BIO210 Weekly Guide #10
PERIPHERAL NERVOUS SYSTEM;
VISCERAL NERVOUS SYSTEM
After completing this laboratory you should be able to:
1) Identify or each of the cranial nerve pairs, and state its rout of exit from the cranium and major actions
2) Recognize the common structure of the spinal nerves, particularly as they relate to the spinal cord
3) Identify the major nerve roots and nerves of the brachial and lumbosacral plexi
4) Identify and distiguish dorsal root ganglia and paravertebral chain ganglia in terms of anatomical location and function
5) Distinguish clearly between the sympathetic and parasympathetic nervous systems in terms of anatomical location, anatomical structure, and function.
6) Recognize spinal nerves in histological section
7) Identify and distinguish dorsal root ganglia, sympathetic ganglia and parasympathetic ganglia/plexi in histological section
Guide to Gross Anatomy Guide to Histology Guide to Physiology
Outline
I. Peripheral Nervous System
A. Components
nerves
structure
axons
myelination - Schwann cells
C.T. and bundling pattern
spinal vs. cranial nerves {FAP13-4, 14-FOCUS SECTION}
afferent (sensory) vs. efferent (motor) fibers
ganglia
DRG, retinal ganglion cells, spiral ganglion, gustatory ganglia
receptors
exteroceptors
retinal receptors, auditory and vestibular hair cells, taste buds,
olfactory receptors, skin receptors
interoceptors
muscle spindles, GTOs, visceral receptors
B. Spinal cord and paraspinal structures {FAP 13-2 to 13-4}
ventral and dorsal horns
ventral and dorsal roots
dorsal root ganglia
DRG cells (pseudounipolar neurons)
satellite cells (glia)
the reflex arc
C. Peripheral structures {FAP 13-4}
spinal nerves
31 pairs
ventral ramus
dorsal ramus
plexuses {FAP 13-4}
brachial plexus
lumbosacral plexus
D. Cranial nerves - #s, names, functions, origins, targets, exits from skull
{FAP - FOCUS}
12 (pairs) cranial nerves - sensory, motor, and mixed
a couple of tired, sanitized mnemonics:
Names -"On old Olympus' towering top a Finn and German vault and hop."
Fibers -"Some say 'Marry money', but my brother says 'Bad boys marry money'"
complete list of names and functions in the Guide to Gross Anatomy below
II. Visceral Nervous System (Autonomic Nervous System)
A. Function - visceral control
B. Components {FAP 16-1}
afferent visceral sensory
efferent visceral motor
sympathetic and parasympathetic divisions
preganglionic and postganglionic fibers
C. Sympathetic division {FAP 16-2, 16-3}
origins - thoracic and lumbar cord
general functions
diffuse activity
components
lateral horns of spinal gray - preganglionic cell bodies
ganglia - postganglionic cell bodies
sympathetic (paravertebral) chain ganglia
white, gray, and communicating rami
celiac and mesenteric ganglia
adrenal medulla
D. Parasympathetic division {FAP 16-4, 16-5}
origins - cranial nuclei and sacral cord
general functions
specific activity
components
cranial nerves III, VII, IX, X (preganglionic fibers)
sacral nerves (preganglionic fibers)
visceral ganglia and plexuses
Gross Anatomy List
Cranial Nerves
NI olfactory
NII optic
NIII oculomotor
NIV trochlear
NV trigeminal
NVI abducens
NVII facial
NVIII vestibulocochlear (auditory)
NIX glossopharyngeal
NX vagus
NXI spinal accessory
NXII hypoglossal
Spinal Nerves Structures:
ventral root
dorsal root
dorsal root ganglion
spinal nerve
Spinal Nerve Plexuses Innovating the Extremities:
Cervical Plexus: (C1-C4)
phrenic nerve
Brachial Plexus: (C5-T1)
lateral & medial cords
musculocutaneous nerve
median nerve
ulnar nerve
posterior cord
axillary nerve
radial nerve
Lumbosacral Plexus: (T12-S3)
femoral nerve
obturator nerve
sciatic nerve
Autonomic (Visceral) Nervous System:
paravertebral chain ganglia (sympathetic trunk)
collateral sympathetic ganglia
celiac, superior mesenteric, and inferior mesenteric
vagus nerve
adrenal gland (medulla)
Key: Know location and approximate regions innervated
Guide to Gross Anatomy
The nervous system may be divided on gross anatomical grounds into the central nervous system, consisting of the brain and spinal cord, and the peripheral nervous system, consisting of the cranial and spinal nerves. The nervous system may alternatively be split on functional grounds into the somatic and visceral (autonomic) nervous systems. Last week we dealt with the central nervous system. This week we will deal with the peripheral nervous system and the visceral/autonomic nervous system.
