographic analysis of Beta Lactam AntibioticsThin layer chromatographic analysis of Beta Lactam Antibiotics
Thin layer chromatographic analysis of Beta Lactam AntibioticsSatyajit Ghosh
 
Adverse drug reaction (ADR)
Adverse drug reaction (ADR)Adverse drug reaction (ADR)
Adverse drug reaction (ADR)Satyajit Ghosh
 
Pharmacodynamics (Receptor Pharmacology)
Pharmacodynamics (Receptor Pharmacology)Pharmacodynamics (Receptor Pharmacology)
Pharmacodynamics (Receptor Pharmacology)Satyajit Ghosh
 
Pharmacokinetics (ADME)
Pharmacokinetics (ADME)Pharmacokinetics (ADME)
Pharmacokinetics (ADME)Satyajit Ghosh
 
Drugs used in glaucoma and myasthenia gravis
Drugs used in glaucoma and myasthenia gravisDrugs used in glaucoma and myasthenia gravis
Drugs used in glaucoma and myasthenia gravisSatyajit Ghosh
 
Periphral acting muscle relaxant & nm blocking agents
Periphral acting muscle relaxant & nm blocking agentsPeriphral acting muscle relaxant & nm blocking agents
Periphral acting muscle relaxant & nm blocking agentsSatyajit Ghosh
 
Cholinergic transmission
Cholinergic transmissionCholinergic transmission
Cholinergic transmissionSatyajit Ghosh
 
Adrenergic transmission
Adrenergic transmissionAdrenergic transmission
Adrenergic transmissionSatyajit Ghosh
 
Conservation of medicinal plant
Conservation of medicinal plantConservation of medicinal plant
Conservation of medicinal plantSatyajit Ghosh
 
Cultivation, isolation, processing, and storage of the drugs from natural origin
Cultivation, isolation, processing, and storage of the drugs from natural originCultivation, isolation, processing, and storage of the drugs from natural origin
Cultivation, isolation, processing, and storage of the drugs from natural originSatyajit Ghosh
 

Más de Satyajit Ghosh (15)

Thin layer chromatographic analysis of Beta Lactam Antibiotics
Thin layer chromatographic analysis of Beta Lactam AntibioticsThin layer chromatographic analysis of Beta Lactam Antibiotics
Thin layer chromatographic analysis of Beta Lactam Antibiotics
 
Adverse drug reaction (ADR)
Adverse drug reaction (ADR)Adverse drug reaction (ADR)
Adverse drug reaction (ADR)
 
Pharmacodynamics (Receptor Pharmacology)
Pharmacodynamics (Receptor Pharmacology)Pharmacodynamics (Receptor Pharmacology)
Pharmacodynamics (Receptor Pharmacology)
 
Pharmacokinetics (ADME)
Pharmacokinetics (ADME)Pharmacokinetics (ADME)
Pharmacokinetics (ADME)
 
Drugs used in glaucoma and myasthenia gravis
Drugs used in glaucoma and myasthenia gravisDrugs used in glaucoma and myasthenia gravis
Drugs used in glaucoma and myasthenia gravis
 
Periphral acting muscle relaxant & nm blocking agents
Periphral acting muscle relaxant & nm blocking agentsPeriphral acting muscle relaxant & nm blocking agents
Periphral acting muscle relaxant & nm blocking agents
 
Cholinergic transmission
Cholinergic transmissionCholinergic transmission
Cholinergic transmission
 
Adrenergic transmission
Adrenergic transmissionAdrenergic transmission
Adrenergic transmission
 
Plant tissue culture
Plant tissue culturePlant tissue culture
Plant tissue culture
 
Secondary metabolites
Secondary metabolitesSecondary metabolites
Secondary metabolites
 
Primary metabolites
Primary metabolitesPrimary metabolites
Primary metabolites
 
Marine drugs
Marine drugsMarine drugs
Marine drugs
 
Plant product
Plant productPlant product
Plant product
 
Conservation of medicinal plant
Conservation of medicinal plantConservation of medicinal plant
Conservation of medicinal plant
 
Cultivation, isolation, processing, and storage of the drugs from natural origin
Cultivation, isolation, processing, and storage of the drugs from natural originCultivation, isolation, processing, and storage of the drugs from natural origin
Cultivation, isolation, processing, and storage of the drugs from natural origin
 

Último

Separation of Lanthanides/ Lanthanides and Actinides
Separation of Lanthanides/ Lanthanides and ActinidesSeparation of Lanthanides/ Lanthanides and Actinides
Separation of Lanthanides/ Lanthanides and ActinidesFatimaKhan178732
 
MENTAL STATUS EXAMINATION format.docx
MENTAL STATUS EXAMINATION format.docxMENTAL STATUS EXAMINATION format.docx
MENTAL STATUS EXAMINATION format.docxPoojaSen20
 
Crayon Activity Handout For the Crayon A
Crayon Activity Handout For the Crayon ACrayon Activity Handout For the Crayon A
Crayon Activity Handout For the Crayon AUnboundStockton
 
Q4-W6-Restating Informational Text Grade 3
Q4-W6-Restating Informational Text Grade 3Q4-W6-Restating Informational Text Grade 3
Q4-W6-Restating Informational Text Grade 3JemimahLaneBuaron
 
Paris 2024 Olympic Geographies - an activity
Paris 2024 Olympic Geographies - an activityParis 2024 Olympic Geographies - an activity
Paris 2024 Olympic Geographies - an activityGeoBlogs
 
