ANS III- Parasympathetic Nervous System and Visceral Sensory

Summary

This document provides an overview of parasympathetic nervous system and visceral sensory functions in the body. The document details processes involved, including anatomical structures and pathways, to assist in medical diagnosis.

Full Transcript

ANS III- Parasympathetic and
Visceral Sensory
Course Learning Objective
Nervous: Describe how the body communicates with itself by identifying
anatomical structures and tracing pathways of the nervous system in order to
aid in medical diagnoses when these systems are compromised
 LO 6

Lecture Learning Objectives
1. Compare and contract cranial and sacral 5. Briefly describe what the enteric nervous
parasympathetic pathways including system is and what makes the enteric nervous
1. Associated CNS structures system unique
2. Associated PNS structures/ganglia 6. Explain the role and stimuli of autonomic
2. Diagram the parasympathetic pathways for CN reflexes
III, VII, IX, and X including the following: 7. Explain to a friend the following regarding
a. Location of nuclei in brainstem visceral sensation:
b. Preganglionic axons a. Its role
c. Associated cranial ganglion b. How it is stimulated
d. Postganglionic axons c. Contrast the type of sensation that travels with
e. Target organ sympathetic versus parasympathetic fibers
d. The type and origin of visceral pain
3. Recall the spinal contribution and pre and
postganglionic pathway for parasympathetic 8. Identify indicated parasympathetic terms on
sacral outflow, effects, and target organs histology slide
4. List the sympathetic and parasympathetic 9. Identify the terms indicated by on supplied
contributions and resulting effects for each images
autonomic plexus; link these to the origins of
each contribution (e.g., brainstem/spinal
contributions, splanchnic or cranial nerve, type
and location of ganglia)
Parasympathetic
Introduction
 LO 1

Parasympathetic Division
Most active during times the body
must process nutrients, conserve
energy, and return to homeostasis
(anabolic)

Anatomically more restricted than
the sympathetic division

Axons are not components of the
spinal nerves or their branches

Gray’s Basic Anatomy, Drake et al., 2018
 LO 1
Parasympathetic Division
Cranial parasympathetic outflow
Preganglionic cell bodies located in
brainstem nuclei
Exit via cranial nerves
Synapse on parasympathetic crania ganglia
postganglionic axons to target organ

Sacral parasympathetic outflow
Preganglionic cell bodies located in spinal
cord segments S2-S4
Exit via anterior roots of sacral spinal nerves
forming pelvic splanchnic nerves from
anterior rami
Synapse on ganglia in (intramural) or near
(terminal ganglia) target organ
postganglionic organs to target organ

Preganglionic axons are long and
postganglionic axons are short
Clinically Oriented Anatomy, Moore et al., 2018
Cranial Outflow
 LO 2
Cranial Nerves: Introduction
12 pairs
Numerically ordered using roman numerals

Which motor pathway travels through cranial nerves?
How is sensory information from head and neck
transmitted?

Sensory and motor communication carried within
CNs will synapse on cranial nerve nuclei
Nuclei for all CN are in brainstem, except CN I and II

Travel through openings in crania and are covered
with protective CT continuous with meninges

Communication occurs between cranial nerves
E.g., nerves may begin as sensory, but receive motor
fibers along its course
Cranial Nerves and Nuclei

CN III

CN VII

CN IX

CN X
 1 LO 2
2
Cranial Outflow 3

Preganglionic cell bodies in cranial nerve nuclei
in brainstem
Cranial nerves
III (Oculomotor)
VII (Facial)
IX (Glossopharyngeal)
X (Vagus)

Postganglionic cell bodies in parasympathetic
cranial ganglia
1. Ciliary
2. Otic
3. Pterygopalatine
4. Submandibular
4
Postganglionic axons
Target organ/muscle
 Mesencephalic nuclei
Ciliary ganglion LO 2

Cranial Outflow- CN III
Exits brain stem near midline at
superior aspect of pons

Cranial nerve III (Oculomotor)
Preganglionic cell bodies in
mesencephalic nuclei
Exit via CN III CN III
Synapse in ciliary ganglion
Postganglionic fibers to
1. Ciliary muscles
2. Sphincter pupillae muscles of
iris and eye

Lens accommodation and
pupillary constriction
 LO 2
Cranial Outflow- CN VII
Pterygopalatine
Cranial nerve VII (Facial) ganglion
Preganglionic cell bodies in pontic Greater Pontic nuclei
nuclei petrosal
Exit via CN VII nerve

A
Greater petrosal nerve
Synapse on pterygopalatine ganglion
Lacrimal gland and smaller glands of
nasal and oral cavity
Tear production, nasal secretion

B Chorda
Chorda tympani tympani
Synapse on submandibular ganglion
Submandibular and sublingual glands Submandibular
Saliva production ganglion
 Otic ganglion LO 2
Cranial Outflow- CN IX Medullary nuclei

Cranial nerve IX (Glossopharyngeal)
Preganglionic cell bodies are house in
medullary nuclei
Exit via CN IX
Synapse on otic ganglion
postganglionic fibers to parotid gland
Increased saliva flow

