Upload
diata
View
30
Download
0
Tags:
Embed Size (px)
DESCRIPTION
Chapter 13. Peripheral Nervous System. PNS – the link to the outside world. White matter transmitted impulses to and from the brain PNS includes all neural structures outside the brain and spinal cord: Sensory receptors Peripheral nerves Ganglia Motor endings - PowerPoint PPT Presentation
Citation preview
Chapter 13
Peripheral Nervous System
PNS – the link to the outside world • White matter transmitted impulses to and from
the brain• PNS includes all neural structures outside the
brain and spinal cord:– Sensory receptors– Peripheral nerves– Ganglia– Motor endings
• Also includes: Somatic NS, ANS (sympathetic & parasympathetic)
Sensory Receptors & Sensation
• Stimuli from environment results in graded (local) potentials that in turn trigger nerve impulses along afferent PNS fibers
• In the brain, sensation (awareness) and perception (interpretation of the “meaning” of the stimulus)
• Classify sensory receptors by: 1) type of stimulus detected, 2) body location, & 3) their structural complexity
Classification by Stimulus Type
1)Mechanoreceptors – deform w/ mechanical forces: touch, pressure, vibration, stretch, itch
2)Thermoreceptors – Tpo changes3)Photoreceptors – retina in the eye4)Chemoreceptors – chemicals of taste 7 smell5)Nociceptors – respond to stimuli that result in
pain, which can be any sensory receptor if overstimulated
Classification by Location• Exteroceptors – stimuli arise outside the body, so
receptors are close to the surface: touch, pressure, pain and Tpo plus special senses vision, hearing, equilibrium, taste, smell
• Interoceptors – aka visceroceptors from organs and BV’s, monitor chemical change, stretch, Tpo
and we feel discomfort, hunger or thirst• Proprioceptors – in skeletal m., tendons, joints, &
ligaments, which advise the brain of our positions in space and our movements
Classification by Structural Complexity
• Simple or complex – latter are generally special sense organs for vision, taste, hearing, smell and equilibrium. Simple are receptors of general senses:
A) Free Nerve Endings – “naked”1) Naked – everywhere (epithelium, CT), C-fibers, pain, Tpo
2) Merkel (tactile) disc – epidermis for light touch3) Hair follicle receptors – detect bending hair or are light
touch detecting mosquitoes – “itch receptor”
B) Encapsulated Dendritic Endings - most are mechano-receptors w/ >1 terminals of sensory nerves in CT
Encapsulated - Cont.
1) Meissner’s corpuscle in dermal papillae of sensitive skin (nipples, fingertips, soles/palms) – light touch analogous to hair follicle in hairless skin
2) Pacinian corpuscle in deep dermis & sub-Q, respond to deep pressure but only at first stimulus, so their value is in vibration detection. Largest receptor
3) Ruffini corpuscle in dermis, sub-Q, & joint capsules, with a “spray” of receptor endings responding to deep & continuous pressure
4) Muscle spindles – proprioceptors of skeletal m.peri-mysium – modified muscle fibers called intrafusal fibers in CT – stretch receptor that initiates a reflex stop
Encapsulated - Cont.
5) Golgi tendon organs – proprioceptors in tendons where they join the muscle body – stimulated by muscle contraction and tendon stretch – activation of these causes muscle to relax (inhibited)
6) Joint kinesthetic receptors – proprioceptors that monitor stretch in synovial joint capsules – 4 of the categories contribute to this group:
Ruffini, Golgi Tendon, Pacinian, & Free (naked) all of which provide information on joint position
Simple Receptors: Unencapsulated
Table 13.1.1
Simple Receptors: Encapsulated
Table 13.1.2
From Sensation to Perception
• Survival depends upon sensation and perception
• Sensation is the awareness of changes in the internal and external environment
• Perception is the conscious interpretation of those stimuli
Organization of the Somatosensory System
• Input comes from exteroceptors, proprioceptors, and interoceptors
• The three main levels of neural integration in the somatosensory system are:– Receptor level – the sensor receptors– Circuit level – ascending pathways– Perceptual level – neuronal circuits in the
cerebral cortex
Somatosensory System Processing – 3 Levels
1) Receptor level – stimulus must:a) Have specificity i.e. mechano won’t respond to lightb) Be applied in receptor field – smaller field the better
able the brain can locate the stimulusc) Be converted to graded (receptor) potential that may be
excitatory or inhibitory. Those that summate to cause AP are called generator potentials that release NT
d) Generator potential must reach threshold to open Na+
gated channels on the axon to send impulse to CNS* Info about the stimulus: strength, duration, pattern is all in
the frequency of arriving impulses (faster = stronger)
Cont.