Kisan Call Centre - To harness potential of ICT in Agriculture by answer farm...
Kisan Call Centre - To harness potential of ICT in Agriculture by answer farm...Kisan Call Centre - To harness potential of ICT in Agriculture by answer farm...
Kisan Call Centre - To harness potential of ICT in Agriculture by answer farm...Krashi Coaching
 
Introduction to AI in Higher Education_draft.pptx
Introduction to AI in Higher Education_draft.pptxIntroduction to AI in Higher Education_draft.pptx
Introduction to AI in Higher Education_draft.pptxpboyjonauth
 
“Oh GOSH! Reflecting on Hackteria's Collaborative Practices in a Global Do-It...
“Oh GOSH! Reflecting on Hackteria's Collaborative Practices in a Global Do-It...“Oh GOSH! Reflecting on Hackteria's Collaborative Practices in a Global Do-It...
“Oh GOSH! Reflecting on Hackteria's Collaborative Practices in a Global Do-It...Marc Dusseiller Dusjagr
 
APM Welcome, APM North West Network Conference, Synergies Across Sectors
APM Welcome, APM North West Network Conference, Synergies Across SectorsAPM Welcome, APM North West Network Conference, Synergies Across Sectors
APM Welcome, APM North West Network Conference, Synergies Across SectorsAssociation for Project Management
 
BASLIQ CURRENT LOOKBOOK LOOKBOOK(1) (1).pdf
BASLIQ CURRENT LOOKBOOK LOOKBOOK(1) (1).pdfBASLIQ CURRENT LOOKBOOK LOOKBOOK(1) (1).pdf
BASLIQ CURRENT LOOKBOOK LOOKBOOK(1) (1).pdfSoniaTolstoy
 
Industrial Policy - 1948, 1956, 1973, 1977, 1980, 1991
Industrial Policy - 1948, 1956, 1973, 1977, 1980, 1991Industrial Policy - 1948, 1956, 1973, 1977, 1980, 1991
Industrial Policy - 1948, 1956, 1973, 1977, 1980, 1991RKavithamani
 
Call Girls in Dwarka Mor Delhi Contact Us 9654467111
Call Girls in Dwarka Mor Delhi Contact Us 9654467111Call Girls in Dwarka Mor Delhi Contact Us 9654467111
Call Girls in Dwarka Mor Delhi Contact Us 9654467111Sapana Sha
 
Measures of Central Tendency: Mean, Median and Mode
Measures of Central Tendency: Mean, Median and ModeMeasures of Central Tendency: Mean, Median and Mode
Measures of Central Tendency: Mean, Median and ModeThiyagu K
 
Mastering the Unannounced Regulatory Inspection
Mastering the Unannounced Regulatory InspectionMastering the Unannounced Regulatory Inspection
Mastering the Unannounced Regulatory InspectionSafetyChain Software
 
Accessible design: Minimum effort, maximum impact
Accessible design: Minimum effort, maximum impactAccessible design: Minimum effort, maximum impact
Accessible design: Minimum effort, maximum impactdawncurless
 
Arihant handbook biology for class 11 .pdf
Arihant handbook biology for class 11 .pdfArihant handbook biology for class 11 .pdf
Arihant handbook biology for class 11 .pdfchloefrazer622
 
How to Make a Pirate ship Primary Education.pptx
How to Make a Pirate ship Primary Education.pptxHow to Make a Pirate ship Primary Education.pptx
How to Make a Pirate ship Primary Education.pptxmanuelaromero2013
 
Sanyam Choudhary Chemistry practical.pdf
Sanyam Choudhary Chemistry practical.pdfSanyam Choudhary Chemistry practical.pdf
Sanyam Choudhary Chemistry practical.pdfsanyamsingh5019
 

Último (20)

Separation of Lanthanides/ Lanthanides and Actinides
Separation of Lanthanides/ Lanthanides and ActinidesSeparation of Lanthanides/ Lanthanides and Actinides
Separation of Lanthanides/ Lanthanides and Actinides
 
MENTAL STATUS EXAMINATION format.docx
MENTAL STATUS EXAMINATION format.docxMENTAL STATUS EXAMINATION format.docx
MENTAL STATUS EXAMINATION format.docx
 
Crayon Activity Handout For the Crayon A
Crayon Activity Handout For the Crayon ACrayon Activity Handout For the Crayon A
Crayon Activity Handout For the Crayon A
 
Q4-W6-Restating Informational Text Grade 3
Q4-W6-Restating Informational Text Grade 3Q4-W6-Restating Informational Text Grade 3
Q4-W6-Restating Informational Text Grade 3
 
Paris 2024 Olympic Geographies - an activity
Paris 2024 Olympic Geographies - an activityParis 2024 Olympic Geographies - an activity
Paris 2024 Olympic Geographies - an activity
 
Kisan Call Centre - To harness potential of ICT in Agriculture by answer farm...
Kisan Call Centre - To harness potential of ICT in Agriculture by answer farm...Kisan Call Centre - To harness potential of ICT in Agriculture by answer farm...
Kisan Call Centre - To harness potential of ICT in Agriculture by answer farm...
 
Introduction to AI in Higher Education_draft.pptx
Introduction to AI in Higher Education_draft.pptxIntroduction to AI in Higher Education_draft.pptx
Introduction to AI in Higher Education_draft.pptx
 
“Oh GOSH! Reflecting on Hackteria's Collaborative Practices in a Global Do-It...
“Oh GOSH! Reflecting on Hackteria's Collaborative Practices in a Global Do-It...“Oh GOSH! Reflecting on Hackteria's Collaborative Practices in a Global Do-It...
“Oh GOSH! Reflecting on Hackteria's Collaborative Practices in a Global Do-It...
 