Parotid
gland
 LO 2
Cranial Outflow- CN X
Cranial nerve X (vagus= wanderer)
~80% of all parasympathetic innervation
comes from CN X

Supplies parasympathetic innervation to
the thoracic and abdominal cavities

Thoracic
Heart
Respiratory tract (larynx to lungs)

Abdomen
Liver, gallbladder, pancreas
Kidneys
Digestive tract from esophagus down to
proximal half of large intestines
Gonads (testes and ovaries)
Clinically Oriented Anatomy, Moore et al., 2018
 LO 2
Cranial Outflow- CN X
Cranial nerve X (vagus= wanderer)
Preganglionic cell bodies are house in medullary
nuclei
a. Solitary nucleus- visceral sensory
b. Dorsal nucleus- visceral motor
c. Nucleus ambiguus- visceral motor to heart
d. (Spinal trigeminal nucleus)
Exit via CN X
Travels through neck into thorax
Branches into anterior and posterior vagal trunks
Synapse on terminal or intramural ganglia
Target organ

Thoracic cavity: increased mucous production,
decreased diameter of airways, decreased heart
rate and contraction force

Passes through diaphragm
Abdominal cavity: increases smooth muscle motility
and secretory activity in digestive organs(increased
digestion)
Sacral Outflow
 LO 3
Sacral Outflow
Preganglionic cell bodies in spinal
cord levels S2-S4

Leave via anterior root

Branch to form pelvic splanchnic
nerves
Contribute to superior and inferior
hypogastric plexuses

Synapse in target or intramural
ganglia (location of postganglionic
cell bodies) at organs
Clinically Oriented Anatomy, Moore et al., 2018
 LO 3

Sacral Outflow
Innervates distal portion of
large intestines, rectum,
most reproductive organs,
urinary bladder, distal
ureter

Increased smooth muscle
motility and secretory
activity in digestive tract
Contraction of smooth
muscle in bladder wall
Erection of clitoris and
penis
 LO 3

Sacral Outflow Female pelvis:
Anterior View
Innervates distal portion of
large intestines, rectum,
most reproductive organs,
urinary bladder, distal
ureter
S2

Increased smooth muscle S3
S4
motility and secretory
activity in digestive tract
Contraction of smooth
muscle in bladder wall
Erection of clitoris and
penis
Female pelvis: Lateral View
Autonomic Plexuses
 LO 4
Autonomic Para Sym
Plexuses
Collection of Pulmonary
postganglionic sympathetic fibers + plexus Cardiac plexus
preganglionic parasympathetic fibers
+ visceral sensory Esophageal
Axons travel next to one another, but plexus
do not interact
Abdominal plexus
Cardiac plexus Organ
Pulmonary plexus
Esophageal plexus
Abdominal plexus
Celiac plexus
Superior mesenteric plexus
Inferior mesenteric plexus
Hypogastric plexus
Hypogastric plexus
 LO 4

Cardiac Plexus
In thoracic cavity’s mediastinum

Postganglionic sympathetic axons
from sympathetic trunk: superior,
middle and inferior cervical ganglion,
T1-T5

Preganglionic parasympathetic axons
from nucleus ambiguus and vagus
nerve/CN X

Sympathetic activity- increased heart
rate and blood pressure, vasodilation
Parasympathetic activity- decreased
heart rate, vasoconstriction
Gray’s Basic Anatomy, Drake et al., 2018
 LO 4

Pulmonary Plexuses
Surrounds bronchi and blood vessels
of the lungs
T T
Postganglionic sympathetic axons
from sympathetic trunk- T1-T5

Preganglionic parasympathetic axons
from dorsal nucleus and vagus
nerve/CN X

Sympathetic activity- bronchodilation
(increased diameter of bronchi)
Parasympathetic activity-
bronchoconstriction (decreased
diameter of bronchi) and increased
secretion from mucous glands

Gray’s Basic Anatomy, Drake et al., 2018
 LO 4
Esophageal
Plexuses
Controls swallowing reflex
No sympathetic activity
E

Preganglionic
parasympathetic axons from
vagus nerve/CN X

Parasympathetic activity- Stomach
innervates smooth muscle in
the inferior esophagus and
cardiac sphincter (circular
muscle/valve at opening of
stomach), promotes
peristalsis

Gray’s Basic Anatomy, Drake et al., 2018
 LO 4

Abdominal Plexuses
Named for vessels they surround

Includes celiac, superior and inferior
mesenteric plexuses (aortic plexus)

Postganglionic sympathetic axons
from prevertebral ganglia

Preganglionic parasympathetic
axons from vagus nerve/CN X

Gray’s Basic Anatomy, Drake et al., 2018
 LO 4
Abdominal Plexuses
All are interconnected

All parasympathetic comes from vagus nerves

1. Celiac plexus
Sym- Greater, lesser and least splanchnic nerves
Celiac, aorticorenal, superior mesenteric ganglia

2. Superior mesenteric plexus
Sym- Least splanchnic nerves
Superior mesenteric ganglia

3. Inferior mesenteric plexus
Sym- lumbar splanchnic nerve
Inferior mesenteric ganglia

Sympathetic activity- vasoconstriction
Parasympathetic activity- vasodilation
Gray’s Basic Anatomy, Drake et al., 2018
 LO 6
LO 4
Hypogastric Plexuses