Cranial Nerves {FAP FOCUS Section; APL Fig 14.4}
#
Name
Fibers
Origin
Exit Foramen
Functions
NI
Olfactory
sensory
telencephalon
cribriform plate
of the ethmoid
special sense of smell
NII
Optic
sensory
diencephalon
optic foramen
special sense of vision
NIII
Oculomotor
motor
mesencephalon
superior orbital fissure
somatic motor to 4 extrinsic eye muscles; ciliary body; visceral motor to pupillary sphincter
NIV
Trochlear
motor
mesencephalon
superior orbital fissure
somatic motor to superior oblique eye muscle
NV
Trigeminal -
Ophthalmic
Branch
sensory
metencephalon
superior orbital fissure
general sensory for upper head, face, eye
Trigeminal -
Maxillary
Branch
sensory
metencephalon
foramen rotundum
general sensory to maxillary region of face and nasal cavity
Trigeminal
Mandibular
Branch
mixed
metencephalon
foramen ovale
general sensory for lower jaw and face; somatic motor to muscles of mastication
NVI
Abducens
motor
metencephalon
superior orbital fissure
somatic motor to lateral rectus eye muscle
NVII
Facial
mixed
metencephalon
internal auditory meatus to stylomastoid
foramen
special sense of taste from anterior 2/3 of tongue; somatic motor to muscles of facial expression; visceral motor to submandibular, sublingual, and lacrimal glands
NVIII
Vestibulocochlear
(Auditory)
sensory
metencephalon
internal auditory meatus
special senses of audition and equilibrium
NIX
Glossopharyngeal
mixed
myelencephalon
jugular foramen
general sense from pharynx; special senses of taste from posterior 1/3 of tongue; visceral sense from carotid baroreceptors and chemoreceptors; general motor to pharynx muscles; visceral motor to parotid salivary gland
NX
Vagus
mixed
myelencephalon
jugular foramen
minor special sense of taste from epiglottis; visceral sense from aortic baroreceptors and chemoreceptors; visceral sense from thoracic and abdominal viscera; somatic motor to pharynx and larynx; Visceral motor to thoracic and abdominal viscera
NXI
Spinal Accessory
motor
myelencephalon
enters via foramen magnum; exits via jugular foramen
somatic motor to pharynx, larynx, trapezius, and sternocleidomastoideus
NXII
Hypoglossal
motor
myelencephalon
hypoglossal canal
somatic motor to tongue
As indicated above, there are twelve paired cranial nerves, numbered NI through NXII. For each nerve you should know its name, its number, the brain region it originates from, and its functions. In other words, memorize the preceding table. You should also be able to recognize each nerve at its origin from the brain on preserved brains and models, and each exit route in the base of the skull.
Spinal Nerves {FAP Fig 13-2,13-3, 13,4; APL FIg 14.8 to 14.11}
The 32 pairs of spinal nerves carry sensory information from the periphery to the CNS and motor output of the CNS back to the periphery. The neural "circuit" between sensory input and motor output can be as simple as a spinal reflex arc, or as complex as the almost innumerable interactions required to hit a moving baseball.
We will concentrate on the anatomical nerve root pattern common to all of the spinal nerves, and on those nerves that run into the upper and lower extremities, forming the brachial and lumbosacral plexuses, respectively.
a) On the prepared spinal cord and the model horizontal section through the cord and column locate the following:
ventral horn dorsal roots ventral ramus
dorsal horn dorsal root ganglion dorsal ramus
ventral roots
- Where are the neuron cell bodies located whose axons make up the ventral roots? Are these sensory or motor cells? Where are the neuron cell bodies located whose axons make up the dorsal roots? Are these sensory or motor cells?
- Where do the dorsal root ganglia lie in relation to the vertebrae of the spinal column?
- Each of the paired spinal nerves is formed by the fusion of the ventral and dorsal roots from that segment of the cord. The nerve travels a short distance as a common spinal nerve, then branches into a small dorsal and a large ventral ramus. What regions of the body are supplied by the dorsal rami? By the ventral rami?