APM Welcome, APM North West Network Conference, Synergies Across Sectors
APM Welcome, APM North West Network Conference, Synergies Across SectorsAPM Welcome, APM North West Network Conference, Synergies Across Sectors
APM Welcome, APM North West Network Conference, Synergies Across Sectors
 
Código Creativo y Arte de Software | Unidad 1
Código Creativo y Arte de Software | Unidad 1Código Creativo y Arte de Software | Unidad 1
Código Creativo y Arte de Software | Unidad 1
 
BASLIQ CURRENT LOOKBOOK LOOKBOOK(1) (1).pdf
BASLIQ CURRENT LOOKBOOK LOOKBOOK(1) (1).pdfBASLIQ CURRENT LOOKBOOK LOOKBOOK(1) (1).pdf
BASLIQ CURRENT LOOKBOOK LOOKBOOK(1) (1).pdf
 
Industrial Policy - 1948, 1956, 1973, 1977, 1980, 1991
Industrial Policy - 1948, 1956, 1973, 1977, 1980, 1991Industrial Policy - 1948, 1956, 1973, 1977, 1980, 1991
Industrial Policy - 1948, 1956, 1973, 1977, 1980, 1991
 
Call Girls in Dwarka Mor Delhi Contact Us 9654467111
Call Girls in Dwarka Mor Delhi Contact Us 9654467111Call Girls in Dwarka Mor Delhi Contact Us 9654467111
Call Girls in Dwarka Mor Delhi Contact Us 9654467111
 
Measures of Central Tendency: Mean, Median and Mode
Measures of Central Tendency: Mean, Median and ModeMeasures of Central Tendency: Mean, Median and Mode
Measures of Central Tendency: Mean, Median and Mode
 
Mastering the Unannounced Regulatory Inspection
Mastering the Unannounced Regulatory InspectionMastering the Unannounced Regulatory Inspection
Mastering the Unannounced Regulatory Inspection
 
Accessible design: Minimum effort, maximum impact
Accessible design: Minimum effort, maximum impactAccessible design: Minimum effort, maximum impact
Accessible design: Minimum effort, maximum impact
 
Arihant handbook biology for class 11 .pdf
Arihant handbook biology for class 11 .pdfArihant handbook biology for class 11 .pdf
Arihant handbook biology for class 11 .pdf
 
How to Make a Pirate ship Primary Education.pptx
How to Make a Pirate ship Primary Education.pptxHow to Make a Pirate ship Primary Education.pptx
How to Make a Pirate ship Primary Education.pptx
 
Model Call Girl in Bikash Puri Delhi reach out to us at 🔝9953056974🔝
Model Call Girl in Bikash Puri Delhi reach out to us at 🔝9953056974🔝Model Call Girl in Bikash Puri Delhi reach out to us at 🔝9953056974🔝
Model Call Girl in Bikash Puri Delhi reach out to us at 🔝9953056974🔝
 
Sanyam Choudhary Chemistry practical.pdf
Sanyam Choudhary Chemistry practical.pdfSanyam Choudhary Chemistry practical.pdf
Sanyam Choudhary Chemistry practical.pdf
 