2) Tonic receptors just keep signaling at a steady rate (unless inhibited or activated), like the equilibrium receptors of the inner ear
3) Phasic receptors are “off” unless activated by some change in the environment and they just “report” changes in the internal or external
Hearing , smell and some other sensory receptors exhibit adaptation by being less sensitive as stimuli continue – phasic are fast, tonic are slow and pain & proprioception don’t at all
Processing at the Circuit Level
• Task is to deliver impulse to the appropriate cerebral cortex region to localize stimulus and for perception
• Uses 1st, 2nd, or 3rd order neurons to get info to thalamus, cerebellum and cerebral cortex
• Non-specific pathways – pain, Tpo, coarse touch so it is “general” info heavily tied to emotional aspect of perception (pleasure or pain)
• Specific pathways – info from discriminating aspect of touch, vibration, pressure, & conscious proprioception
Processing at the Perceptual Level
• Cortical areas receive AP’s regardless of whatever stimulates a receptor –projection to the usual area for that stimulus so it can be interpreted as a specific modality i.e. hearing, taste “Caller ID for the brain”– Perceptual detection – simplest, requires receptor summation– Magnitude estimation – how much stimulus (↑ frequency)– Spatial discrimination – ID site or pattern of stimulus two point
discrimination shows closeness – tactile receptor density– Feature abstraction – sensation from several stimulus properties
i.e. velvet feels warm, smooth, compressible – texture/shape ID– Quality discrimination – submodality, i.e. sour, sweet, bitter etc.– Pattern recognition – take in the scene & detect familiar (song)
Nerve structure – axon surrounded by endoneurium, w/ bundle (fascicle) surrounded by perinerurium, w/ all fascicles surrounded by the epineurium
PNS Nerves• Afferent – Efferent – Mixed (both fibers in most nerves)• Mixed nerves carry both somatic & autonomic (visceral)
nervous system fibers, therefore they are:• Classified as: somatic afferent or efferent, and visceral
afferent or efferent and are further classified as either cranial or spinal depending upon where they arise
• Ganglia – collections of neuron cell bodies of PNS nerves• Those associated with afferent nerve fibers are of sensory
neurons (dorsal root ganglia), while those of efferent fibers are cell bodies of autonomic motor neurons
Nerve Regeneration• Cut axons may regenerate, but NOT cell bodies• Cut axonal end seals itself and the end undergoes
Wallerian degeneration as axon and myelin sheath disintegrate and fragment the axon w/in a week, but the neurilemma (Schwann cell) remains intact w/in the endoneurium
• Schwann cells then migrate into the injury site and begin releasing growth factors and N-CAMS and that guide new axon through a regeneration tube at 1.5mm/day, but distance limits success and it never occurs naturally in the CNS
Regeneration of Nerve Fibers
Figure 13.4
Regeneration of Nerve Fibers
Figure 13.4
Cranial Nerves
• Twelve pairs of cranial nerves arise from the brain
• They have sensory, motor, or both sensory and motor functions
• Each nerve is identified by a number (I through XII) and a name
• Four cranial nerves carry parasympathetic fibers that serve muscles and glands
Summary of Function of Cranial Nerves
Figure 13.5b
Cranial Nerve I: Olfactory
• Arises from the olfactory epithelium
• Passes through the cribriform plate of the ethmoid bone
• Fibers run through the olfactory bulb and terminate in the primary olfactory cortex
• Functions solely by carrying afferent impulses for the sense of smell
Cranial Nerve I: Olfactory
Figure I from Table 13.2
Cranial Nerve II: Optic
• Arises from the retina of the eye• Optic nerves pass through the optic canals and
converge at the optic chiasm• They continue to the thalamus where they
synapse• From there, the optic radiation fibers run to the
visual cortex• Functions solely by carrying afferent impulses
for vision
Cranial Nerve II: Optic
Figure II from Table 13.2
Cranial Nerve III: Oculomotor
• Fibers extend from the ventral midbrain, pass through the superior orbital fissure, and go to the extrinsic eye muscles
• Functions in raising the eyelid, directing the eyeball, constricting (parasympathetic) the iris, and controlling lens shape
• Parasympathetic cell bodies are in the ciliary ganglia
Oculomotor Deficit
• Lack of pupillary response