- How many pairs of spinal nerves are associated with each of the five regions of the vertebral column?
b) In some regions of the spinal cord the spinal nerves (ventral rami) from neighboring segments form anastomosing networks called plexuses. One principal nerve from the cervical plexus is the phrenic nerve. What muscle does this nerve (pair) innervate?
c) Locate the brachial plexus on the cat excised nervous system and models. Identify the following:
medial cord ulnar nerve radial nerve
lateral cord median nerve axillary nerve
posterior cord musculocutaneous nerve
- State which muscle groups of the upper extremity are innervated by each of the above nerves.
- Note the anatomical relationship of the brachial plexus to the axillary artery.
d) Locate the lumbosacral plexus on the charts and models. Locate the following nerves where they pass through the abdominal cavity and where they run in the lower extremity.
femoral nerve sciatic nerve obturator nerve
- What muscle groups are innervated by each of these nerves? By what route does each nerve leave the abdominal or pelvic cavity?
Autonomic Nervous System {APL Fig 16-2 to 16-6}
The visceral or autonomic nervous system has traditionally been considered to be a purely motor system for "involuntary" control of visceral smooth muscle and glandular activity. More recently, it has come to be understood as a true "visceral nervous system" with both sensory and motor components. The afferent sensory fibers carry "state" information from sensors of the viscera, e.g. pulmonary stretch receptors, carotid and aortic baroreceptors. The efferent motor fibers carry "control" information back to the viscera.
We will concentrate on the visceral efferent neurons, because their structures and functions are the most clearly demonstrated. The visceral efferent system has two main divisions - sympathetic and parasympathetic. These are roughly antagonistic systems, and a balance between their activities maintains homeostasis. Review the specific sympathetic and parasympathetic actions. Review also the meanings of the terms preganglionic and postganglionic, as applied to the visceral efferent fibers.
a) The sympathetic division arises from the thoracic and lumbar spinal cord. Identify the following structures in the charts, prepared spinal cord, and models (as appropriate):
white communicating ramus celiac ganglion
gray communicating ramus superior mesenteric ganglion
paravertebral chain ganglia inferior mesenteric ganglion
- In which horn of the spinal gray matter do sympathetic preganglionic neurons lie? By what route do their axons reach the paravertebral chain ganglia? By what route do postganglionic fibers run from the paravertebral ganglia to the spinal nerves?
- Some preganglionic fibers run up or down the paravertebral chain to synapse at another vertebral level. This characteristic makes the sympathetic division act in a very diffuse, whole body manner, in contrast to the organ specificity of the parasympathetic system. How does this anatomical pattern promote general (whole body) arousal when the sympathetic nervous system is activated?
- Some preganglionic fibers pass through the chain ganglia to synapse in one of the three collateral ganglia - the celiac, superior mesenteric, or inferior mesenteric. What is the solar plexus?
- Finally, some preganglionic fibers bybass all of the sympathetic ganglia to synapse in the adrenal medulla (discussed further in the endocrine week next semester). The adrenal medulla releases adrenalin (epinephrine) into the blood. Adrenalin mimics most of the effects of noradrenalin (norepinephrine), the neurotransmitter at post-ganglionic sympathetic nerve terminals. How might the involvement of the adrenal gland also promote the whole-body nature of sympathetic arousal?
b) The parasympathetic division arises from the brain and the sacral spinal cord, hence the name parasympathetic (around the sympathetic). The cranial preganglionic components travel in cranial nerves III, VII, IX, & X. The sacral preganglionic components travel in the pelvic nerves.
- Parasympathetic preganglionic fibers are quite long and travel to ganglia located in the target organs themselves. This makes the parasympathetic division act in a very direct and organ- specific manner, in contrast to the diffuse sympathetic action.
- The sympathetic and parasymapathetic systems are generally antagonistic and the relative degree of activation in each constitutes "autonomic balance". As a simple example, parasympathetic arousal constricts the pupils of the eyes and sympathetic arousal dilates the pupils. Preganglionic axons of the parasympathetic system travel to the eye in the oculomotor nerve (NIII) and innervate the pupillary sphincter muscle. Postganglionic sympathetic fibers from the superior cervical ganglion (the anterior end of the paravertebral chain ganglia) travel by way of the ophthalmic branch of the trigeminal nerve (NV) to the pupillar dilator muscles.
- As a routine part of an eye exam, your doctor will dilate your pupils with atropine, a parasympathetic blocker of the pupillary sphincter muscles. Why not just use adrenaline (epinephrine) which directly mimics sympathetic arousal of the dilator muscles?