Pharmacology of peripheral nervous system

  • 1. PHARMACOLOGY OF PERIPHERAL NERVOUS SYSTEM SATYAJIT GHOSH B. PHARM 4TH SEMESTER
  • 2. Autonomic Nervous System: General Consideration  Organisation and Function OF ANS: The ANS consists following nerve fibre: -  Sensory Information: Afferent Fibers and Reflex Arcs: - i. Afferent fibers from visceral structures are the first link in the reflex arcs of the autonomic system. With certain exceptions, such as local axon reflexes, most visceral reflexes are mediated through the CNS. ii. Visceral Afferent Fibers:  Information on the status of the visceral organs is transmitted to the CNS through two main sensory systems: a- the cranial nerve (parasympathetic) visceral sensory system b- the spinal (sympathetic) visceral afferent system.  The cranial visceral sensory system carries mainly mechanoreceptor and chemosensory information, whereas the afferents of the spinal visceral system principally convey sensations related to temperature and tissue injury of mechanical, chemical, or thermal origin.  Cranial visceral sensory information enters the CNS by four cranial nerves: the trigeminal (V), facial (VII), glossopharyngeal (IX), and vagus(X) nerves.  These four cranial nerves transmit visceral sensory information from the internal face and head (V); tongue (taste, VII); hard palate and upper part of the oropharynx (IX); and carotid body, lower part of the oropharynx, larynx, trachea, esophagus, and thoracic and abdominal organs (X), with the exception of the pelvic viscera. The visceral afferents from these four cranial nerves terminate topographically in the STN.
  • 3.  Sensory afferents from visceral organs also enter the CNS from the spinal nerves. Those concerned with muscle chemo sensation may arise at all spinal levels, whereas sympathetic visceral sensory afferents generally arise at the thoracic levels where sympathetic preganglionic neurons are found.  In general, visceral afferents that enter the spinal nerves convey information concerned with temperature as well as nociceptive visceral inputs related to mechanical, chemical, and thermal stimulation.  Substance P and CGRP, present in afferent sensory fibers, dorsal root ganglia, and the dorsal horn of the spinal cord, communicate nociceptive stimuli from the periphery to the spinal cord and higher structures.  Central autonomic connections: i. There are no purely autonomic or somatic centres of integration, and extensive overlap occurs. Somatic responses always are accompanied by visceral responses and vice versa. ii. Autonomic reflexes can be elicited at the level of the spinal cord. The hypothalamus and the solitary tract nucleus (STN) generally are regarded as principal loci of integration of autonomic nervous system functions, which include regulation of body temperature, water balance, carbohydrate and fat metabolism, blood pressure, emotions, sleep, respiration, and reproduction. Signals are received through ascending spinobulbar pathways, the limbic system, neostriatum, cortex, and toa lesser extent other higher brain centers. iii. Stimulation of the STN and the hypothalamus activates bulbospinal pathways and hormonal output to mediate autonomic and motor responses. The hypothalamic nuclei that lie posteriorly and laterally are sympathetic in their main connections, whereas parasympathetic functions evidently are integrated by the midline nuclei in the region of the tuber cinereum and by nuclei lying anteriorly.
  • 4.  Autonomic efferent: i. The output part of ANS has two divisions: the sympathetic division and the parasympathetic division. Most organ have dual innervation, i.e., they receive impulses from both sympathetic and parasympathetic division and the two divisions are functionally antagonistic. ii. The level of activity of innervated organ at a given moment is the algebraic sum of sympathetic and parasympathetic tone. iii. The sympathetic division is also known as fight – flight division. Sympathetic activity results in increased alertness and metabolic activities in order to prepare the body for an emergency situation. iv. The parasympathetic division is also known as rest – and – digest division because its activities conserve and restore body energy during time of rest or digesting a meal. v. Each division of ANS has two motor neurons 1- Preganglionic Neuron: It is the first motor neuron in any autonomic motor pathway. Its cell body is present in the brain or spinal cord; its axon exits the CNS as part of cranial or spinal nerve. The preganglionic neuron is a myelinated type B fibre extend to the autonomic ganglion, where it synapses with a post ganglionic neuron. 2- Postganglionic neuron: It is the second neuron of the autonomic motor pathway. Its cell body and dendrites are located in an autonomic ganglion, where it forms synapses with one or more presynaptic ganglion. The axon of post synaptic neuron is an unmyelinated type C fibre. that terminate in the visceral effector.  Divisions of the Peripheral Autonomic System: -  On the efferent side, the autonomic nervous system consists of two large divisions: a- the sympathetic or thoracolumbar outflow
  • 5. b- the parasympathetic or craniosacral outflow.  The neurotransmitter of all preganglionic autonomic fibers, most postganglionic parasympathetic fibers, and a few postganglionic sympathetic fibers is ACh. Some postganglionic parasympathetic nerves use NO as a neurotransmitter and are termed nitrergic.  The majority of the postganglionic sympathetic fibers are adrenergic, in which the transmitter is NE. The terms cholinergic and adrenergic describe neurons that liberate ACh or NE, respectively.  Sympathetic Nervous System: - i. The cells that give rise to the preganglionic fibers of the sympathetic nervous system division lie mainly in the intermediolateral columns of the spinal cord and extend from the first thoracic to the second or third lumbar segment. ii. The axons from these cells are carried in the anterior (ventral) nerve roots and synapse, with neurons lying in sympathetic ganglia outside the cerebrospinal axis. iii. Sympathetic ganglia are found in three locations: paravertebral, prevertebral, and terminal. The 22 pairs of paravertebral sympathetic ganglia form the lateral chains on either side of the vertebral column. iv. The ganglia are connected to each other by nerve trunks and to the spinal nerves by rami communicantes. The white rami carry the preganglionic myelinated fibers that exit the spinal cord by the anterior spinal roots. The gray rami arise from the ganglia and carry postganglionic fibers back to the spinal nerves for distribution to sweat glands and pilomotor muscles and to blood vessels of skeletal muscle and skin. v. The prevertebral ganglia lie in the abdomen and the pelvis near the ventral surface of the bony vertebral column and consist mainly of the celiac (solar), superior mesenteric, aorticorenal, and inferior mesenteric ganglia. vi. The terminal ganglia are few in number, lie near the organs they innervate, and include ganglia connected with the urinary bladder, rectum and the cervical ganglia in the region of the neck.
