3. Introduction
The critical component of central network involved in
homeostasis & adaptation
3 subdivisions :
â—ŹSympathetic Nervous System
â—ŹParasympathetic Nervous System
â—ŹEnteric Nervous System
4. To repeat…
ANS is the subdivision of the peripheral nervous system that
regulates body activities that are generally not under
conscious control
â—ŹVisceral motor innervates non-skeletal (non-somatic)
muscles
â—ŹComposed of a special group of neurons serving:
â—Ź
â—Ź
â—Ź
â—Ź
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Cardiac muscle (the heart)
Smooth muscle (walls of viscera and blood vessels)
Internal organs
Skin
4
5. Divisions of the autonomic nervous system
Parasympathetic division
â—Ź
Sympathetic division
â—Ź
Serve most of the same organs but cause opposing
or antagonistic effects
Parasysmpathetic: routine maintenance
“rest &digest”
Sympathetic: mobilization & increased metabolism
“fight, flight or fright” or “fight, flight or freeze”
5
6. Basic anatomical difference between the motor pathways of
the voluntary somatic nervous system (to skeletal muscles)
and those of the autonomic nervous system
Somatic division:
â—Ź
â—Ź
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Cell bodies of motor neurons reside in CNS (brain or spinal cord)
Their axons (sheathed in spinal nerves) extend all the way to their
skeletal muscles
Autonomic system: chains of two motor neurons
â—Ź
â—Ź
â—Ź
â—Ź
1st = preganglionic neuron (in brain or cord)
2nd = ganglionic neuron (cell body in ganglion outside CNS)
Slower because lightly or unmyelinated
6
7. â—Ź
â—Ź
Axon of 1st (preganglionic) neuron leaves CNS to
synapse with the 2nd (ganglionic) neuron
Axon of 2nd (ganglionic) neuron extends to the organ
it serves
Diagram contrasts somatic (lower) and autonomic:
autonomic
this dorsal root
ganglion is
sensory
somatic
7
Note: the autonomic ganglion is motor
8. Anatomical Differences in Sympathetic
and Parasympathetic Divisions
Length of postganglionic fibers
–
Sympathetic – long postganglionic fibers
–
Parasympathetic – short postganglionic fibers
Branching of axons
–
Sympathetic axons – highly branched
–
Influences many organs
–
Parasympathetic axons – few branches
–
Localized effect
8
12. Sympathetic nervous system continued
Regardless of target, all begin same
â—Ź
Preganglionic axons exit spinal
cord through ventral root and enter
spinal nerve
â—Ź
Exit spinal nerve via
communicating ramus
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Enter sympathetic trunk/chain
where postganglionic neurons are
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Has three options…
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12
13. Options of preganglionic axons in
sympathetic trunk
Synapse on postganglionic neuron in chain ganglion then
return to spinal nerve and follow its branch to the skin
â—Ź
Ascend or descend within sympathetic trunk, synapse with a
posganglionic neuron within a chain ganglion, and return to
spinal nerve at that level and follow branches to skin
â—Ź
Enter sympathetic chain, pass through without synapsing, form
a splanchnic nerve that passes toward thoracic or abdominal
organs
â—Ź
These synapses in prevertebral ganglion in front of aorta
â—Ź
Postganglionic axons follow arteries to organs
â—Ź
13
19. The Role of the Adrenal Medulla in the
Sympathetic Division
Major organ of the sympathetic nervous system
Secretes great quantities epinephrine (a little
norepinephrine)
Stimulated to secrete by preganglionic sympathetic
fibers
23. Cranial Outflow
Preganglionic fibers run via:
–
Oculomotor nerve (III)
–
Facial nerve (VII)
–
Glossopharyngeal nerve (IX)
–
Vagus nerve (X)
Cell bodies located in cranial nerve nuclei in the brain
stem
24. Westphal nucleus is a part of occulomotor complex in
midbrain – sends preganglionic axons that occupy peripheral
portion of the occulomotor nerve and synapse on the neurons
of ciliary ganglion in the orbit
â—Ź
These neurons innervate iris and ciliary muscles
â—Ź
Eliciting pupil constriction, accomodation of eye
â—Ź
25. Superior salivatory nucleus –
â—Ź
In pons
â—Ź
projects via facial nerve to sphenopalatine ganglion, which
innervates - lacrimal gland ( lacrimation )
cerebral blood vessels ( vasodilatation )
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to submandibular ganglion – secretomotor & vasodilator
inputs to corresponding salivary glands
â—Ź
26. Inferior salivatory nucleus –
â—Ź
In medulla
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Sends axons via glossopharyngeal nerve
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Synapse on Otic ganglion
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Stimulate parotid gland secretion
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27. Outflow via the Vagus Nerve (X)
Fibers innervate visceral organs of the
thorax and most of the abdomen
Stimulates - digestion, reduction in
heart rate and blood pressure
Preganglionic cell bodies
Located in dorsal motor nucleus
in the medulla
Ganglionic neurons
–
–
Confined within the walls of
organs being innervated
28. Vagus innervates heart, respiratory tract and entire
gastrointestinal tract except descending colon and rectum
â—Ź
Most vagal preganglionic neurons – situated in dorsal motor
nucleus of vagus provides input to git and respiratory
tracts, heart
â—Ź
Vagal preganglionic output to heart - Neurons in
ventrolateral portion of nucleus ambiguus
â—Ź
Vagus – cardioinhibitory, visceromotor and secretomotor
effects
â—Ź
30. Sacral preganglionic output –
Arises from neurons of sacral preganglionic nucleus located
in lateral gray matter of spinal segments S2 & S3
â—Ź
Their axons pass via ventral roots of pelvic splanchnic nerves
which join inferior hypogastric plexus
â—Ź
Innervate colon, bladder, sexual organs
â—Ź
Parasympathetic output – contraction of bladder detrussor
muscle & circular smooth muscle of rectum.