Guide to Histology
Peripheral and Visceral Nervous Systems
After working through these slides you should be able to:
1) Define the following histological terms: nerve, ganglion, neurolemma, endoneurium, perineurium, epineurium, axis cylinder, myelin, Schwann cell, node of Ranvier, satellite cell.
2) Identify and distinguish between: somatic ganglia (e.g. DRG), sympathetic ganglia (e.g. paravertebral chain), and parasympathetic ganglia (e.g. Meissner's and Auerbach's plexuses.
3) For the visceral nervous system define: preganglionic fiber, postganglionic fiber.
4) Identify a peripheral nerve in cross or longitudinal section.
a) Peripheral Nerves {FAP Fig. 14.3}
A nerve is a collection of axons running in parallel and bundled together, located outside of the CNS. Peripheral nerves typically carry axons of widely varying diameter, some of which are myelinated and some of which are not. Nerves also typically carry both sensory and motor fibers, thus impluses travel in both directions along the nerve.
- Examine the X-sections of peripheral nerves. Identify the endoneurium, perineurium, and epineurium connective tissue framework which bundles the axons. Note the similarity in this bundling pattern to that of skeletal muscle. What mechanical properties does this C.T. convey to nerves?
- In the cross sections on high power locate the axis cylinders and their myelin sheaths. Identify Schwann cell nuclei. What are the functions of Schwann cells and myelin?
- Note the annoying similarity in appearance of peripheral nerves, smooth muscle, and dense regular collagenous C.T. in longitudinal section. How could you distinguish them ?
- Find the terminal axon boutons and neuromuscular junctions in the demonstration slide of nerve endings on skeletal muscle.
b) Somatic Ganglia
A ganglion is a collection of nerve cell bodies located outside of the CNS. Motor ganglia in the visceral nervous system are either sympathetic or parasympathetic. Somatic ganglia contain sensory neuron cell bodies. Somatic nerves do not have motor ganglia; the motor neuron somas are in the CNS (e.g. ventral horn cells).
- Locate the dorsal root ganglion (DRG, also called a sensory ganglion or spinal ganglion because it contains sensory neurons and is located along the dorsal roots near the spinal cord) in the spinal cord slide. Identify the DRG cells. Are these neurons unipolar, pseudounipolar, bipolar, or multipolar? Are their nuclei central or eccentric?
- Identify also (if possible) satellite cells, fibroblasts, and dorsal root fibers (axons).
c) Sympathetic Gangila
Sympathetic ganglia are embedded in loose irregular C.T. Sympathetic ganglion cells are multipolar neurons with eccentric nuclei, surrounded by an interrupted ring of satellite cells (glia). In the sympathetic ganglion, identify ganglion cells and satellite cells.
- Note that in the sympathetic ganglion, small clumps of neuron somas are interspersed with axon bundles. By comparison, in dorsal root ganglia the neuron somas tend to be more segregated from the axon bundles.
- In what locations are sympathetic ganglia found? Where are the cell bodies of the sympathetic preganglionic fibers located?
d) Parasympatheitc Ganglia
Parasympathetic ganglia are embedded in the surrounding tissues of the organs that they serve, in contrast to sympathetic ganglia. In the gut, ganglion cell bodies and their satellite cells are embedded in the muscular and connective tissue layers that make up the walls of hollow organs such as the esophagus, stomach, and intestines. Auerbach's (myenteric) plexus consists of small nests of ganglion and satellite cells sandwiched between the inner circular and outer longitudinal smooth muscle layers; these neurons regulate peristalsis and gut motility. Meissner's (submucosal) plexus consists of similar nests of neurons and satellite cells in the irregular C.T. of the submucosa; these neurons regulate secretion and, to a lesser extent, motility.
- Locate Auerbach's myenteric plexus in the ileum slide. Are the neuron nuclei central or eccentric? Are these unipolar, pseudounipolar, bipolar, or multipolar neurons? Where are the cell bodies of the preganglionic fibers that project to these parasympathetic ganglia located?
- Can you now distinguish somatic sensory ganglia (DRG), sympathetic ganglia, and parasympathetic ganglia?
- What are the functional, anatomical, and neurochemical differences between the sympathetic and parasympathetic nervous systems?
Guide to Physiology
The physiology of both the central and peripheral nervous systems will be covered in week 12.