  • 6. vii. Preganglionic fibers issuing from the spinal cord may synapse with the neurons of more than one sympathetic ganglion. Many of the preganglionic fibers from the fifth to the last thoracic segment pass through the paravertebral ganglia to form the splanchnic nerves. Most of the splanchnic nerve fibers do not synapse until they reach the celiac ganglion; others directly innervate the adrenal medulla. viii. Postganglionic fibers arising from sympathetic ganglia innervate visceral structures of the thorax, abdomen, head, and neck. The trunk and the limbs are supplied by the sympathetic fibers in spinal nerves. ix. The prevertebral ganglia contain cell bodies whose axons innervate the glands and smooth muscles of the abdominal and the pelvic viscera. x. Many of the upper thoracic sympathetic fibers from the vertebral ganglia form terminal plexuses, such as the cardiac, oesophageal, and pulmonary plexuses. The sympathetic distribution to the head and the neck (vasomotor, pupillodilator, secretory, and pilomotor) is by means of the cervical sympathetic chain and its three ganglia. xi. All postganglionic fibers in this chain arise from cell bodies located in these three ganglia.  Parasympathetic Nervous System: - i. The parasympathetic nervous system consists of preganglionic fibers that originate in the CNS and their postganglionic connections. The regions of central origin are the midbrain, the medulla oblongata, and the sacral part of the spinal cord. ii. The midbrain, or tectal, outflow consists of fibers arising from the Edinger-Westphal nucleus of the third cranial nerve and going to the ciliary ganglion in the orbit. iii. The medullary outflow consists of the parasympathetic components of the VII, IX, and X cranial nerves. The fibers in the VII (facial) cranial nerve form the chorda tympani, which innervates the ganglia lying on the submaxillary and sublingual glands. They also form the greater superficial petrosal nerve, which innervates the sphenopalatine ganglion.
  • 7. iv. The autonomic components of the IX (glossopharyngeal) cranial nerve innervate the otic ganglia. Postganglionic parasympathetic fibers from these ganglia supply the sphincter of the iris (pupillary constrictor muscle), the ciliary muscle, the salivary and lacrimal glands, and the mucous glands of the nose, mouth, and pharynx. These fibers also include vasodilator nerves to these same organs. v. Cranial nerve X (vagus) arises in the medulla and contains preganglionic fibers, most of which do not synapse until they reach the many small ganglia lying directly on or in the viscera of the thorax and abdomen. In the intestinal wall, the vagal fibers terminate around ganglion cells in the myenteric and submucosal plexuses. vi. Thus, in the parasympathetic branch of the autonomic nervous system, preganglionic fibers are very long, whereas postganglionic fibers are very short. vii. The parasympathetic sacral outflow consists of axons that arise from cells in the second, third, and fourth segments of the sacral cord and proceed as preganglionic fibers to form the pelvic nerves (nervi erigentes). They synapse in terminal ganglia lying near or within the bladder, rectum, and sexual organs. The vagal and sacral outflows provide motor and secretory fibers to thoracic, abdominal, and pelvic organs.  Enteric Nervous System: - i. The processes of mixing, propulsion, and absorption of nutrients in the GI tract are controlled locally through a restricted part of the peripheral nervous system called the ENS. ii. The ENS comprises components of the sympathetic and parasympathetic nervous systems and has sensory nerve connections through the spinal and nodose ganglia. iii. The ENS is involved in sensorimotor control and thus consists of both afferent sensory neurons and a number of motor nerves and interneurons that are organized principally into two nerve plexuses: the myenteric (Auerbach) plexus and the submucosal (Meissner) plexus. iv. The myenteric plexus, located between the longitudinal and circular muscle layers, plays an important role in the contraction and relaxation of GI smooth muscle.
  • 8. v. The submucosal plexus is involved with secretory and absorptive functions of the GI epithelium, local blood flow, and neuroimmune activities. vi. Parasympathetic preganglionic inputs are provided to the GI tract via the vagus and pelvic nerves. ACh released from preganglionic neurons activates nAChRs on postganglionic neurons within the enteric ganglia. vii. Excitatory preganglionic input activates both excitatory and inhibitory motor neurons that control processes such as muscle contraction and secretion/absorption. viii. Postganglionic sympathetic nerves also synapse with intrinsic neurons and generally induce relaxation. Sympathetic input is excitatory (contractile) at some sphincters. Information from afferent and preganglionic neural inputs to the enteric ganglia is integrated and distributed by a network of interneurons.
  • 9.
  • 10.
  • 11. Comparison of the Somatic and Autonomic Nervous System Somatic Nervous System Autonomic Nervous System Sensory input From somatic senses and special senses Mainly from interoceptors; some from somatic senses and special senses. Control of motor output Voluntary control from cerebral cortex, with contributions from basal ganglia, cerebellum, brain stem, and spinal cord. Involuntary control from hypothalamus, limbic system, brain stem, and spinal cord; limited control from cerebral cortex. Motor neuron pathway One-neuron pathway: Somatic motor neurons extending from CNS synapse directly with effector. Usually two-neuron pathway: Preganglionic neurons extending from CNS, synapse with postganglionic neurons in autonomic ganglion, and postganglionic neurons extending from ganglion synapse with visceral effector. Alternatively, preganglionic neurons may extend from CNS to synapse with chromaffin cells of adrenal medullae. Neurotransmitters and hormones All somatic motor neurons release only acetylcholine (ACh). All sympathetic and parasympathetic preganglionic neurons release ACh. Most sympathetic postganglionic neurons release NE; those to most sweat glands release ACh. All parasympathetic postganglionic neurons release ACh. Chromaffin cells of adrenal medullae release epinephrine and norepinephrine. Effectors Skeletal muscle Smooth muscle, cardiac muscle, and glands. Responses. Contraction of skeletal muscle Contraction or relaxation of smooth muscle; increased or decreased rate and force of contraction of cardiac muscle; increased or decreased secretions of glands.