â—Ź
31. Sacral parasympathetic output elicits
Vasodilatation of cavernous tissue of penis
required for penile erection ,
whereas sympathetic output controls ejaculation
â—Ź
32. 2
Autonomic Plexuses
• A network of sympathetic and parasympathetic axons.
• Cardiac plexus- heart.
• Pulmonary plexus- the bronchial tree.
• Celiac plexus- largest. Supplies the stomach, spleen,
pancreas, liver, gallbladder, and adrenal medullae.
33. 3
Autonomic Plexuses (Cont’d)..
• Superior mesenteric plexus- small intestine and proximal
colon.
• Inferior mesenteric plexus- distal colon and rectum.
• Hypogastric plexus- urinary bladder and genital organs.
• Renal plexus- kidneys and ureters.
34. Enteric Nervous System
Includes several types of sensory neurons, inter-neurons,
motor neurons – which form integrative local reflex circuits
â—Ź
Controlling motility, secretion, blood flow throughout the gut
â—Ź
The activity of enteric nervous system is largely independent
of extrinsic innervation but is modulated by both vagal inputs
from dorsal vagal nucleus and sympathetic inputs from
prevertebral ganglia
â—Ź
35. 5
Integration and Control of Autonomic
Functions
• Direct innervation- brain stem and spinal cord.
• Hypothalamus is the major control and integration center of
the ANS.
• It receives input from the limbic system.
36. Central control of the
Autonomic NS
Amygdala: main limbic region
for emotions
-Stimulates sympathetic activity,
especially previously learned fearrelated behavior
-Can be voluntary when decide to recall
frightful experience - cerebral cortex
acts through amygdala
-Some people can regulate some
autonomic activities by gaining
extraordinary control over their
emotions
Hypothalamus: main integration
center
Reticular formation: most direct
influence over autonomic
function
36
37. Components
Telencephalic structures –insular cortex
ant cingulate cortex
Amygdala
â—Ź
Insular cortex - integration of bodily sensation, emotion,
decision making
â—Ź
anterior cingulate cortex – motivation, goal directed
behavior
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amygdala – conditioned fear responses
â—Ź
38. Hypothalamus – central role in integrating autonomic and
endocrine responses
â—Ź
Hypothalmus – critical role in adaptation to internal /
external stimuli, while maintaining homeostasis
â—Ź
3 zones
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Paraventricular zone – neuroendocrine control via
connections to pituitary
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Medial zone – thermoregulation, osmoregulation, food
intake, response to stress
â—Ź
Lateral zone – arousal behaviour, sleep wake cycle
â—Ź
39. Brain Stem Components –
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Periaqueductal gray –
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integration of autonomic, somatic and antinociceptive
responses to external stress.
â—Ź
coordinates cardiovascular, respiratory, thermoregulatory,
urinary, reproductive and pain control systems
â—Ź
Parabrachial nucleus – taste, salivation, gi activity,
cardiorespiratory activity, thermoregulation
â—Ź
NTS – 1st relay center for taste and visceral afferent
information carried in CN VII,IX,X
And also for all medullary, cvs, rs, gi reflexes
â—Ź
40. Visceral Afferents
Inform CNS about Mechanical & Chemical events in internal
organs
â—Ź
This information is conveyed to produce conscious visceral
sensation and initiate visceral reflex responses
â—Ź
Spinal visceral afferents innervate all peripheral organs
â—Ź
Their cell bodies are in dorsal root ganglion
â—Ź
41. Brain stem visceral afferents are carried primarily by
glossopharyngeal and vagus nerves
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Cell bodies in petrosal & nodose ganglia
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All brain stem visceral afferent nerves relay in nucleus of
solitary tract ( NTS )
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NTS is a major site of information integration of many
bodily functions
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42. Rostral portion of NTS – receives taste afferents via facial
nerve( geniculate ganglion ) , glossopharyngeal & vagus
nerves
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Intermediate portion – receives gastrointestinal afferents
â—Ź
Caudal portion of the NTS recieves afferent information
from baroreceptors, cardioreceptors, chemoreceptors and
pulmonary receptors
â—Ź
43. Anatomical Differences in Sympathetic
and Parasympathetic Divisions (Recall)
Issue from different regions
of the CNS
–
Sympathetic – also
called the
thoracolumbar division
–
Parasympathetic – also
called the craniosacral
division
49. Horner's syndrome
â—Ź
Interruption of sympathetic supply to head and neck
â—Ź
Constriction of pupil
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Drooping of upper eyelid
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Reduced prominance of eye(enophthalmous)
â—Ź
anhydrosis