Innervate viscera within pelvic region

Postganglionic sympathetic axons from
lumbar and sacral splanchnic nerves
Preganglionic parasympathetic axons
from pelvic splanchnic nerve

Sympathetic activity- vasoconstriction,
contraction of muscles (sphincter of
bladder, anus), ejaculation, remission of
erection
Parasympathetic activity- vasodilation,
relaxation of muscles (sphincter of
bladder, anus), engorgement of erectile
tissue

Gray’s Basic Anatomy, Drake et al., 2018
 LO 5

Enteric System
Postganglionic parasympathetic
motor neurons of the GI tract
More function than just receiving
and passing on input from
preganglionic fibers

“Second brain”- “due to its
complexity, integrative function,
and ability to function
autonomously, without connection
to the CNS”

Gray’s Basic Anatomy, Drake et al., 2018
Plexus Sympathetic (thoracolumbar) Input Parasympathetic Result LO 4
(craniosacral) Input
Cardiac Spinal levels: Brainstem level/nuclei: S: __________ heart rate and
strength of contraction

Sympathetic trunk ganglia: Cranial nerve: CN __
P: ___________ heart rate and
strength of contraction
Splanchnic nerve:

Pulmonary Spinal levels: Brainstem level/nuclei: S: Broncho_________, decrease
secretions

Sympathetic trunk: Cranial nerve: CN __
P: Broncho___________,
increase secretion
Splanchnic nerve:

Esophageal None Brainstem level/nuclei: S: None

P: Control of stomach sphincter,
Cranial nerve: CN __
Plexus Sympathetic (thoracolumbar) Input Parasympathetic (craniosacral) Result LO 4
Input

Abdominal Spinal levels: T5-L2 Brainstem level/nuclei: S: Primarily vaso____________
_____________ digestive
(solitary nucleus receives visceral afferent secretions
form organs)

Cranial nerve: CN __
P: Primairly vaso_____________,
_____________ digestive
secretions
Celiac plexus

___________ splanchnic - celiac ganglia

_______ splanchnic- aorticorenal ganglia

_______ splanchnic- superior mesenteric ganglia
Superior mesenteric plexus

_______ splanchnic- superior mesenteric ganglia

Inferior mesenteric plexus

_______ splanchnic- inferior mesenteric ganglia
Plexus Sympathetic (thoracolumbar) Input Parasympathetic (craniosacral) Result
LO 4
Input

Hypogastric Spinal levels: L1- L2 Spinal levels: S:
Urinary:
Superior and Splanchnic nerve and prevertebral ganglion:
inferior
_________ splanchnic nerve- _________ Digestive:
_____________ ganglion Splanchnic nerve:
P______ splanchnic nerve
Sacral splanchnic nerve External genitalia:

P:
Urinary:

Digestive:

External genitalia:
Autonomic Reflexes
 LO 6
Autonomic or
Visceral Reflexes
Helps maintain homeostasis

Smooth muscle contractions, cardiac
muscle contractions, secretions by glands
that are responses to specific stimuli

Information about distension, blood gas,
blood pressure levels from hollow organs
or blood vessels

E.g., Respiratory movement of the
diaphragm is controlled mostly by reflexes
stimulated by levels of oxygen and carbon
dioxide in blood
Clinically Oriented Anatomy, Moore et al., 2018
Visceral Sensation
 LO 7
Visceral Sensation
Visceral afferent fibers provide information With local anesthesia, visceral organs
about the condition of the body’s internal can by handles, cut, clamped, or
environment
cauterized without causing pain
Mostly unconscious
Conscious sensation is usually perceived
as poorly localized pain (e.g., cramps,
Integrated in the CNS, triggered by visceral fullness, nausea, hunger)
and/or somatic reflexes which regulate
blood pressure and chemistry by altering Pain may be caused by
function of target organs (e.g., heart rate)
Sudden distension
Spasms or strong contractions
Most visceral reflex sensations travel with Chemical irritants
parasympathetic fibers (but in opposite Mechanical stimulation (when organ is
direction)
active)
Pathological conditions, especially those
Most visceral pain impulses travel along-side causing ischemia (inadequate blood supply)
with sympathetic fibers Why is this important?
Parasympathetic Histology
 LO 8
Histology- Parasympathetic
Parasympathetic ganglia
Neurons
Parasympathetic Intramural LO 8

Ganglia Histology
a. Intramural parasympathetic
ganglion
b. Neuron cell bodies
c. Satellite cells

Gray’s Basic Anatomy, Drake et al., 2018
Vagus Nerve LO 9
 LO 9
1

Abdominal Plexuses
2

1. Celiac plexus and ganglia
3

2. Superior mesenteric plexus and
ganglia

3. Inferior mesenteric plexuses and
ganglia
 LO 9

Hypogastric Plexuses

1. Superior hypogastric plexus

2. Inferior hypogastric plexus 1

2