• External strabismus – opposite of being “cross-eyed”
• Drooping eyelid - ptosis
Cranial Nerve III: Oculomotor
Figure III from Table 13.2
Cranial Nerve IV: Trochlear
• Fibers emerge from the dorsal midbrain and enter the orbits via the superior orbital fissures; innervate the superior oblique muscle
• Primarily a motor nerve that directs the eyeball
Cranial Nerve IV: Trochlear
Figure IV from Table 13.2
Cranial Nerve V: Trigeminal
• Three divisions: ophthalmic (V1), maxillary (V2), and mandibular (V3)
• Fibers run from the face to the pons via the superior orbital fissure (V1), the foramen rotundum (V2), and the foramen ovale (V3)
• Conveys sensory impulses from various areas of the face (V1) and (V2), and supplies motor fibers (V3) for mastication
Cranial Nerve V: Trigeminal
Figure V from Table 13.2
Cranial Nerve VI: Abdcuens
• Fibers leave the inferior pons and enter the orbit via the superior orbital fissure
• Primarily a motor nerve innervating the lateral rectus muscle
Figure VI from Table 13.2
Cranial Nerve VII: Facial• Fibers leave the pons, travel through the
internal acoustic meatus, and emerge through the stylomastoid foramen to the lateral aspect of the face
• Mixed nerve with five major branches• Motor functions include facial expression, and
the transmittal of autonomic impulses to lacrimal and salivary glands
• Sensory function is taste from the anterior two-thirds of the tongue
Bell’s Palsy
Xerophthalmia (“dry eye”)
Cranial Nerve VII: Facial
Figure VII from Table 13.2
Cranial Nerve VIII: Vestibulocochlear
• Fibers arise from the hearing and equilibrium apparatus of the inner ear, pass through the internal acoustic meatus, and enter the brainstem at the pons-medulla border
• Two divisions – cochlear (hearing) and vestibular (balance)
• Functions are solely sensory – equilibrium and hearing
Cranial Nerve VIII: Vestibulocochlear
Figure VIII from Table 13.2
Cranial Nerve IX: Glossopharyngeal• Fibers emerge from the medulla, leave the
skull via the jugular foramen, and run to the throat
• Nerve IX is a mixed nerve with motor and sensory functions
• Motor – innervates part of the tongue and pharynx, and provides motor fibers to the parotid salivary gland
• Sensory – fibers conduct taste and general sensory impulses from the tongue and pharynx
Cranial Nerve IX: Glossopharyngeal
Figure IX from Table 13.2
Cranial Nerve X: Vagus• The “vagabond” or “wanderer” nerve
• The only cranial nerve that extends beyond the head and neck
• Fibers emerge from the medulla via the jugular foramen
• The vagus is a mixed nerve
• Most motor fibers are parasympathetic fibers to the heart, lungs, and visceral organs
• Its sensory function is in taste
Cranial Nerve X: Vagus
Figure X from Table 13.2
Cranial Nerve XI: Accessory
• Formed from a cranial root emerging from the medulla and a spinal root arising from the superior region of the spinal cord
• The spinal root passes upward into the cranium via the foramen magnum
• The accessory nerve leaves the cranium via the jugular foramen
Cranial Nerve XI: Accessory
• Primarily a motor nerve – Supplies fibers to the larynx, pharynx, and soft
palate– Innervates the trapezius and
sternocleidomastoid, which move the head and neck
Cranial Nerve XI: Accessory
Figure XI from Table 13.2
Cranial Nerve XII: Hypoglossal
• Fibers arise from the medulla and exit the skull via the hypoglossal canal
• Innervates both extrinsic and intrinsic muscles of the tongue, which contribute to swallowing and speech
Cranial Nerve XII: Hypoglossal
Figure XII from Table 13.2
Spinal Nerves• Thirty-one pairs of mixed nerves arise from the
spinal cord and supply all parts of the body except the head
• They are named according to their point of issue– 8 cervical (C1-C8)– 12 thoracic (T1-T12)– 5 Lumbar (L1-L5)– 5 Sacral (S1-S5)– 1 Coccygeal (C0)
Spinal Nerves: Roots
• Each spinal nerve connects to the spinal cord via two medial roots
• Each root forms a series of rootlets that attach to the spinal cord
• Ventral roots arise from the anterior horn and contain motor (efferent) fibers
• Dorsal roots arise from sensory neurons in the dorsal root ganglion and contain sensory (afferent) fibers
Spinal Nerves: Rami
• The short spinal nerves branch into three or four mixed, distal rami– Small dorsal ramus– Larger ventral ramus– Tiny meningeal branch– Rami communicantes at the base of the ventral
rami in the thoracic region
Nerve Plexuses