  • 12. Comparison of Sympathetic and Parasympathetic Division Sympathetic (Thoracolumbar) Parasympathetic (Craniosacral) Distribution Wide regions of body: skin, sweat glands, arrector pili muscles of hair follicles, adipose tissue, smooth muscle of blood vessels. Limited mainly to head and to viscera of thorax, abdomen, and pelvis; some blood vessels. Location of preganglionic neuron cell bodies and site of outflow Lateral gray horns of spinal cord segments T1–L2. Axons of preganglionic neurons constitute thoracolumbar outflow. Nuclei of cranial nerves III, VII, IX, and X and lateral gray matter of spinal cord segments S2–S4. Axons of preganglionic neurons constitute craniosacral outflow. Associated ganglia Sympathetic trunk ganglia and prevertebral ganglia Terminal ganglia Ganglia locations Close to CNS and distant from visceral effectors Typically, near or within wall of visceral effectors. Axon length and divergence Preganglionic neurons with short axons synapse with many postganglionic neurons with long axons that pass to many visceral effectors. Preganglionic neurons with long axons usually synapse with four to five postganglionic neurons with short axons that pass to single visceral effector. White and gray rami communicantes Both present; white rami communicantes contain myelinated preganglionic axons; gray rami communicantes contain unmyelinated postganglionic axons. Neither present Neurotransmitters Preganglionic neurons release acetylcholine (ACh), which is excitatory and stimulates postganglionic neurons; most postganglionic neurons release norepinephrine (NE); postganglionic neurons that innervate most sweat glands and some blood vessels in skeletal muscle release ACh. Preganglionic neurons release ACh, which is excitatory and stimulates postganglionic neurons; postganglionic neurons release ACh. Physiological effects Fight-or-flight responses Rest-and-digest activities
  • 13. EFFECT OF SYMPATHETIC AND PARASYMPATHETIC DIVISION OF ANS Visceral Effector Effect of Sympathetic stimulation (α, β – Adrenergic Receptor) Effect of Parasympathetic Stimulation (Muscarinic ACh receptor) GLANDS Adrenal medullae Secretion of epinephrine and norepinephrine (nicotinic ACh receptors). No Innervation Lacrimal (tear) Slight secretion of tears (α). Secretion of tear Pancreas Inhibits secretion of digestive enzymes and the hormone insulin (α2) Promotes secretion of the hormone glucagon (β2) Secretion of digestive enzymes and the hormone insulin. Posterior pituitary Secretion of ADH (β1) No innervation. Pineal Increases synthesis and release of melatonin (β) No innervation. Sweat Increases sweating in most body regions (muscarinic ACh receptors) Sweating on palms and soles (α1) No innervation Adipose tissue Lipolysis (β1) Release of fatty acids into blood (β1 and β3) No innervation Liver Glycogenolysis Gluconeogenesis Decreased bile secretion (α and β2) Glycogen synthesis Increased bile secretion Kidney, Juxtaglomerular Cell Secretion of renin (β1) No innervation HEART Cardiac Muscle Increased Ionotropic Action Increased Chronotropic Action Increased Dromotropic Action Increased Heart Rate, C.O, B.P (β1) Decreased Ionotropic Action Decreased Chronotropic Action Decreased Dromotropic Action Decreased Heart Rate, C.O, B.P (M2) SMOOTH MUSCLE Iris, radial muscle Contraction → dilation of pupil (α1) No innervation Iris, circular muscle No innervation Contraction → constriction of pupil Ciliary muscle of eye Relaxation to adjust shape of lens for distant vision (β2). Contraction for close vision Lungs, bronchial muscle Relaxation → airway dilation (β2), Decreases bronchial mucus secretion Contraction → airway constriction, Increases bronchial mucus secretion
  • 14. Gallbladder and ducts Relaxation to facilitate storage of bile in the gallbladder (β2). Contraction → release of bile into small intestine Stomach and intestine Decreased motility and tone (α1, α2, β2), Contraction of sphincters (α1) Decreased Peristalsis Increased motility and tone Relaxation of sphincters Increased Peristalsis Spleen Contraction and discharge of stored blood into general circulation (α1). No innervation Ureter Increases motility (α1). Increases motility (?). Urinary bladder Relaxation of muscular wall (β2) Contraction of internal urethral sphincter (α1). Contraction of muscular wall Relaxation of internal urethral sphincter Uterus Inhibits contraction in nonpregnant women (β2); Promotes contraction in pregnant women (α1). Minimal effect Sex organs In males: contraction of smooth muscle of vas deferens, prostate, and seminal vesicle resulting in ejaculation (α1). Vasodilation; erection of clitoris (females) and penis (males). Hair follicles, arrector pili muscle Contraction → erection of hairs resulting in goose bumps (α1) No innervation VASCULAR SMOOTH MUSCLE Salivary gland arterioles Vasoconstriction, which decreases secretion of saliva (α1) Vasodilation → Increases secretion of saliva Gastric gland arterioles Vasoconstriction, which inhibits secretion (α1) Secretion of Gastric juice Intestinal gland arterioles Vasoconstriction, which inhibits secretion (α1) Secretion of Intestinal juice Coronary (heart) arterioles Relaxation → vasodilation (β2) contraction → vasoconstriction (α1, α2) contraction → vasoconstriction (muscarinic Ach receptors) Contraction → Vasoconstriction Skin and mucosal arterioles Contraction → vasoconstriction (α1) Vasodilation Skeletal muscle arterioles Contraction → vasoconstriction (α1) relaxation → vasodilation (β2) relaxation → vasodilation (muscarinic ACh receptors) No Innervation Abdominal viscera arterioles Contraction → vasoconstriction (α1, β2) No Innervation Brain arterioles Slight contraction → vasoconstriction (α1) No Innervation Kidney arterioles Constriction of blood vessels → decreased urine volume (α1) No Innervation Systemic veins Contraction → Constriction (α1) Relaxation → Dilation (β2) No Innervation