• All ventral rami except T2-T12 form interlacing nerve networks called plexuses
• Plexuses are found in the cervical, brachial, lumbar, and sacral regions
• Each resulting branch of a plexus contains fibers from several spinal nerves
Nerve Plexuses
• Fibers travel to the periphery via several different routes
• Each muscle receives a nerve supply from more than one spinal nerve
• Damage to one spinal segment cannot completely paralyze a muscle
• The back is innervated by dorsal rami via several branches
• The thorax is innervated by ventral rami T1-T12 as intercostal nerves
• Intercostal nerves supply muscles of the ribs, anterolateral thorax, and abdominal wall
Spinal Nerve Innervation: Back, Anterolateral Thorax, and Abdominal Wall
Cervical Plexus
• The cervical plexus is formed by ventral rami of C1-C4
• Most branches are cutaneous nerves of the neck, ear, back of head, and shoulders
• The most important nerve of this plexus is the phrenic nerve
• The phrenic nerve is the major motor and sensory nerve of the diaphragm
Brachial Plexus
• Formed by C5-C8 and T1 (C4 and T2 may also contribute to this plexus)
• It gives rise to the nerves that innervate the upper limb
Brachial Plexus
• There are four major branches of this plexus – Roots – five ventral rami (C5-T1)
– Trunks – upper, middle, and lower, which form divisions
– Divisions – anterior and posterior serve the front and back of the limb
– Cords – lateral, medial, and posterior fiber bundles
Brachial Plexus
Figure 13.9a
Brachial Plexus: Nerves• Axillary – innervates the deltoid and teres minor• Musculocutaneous – sends fibers to the biceps
brachii and brachialis• Median – branches to most of the flexor muscles
of arm• Ulnar – supplies the flexor carpi ulnaris and part
of the flexor digitorum profundus• Radial – innervates essentially all extensor
muscles
Brachial Plexus: Distribution of Nerves
Figure 13.9c
Brachial Plexus: Nerves
Figure 13.9b
Lumbar Plexus
• Arises from L1-L4 and innervates the thigh, abdominal wall, and psoas muscle
• The major nerves are the femoral and the obturator
Sacral Plexus
• Arises from L4-S4 and serves the buttock, lower limb, pelvic structures, and the perineum
• The major nerve is the sciatic, the longest and thickest nerve of the body
• The sciatic is actually composed of two nerves: the tibial and the common fibular (peroneal) nerves
Dermatomes
• A dermatome is the area of skin innervated by the cutaneous branches of a single spinal nerve
• All spinal nerves except C1 participate in dermatomes
Innervation of Joints
• Hilton’s law: any nerve serving a muscle that produces movement at a joint also innervates the joint itself and the skin over the joint
Motor Endings
• PNS elements that activate effectors by releasing neurotransmitters at:– Neuromuscular junctions – Varicosities at smooth muscle and glands
Innervation of Skeletal Muscle
• Takes place at a neuromusclular junction
• Acetylcholine is the neurotransmitter that diffuses across the synaptic cleft
• ACh binds to receptors resulting in:– Movement of Na+ and K+ across the membrane– Depolarization of the interior of the muscle cell– An end-plate potential that triggers an action
potential
Innervation of Visceral Muscle and Glands
• Autonomic motor endings and visceral effectors are simpler than somatic junctions
• Branches form synapses en passant via varicosities
• Acetylcholine and norepinephrine are used as neurotransmitters
• Visceral responses are slower than somatic responses
Levels of Motor Control
• The three levels of motor control are– Segmental level– Projection level– Precommand level
Segmental Level
• The segmental level is the lowest level of motor hierarchy
• It consists of segmental circuits of the spinal cord
• Its circuits control locomotion and specific, oft-repeated motor activity
• These circuits are called central pattern generators (CPGs)
Projection Level
• The projection level consists of: – Cortical motor areas that produce the direct
(pyramidal) system– Brain stem motor areas that oversee the indirect
(multineuronal) system
• Helps control reflex and fixed-pattern activity and houses command neurons that modify the segmental apparatus
Precommand Level
• Cerebellar and basal nuclei systems that:– Regulate motor activity– Precisely start or stop movements– Coordinate movements with posture– Block unwanted movements– Monitor muscle tone
Reflexes
• A reflex is a rapid, predictable motor response to a stimulus
• Reflexes may: – Be inborn (intrinsic) or learned (acquired)– Involve only peripheral nerves and the spinal
cord – Involve higher brain centers as well
Reflex Arc
• There are five components of a reflex arc– Receptor – site of stimulus– Sensory neuron – transmits the afferent impulse to
the CNS– Integration center – either monosynaptic or
polysynaptic region within the CNS– Motor neuron – conducts efferent impulses from
the integration center to an effector– Effector – muscle fiber or gland that responds to
the efferent impulse
Stretch and Deep Tendon Reflexes
• For skeletal muscles to perform normally: – The Golgi tendon organs (proprioceptors) must
constantly inform the brain as to the state of the muscle
– Stretch reflexes initiated by muscle spindles must maintain healthy muscle tone
Muscle Spindles• Are composed of 3-10 intrafusal muscle fibers that
lack myofilaments in their central regions, are noncontractile, and serve as receptive surfaces
• Muscle spindles are wrapped with two types of afferent endings: primary sensory endings of type Ia fibers and secondary sensory endings of type II fibers
• These regions are innervated by gamma () efferent fibers
• Note: contractile muscle fibers are extrafusal fibers and are innervated by alpha () efferent fibers
Operation of the Muscle Spindles
• Stretching the muscles activates the muscle spindle– There is an increased rate of action potential in
Ia fibers
• Contracting the muscle reduces tension on the muscle spindle– There is a decreased rate of action potential on
Ia fibers
Operation of the Muscle Spindle
Figure 13.17
Stretch Reflex• Stretching the muscle activates the muscle
spindle• Excited motor neurons of the spindle cause
the stretched muscle to contract• Afferent impulses from the spindle result in
inhibition of the antagonist• Example: patellar reflex
– Tapping the patellar tendon stretches the quadriceps and starts the reflex action
– The quadriceps contract and the antagonistic hamstrings relax
Golgi Tendon Reflex
• The opposite of the stretch reflex
• Contracting the muscle activates the Golgi tendon organs
• Afferent Golgi tendon neurons are stimulated, neurons inhibit the contracting muscle, and the antagonistic muscle is activated
• As a result, the contracting muscle relaxes and the antagonist contracts
Flexor and Crossed Extensor Reflexes
• The flexor reflex is initiated by a painful stimulus (actual or perceived) that causes automatic withdrawal of the threatened body part
• The crossed extensor reflex has two parts– The stimulated side is withdrawn– The contralateral side is extended
Afferentfiber
Efferentfibers
Extensorinhibited
Flexorstimulated
Right arm(site of stimulus)
Left arm (site ofreciprocal activation)
Arm movements
Interneurons
Key:+ Excitatory synapse– Inhibitory synapse
Efferentfibers
Flexorinhibited
Extensorstimulated
+
–+
–
+
+
Flexes
Extends
Figure 13.19
Crossed Extensor Reflex
Afferentfiber
Right arm(site of stimulus)
Key:+ Excitatory synapse– Inhibitory synapse
+
–+
–
+
+
Figure 13.19
Crossed Extensor Reflex
Afferentfiber
Right arm(site of stimulus)
Interneurons
Key:+ Excitatory synapse– Inhibitory synapse
+
–+
–
+
+
Figure 13.19
Crossed Extensor Reflex
Afferentfiber
Efferentfibers
Right arm(site of stimulus)
Left arm (site ofreciprocal activation)
Interneurons
Key:+ Excitatory synapse– Inhibitory synapse
Efferentfibers
+
–+
–
+
+
Figure 13.19
Crossed Extensor Reflex
Afferentfiber
Efferentfibers
Extensorinhibited
Flexorstimulated
Right arm(site of stimulus)
Left arm (site ofreciprocal activation)
Interneurons
Key:+ Excitatory synapse– Inhibitory synapse
Efferentfibers
Flexorinhibited
Extensorstimulated
+
–+
–
+
+
Figure 13.19
Crossed Extensor Reflex
Afferentfiber
Efferentfibers
Extensorinhibited
Flexorstimulated
Right arm(site of stimulus)
Left arm (site ofreciprocal activation)
Arm movements
Interneurons
Key:+ Excitatory synapse– Inhibitory synapse
Efferentfibers
Flexorinhibited
Extensorstimulated
+
–+
–
+
+
Flexes
Extends
Figure 13.19
Crossed Extensor Reflex
Superficial Reflexes
• Initiated by gentle cutaneous stimulation• Example:
– Plantar reflex is initiated by stimulating the lateral aspect of the sole of the foot
– The response is downward flexion of the toes– Indirectly tests for proper corticospinal tract
functioning– Babinski’s sign: abnormal plantar reflex indicating
corticospinal damage where the great toe dorsiflexes and the smaller toes fan laterally