  • 15.  Neurohumoral Transmission: - I. Neurohumoral transmission refers to the transmission of impulse through synapse and neuro – effector junction by release of humoral or chemical substance. II. Neurohumoral transmitter a substance must fulfil the following criteria: 1. It should be present in the presynaptic neurone (usually along with enzymes synthesizing it). 2. It should be released in the medium following nerve stimulation. 3. Its application should produce responses identical to those produced by nerve stimulation. 4. Its effects should be antagonized or potentiated by other substances which similarly alter effects of nerve stimulation.  Steps in Neurohumoral Transmission: -  Axonal Conduction: - 1. Conduction refers to the passage of an electrical impulse along an axon or muscle fiber. At rest, the interior of axon is about 70 mV negative to the exterior. 2. In response to depolarization to a threshold level, an action potential is initiated at a local region of the membrane. The action potential consists of two phases. a- The initial phase is caused by a rapid increase in the permeability and inward movement of Na+ through voltage-sensitive Na+ channels, and a rapid depolarization from the resting potential continues to a positive overshoot. b- The second phase results from the rapid inactivation of the Na+ channel and the delayed opening of a K+ channel, which permits outward movement of K+ to terminate the depolarization. 3. The transmembrane ionic currents produce local circuit currents such that adjacent resting channels in the axon are activated, and excitation of an adjacent portion of the axonal membrane occurs, leading to propagation of the action potential without decrement along the axon.
  • 16. 4. The region that has undergone depolarization remains momentarily in a refractory state. With the exception of the local anaesthetics, few drugs modify axonal conduction in the doses employed therapeutically. 5. The puffer fish poison, tetrodotoxin, and a close congener found in some shellfish, saxitoxin, selectively block axonal conduction by blocking the voltage-sensitive Na+ channel and preventing the increase in Na+ permeability associated with the rising phase of the action potential. 6. In contrast, batrachotoxin, an extremely potent steroidal alkaloid secreted by a South American frog, produces paralysis through a selective increase in permeability of the Na+ channel, which induces a persistent depolarization. 7. Scorpion toxins are peptides that also cause persistent depolarization by inhibiting the inactivation process.  Junctional Transmission: - The term transmission refers to the passage of an impulse across a synaptic or neuroeffector junction. The arrival of the action potential at the axonal terminals initiates a series of events that trigger transmission of an excitatory or inhibitory biochemical message across the synapse or neuroeffector junction. These events are the following: 1. Storage and release of transmitter: -  The nonpeptide (small-molecule) neurotransmitters, such as biogenic amines, are largely synthesized in the region of the axonal terminals and stored there in synaptic vesicles.  Neurotransmitter transport into storage vesicles is driven by an electrochemical gradient generated by the vesicular proton pump (vesicular ATPase).  Synaptic vesicles cluster in discrete areas underlying the presynaptic plasma membrane, termed active zones. Proteins in the vesicular membrane (e.g., synapsin, synaptophysin, synaptogyrin) are involved in development and trafficking of the storage vesicle to the active zone.
  • 17.  The processes of priming, docking, fusion, and exocytosis involve the interactions of proteins in the vesicles and plasma membranes and the rapid entry of extracellular Ca2+ and its binding to synaptotagmins. Life Cycle of a Storage Vesicle, Molecular Mechanism of Exocytosis: -  Fusion of the storage vesicle and plasma membrane involves formation of a multiprotein complex that includes proteins in the membrane of the synaptic vesicle, proteins embedded in the inner surface of the plasma membrane, and several cytosolic components.  These proteins are referred to as SNARE proteins. Through the assembly of these proteins, vesicles draw near the membrane (priming, docking), spatially prepared for the next step, which the entry of Ca2+ initiates.  When Ca2+ enters with the action potential, fusion and exocytosis occur rapidly. After fusion, the chaperone ATPase N-ethylmaleamide sensitive factor (NSF) and its soluble NSF attachment protein, synaptosome-associated Protein (SNAP) adapters catalyse dissociation of the SNARE complex.
  • 18.  During the resting state, there is continual slow release of isolated quanta of the transmitter; this produces electrical responses (miniature end-plate potentials or mepps) at the postjunctional membrane that are associated with the maintenance of the physiological responsiveness of the effector organ.  The action potential causes the synchronous release of several hundred quanta of neurotransmitter. In the exocytosis process, the contents of the vesicles, including enzymes and other proteins, are discharged to the synaptic space.  Synaptic vesicles may either fully exocytose with complete fusion or form a transient, nanometer-size pore that closes after transmitter has escaped, “kiss-and-run” exocytosis.  In full-fusion exocytosis, the pit formed by the vesicle’s fusing with the plasma membrane is clathrin-coated and retrieved from the membrane via endocytosis and transported to an endosome for full recycling.  During kiss-and-run exocytosis, the pore closes, and the vesicle is immediately and locally recycled for reuse in neurotransmitter repackaging. Modulation of Transmitter Release: -  A number of autocrine and paracrine factors may influence the exocytotic process, including the released neurotransmitter itself.  Adenosine, DA, glutamate, GABA, prostaglandins, and enkephalins influence neurally mediated release of neurotransmitters. Receptors for these factors exist in the membranes of the soma, dendrites, and axons of neurons: A- Soma-dendritic receptors, when activated, primarily modify functions of the soma-dendritic region, such as protein synthesis and generation of action potentials. B- Presynaptic receptors, when activated, modify functions of the terminal region, such as synthesis and release of transmitters. Two main classes of presynaptic receptors have been identified on most neurons:
  • 19. a- Heteroreceptors are presynaptic receptors that respond to neurotransmitters, neuromodulators, or neurohormones released from adjacent neurons or cells. For example, NE can influence the release of ACh from parasympathetic neurons by acting on α2A, α2B, and α2C receptors, whereas ACh can influence the release of NE from sympathetic neurons by acting on M2 and M4 receptors. b- Autoreceptors are receptors located on axon terminals of a neuron through which the neuron’s own transmitter can modify transmitter synthesis and release. For example, NE released from sympathetic neurons may interact with α2A and α2C receptors to inhibit neurally released NE. Similarly, ACh released from parasympathetic neurons may interact with M2 and M4 receptors to inhibit neurally released ACh. 2. Interaction of the transmitter with postjunctional receptors and production of the postjunctional potential: -  The transmitter diffuses across the synaptic cleft and combines with specialized receptors on the postjunctional membrane; results in a localized increase in the ionic permeability, or conductance, of the membrane.  With certain exceptions, one of three types of permeability change can occur:  Generalized increase in the permeability to cations (notably Na+ but occasionally Ca2+ ), resulting in a localized depolarization of the membrane, that is, an EPSP.  Selective increase in permeability to anions, usually Cl– , resulting in stabilization or actual hyperpolarization of the membrane, which constitutes an IPSP.  Increased permeability to K+ . Because the K+ gradient is directed out of the cell, hyperpolarization and stabilization of the membrane potential occur (an IPSP).
  • 20.  Electric potential changes associated with the EPSP and IPSP at most sites are the results of passive fluxes of ions down their concentration gradients. The changes in channel permeability that cause these potential changes are specifically regulated by the specialized postjunctional receptors for the neurotransmitter that initiates the response.  These receptors may be clustered on the effector cell surface, as seen at the NMJs of skeletal muscle and other discrete synapses, or distributed more uniformly, as observed in smooth muscle. These high-conductance, ligand-gated ion channels usually permit passage of Na+ or Cl– ; K+ and Ca2+ are involved less frequently.  In the presence of an appropriate neurotransmitter, the channel opens rapidly to a high-conductance state, remains open for about a millisecond, and then closes. A short square-wave pulse of current is observed as a result of the channel’s opening and closing. The summation of these events gives rise to the EPSP.  The ligand-gated channels belong to a superfamily of ionotropic receptor proteins that includes the nicotinic, glutamate, and certain 5HT3 and purine receptors, which conduct primarily Na+ , cause depolarization, and are excitatory; and GABA acid and glycine receptors, which conduct Cl– , cause hyperpolarization, and are inhibitory.  Neurotransmitters also can modulate the permeability of K+ and Ca2+ channels indirectly. In these cases, the receptor and channel are separate proteins, and information is conveyed between them by G proteins. 3. Initiation of postjunctional activity: -  If an EPSP exceeds a certain threshold value, it initiates a propagated action potential in a postsynaptic neuron or a muscle action potential in skeletal or cardiac muscle by activating voltage-sensitive channels in the immediate vicinity.  In certain smooth muscle types in which propagated impulses are minimal, an EPSP may increase the rate of spontaneous depolarization, cause Ca2+ release, and enhance muscle tone; in gland cells, the EPSP initiates secretion through Ca2+ mobilization.  An IPSP, which is found in neurons and smooth muscle but not in skeletal muscle, will oppose excitatory potentials.
  • 21. 4. Destruction or dissipation of the transmitter: -  When impulses can be transmitted across junctions at frequencies up to several hundred per second, there must be an efficient means of disposing of the transmitter following each impulse.  At cholinergic synapses involved in rapid neurotransmission, high and localized concentrations of AChE are available for this purpose. When AChE activity is inhibited, removal of the transmitter is accomplished principally by diffusion. Under these circumstances, the effects of released ACh are potentiated and prolonged.  Rapid termination of NE occurs by a combination of simple diffusion and reuptake by the axonal terminals of most of the released NE. Termination of the action of amino acid transmitters results from their active transport into neurons and surrounding glia. Peptide neurotransmitters are hydrolysed by various peptidases and dissipated by diffusion.  Cotransmission: i. Cotransmission is defined as control of a single target cell by two or more substances released from one neuron in response to the same neuronal event. ii. In the ANS besides the primary transmitters like ACh and NA, neurones also release purines (ATP, adenosine), peptides (vasoactive intestinal peptide (VIP), neuropeptide-Y (NPY), substance P, enkephalins, somatostatin, etc.), nitric oxide and prostaglandins as cotransmitters. iii. In most autonomic cholinergic neurons’ VIP is associated with ACh, while ATP is associated with both ACh and NA. The transmitter at some parasympathetic sites is N0. and these are called nitrergic nerves. iv. Vascular adrenergic nerves contain NPY which causes long lasting vasoconstriction. v. The cotransmitter is stored in the same neurone but in distinct synaptic vesicles or locations. However, ATP is stored with NA in the same vesicle. On being released by nerve impulse the cotransmitter may serve to regulate the presynaptic release of the primary transmitter and/or postsynaptic sensitivity to it (neuromodulator role).
  • 22. vi. The time-course of action of the primary transmitter and the cotransmitter is usually different. The cotransmitter VIP of parasympathetic neurones produces a slow and long-lasting response, while another one (NO) has an intermediate time-course of action between VIP and ACh (fast acting). Similarly, in sympathetic neurones, the cotransmitter PY is slower acting and ATP faster ac ting than NA.