Introduction to Autonomic Nervous system
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Nov 30, 2019
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About This Presentation
Lecture intends to give a brief overview of autonomic nervous system.
it includes the anatomical distribution of ANS, Neurohumoral transmission, co-transmission, receptors for ANS and synthesis of the neurotransmitters, Acetylcholine and Catecholamines
Slide Content
INTRODUCTION TO AUTONOMIC
NERVOUS SYSTEM
DR NASER ASHRAF TADVI
NERVOUS SYSTEM
DR NASER ASHRAF TADVI
OBJECTIVES
•Describe distribution of ANS
•Enlist differences between ANS and PNS
•Describe Neurohumoral transmission
•Enlist main neurotransmitter for Sympathetic and
Parasympathetic NS
•Enlist receptors for Sympathetic and Parasympathetic nervous
system
•Briefly describe the synthesis of Acetyl choline and
Catecholamines
•Describe distribution of ANS
•Enlist differences between ANS and PNS
•Describe Neurohumoral transmission
•Enlist main neurotransmitter for Sympathetic and
Parasympathetic NS
•Enlist receptors for Sympathetic and Parasympathetic nervous
system
•Briefly describe the synthesis of Acetyl choline and
Catecholamines
Introduction to ANS
•Peripheral nervous system is divided into
–Somatic nervous system (SNS)
–Autonomic nervous system (ANS)
•Peripheral nervous system is divided into
–Somatic nervous system (SNS)
–Autonomic nervous system (ANS)
Differences between Somatic and
autonomic nervous system
Somatic Autonomic
1Organ supplied Skeletal Muscles All other organs
2Distal most synapse Within CNS Outside CNS (in
ganglia)
3Nerve fibers Myelinated Preganglionic
Myelinated
Post Ganglionic
Non myelinated
4Peripheral plexus formation Absent Present
5Primary efferent transmitter Acetylcholine(Ach)Ach, Noradrenaline
6Effect of nerve section on
organ supplied
Paralysis &
atrophy
Activity maintained,
no atrophy
autonomic nervous system
Somatic Autonomic
1Organ supplied Skeletal Muscles All other organs
2Distal most synapse Within CNS Outside CNS (in
ganglia)
3Nerve fibers Myelinated Preganglionic
Myelinated
Post Ganglionic
Non myelinated
4Peripheral plexus formation Absent Present
5Primary efferent transmitter Acetylcholine(Ach)Ach, Noradrenaline
6Effect of nerve section on
organ supplied
Paralysis &
atrophy
Activity maintained,
no atrophy
Autonomic innervation
Distribution of parasympathetic nervous system
Distribution of Sympathetic nervous system
ANS FIBRES
Afferents
Efferent
Sympathetic nervous system
Para sympathetic nervous system
•Origin:thoraco lumbar (lateral
horns) outflow C
8to L
2/L
3
•Ganglia –paravertebral (22 pairs)
•Prevertebral (coeliac,
superior & inferior mesentric
& aortorenal)
•Adrenal medulla
•Terminal (u. bladder, rectum)
•Cranio sacral
•Midbrain –3
rd
•Medulla –7,9,10
Sacral–2,3,4, (nervi
erigentis)
•terminal near/with in
innervated tissue.
Afferents
Efferent
Sympathetic nervous system
Para sympathetic nervous system
•Origin:thoraco lumbar (lateral
horns) outflow C
8to L
2/L
3
•Ganglia –paravertebral (22 pairs)
•Prevertebral (coeliac,
superior & inferior mesentric
& aortorenal)
•Adrenal medulla
•Terminal (u. bladder, rectum)
•Cranio sacral
•Midbrain –3
rd
•Medulla –7,9,10
Sacral–2,3,4, (nervi
erigentis)
•terminal near/with in
innervated tissue.
•Symp n. system
•Neurotansmitter
•PSNS
•Neurotansmitter
Nonadrenaline/
ADR
Acetyl
choline
•Function:prepare body
for fight
Acetyl choline
Acetyl choline
•Tissue building reaction
•Neurotansmitter
•PSNS
•Neurotansmitter
Nonadrenaline/
ADR
Acetyl
choline
•Function:prepare body
for fight
Acetyl choline
Acetyl choline
•Tissue building reaction
Differences between sympathetic &
parasympathetic
Features Sympathetic Parasympathetic
1Origin From CNS Thoracolumbar
segments of spinal cord
(T1-T12, L1-L3)
Craniosacral regions (Cranial
nerves 3, 7,9,10 & sacral
segments of spinal cord S 2,3,4)
2Preganglionic
fiber
Short Myelinated Long Myelinated
3Ganglia Located away from the
organs of innervation
Located very close to organs of
innervation
4Post ganglionic
Fiber
Long non myelinated Short non myelinated
5Response to
stimulation
Diffused or generalized Localized reaction
6 Neurotransmitter
Preganglionic
Post Ganglionic
Acetylcholine
Noradrenaline
Acetylcholine
Acetylcholine
7Important
function
Tackling stress and
Emergency
Assimilation of food and
conservation of energy
parasympathetic
Features Sympathetic Parasympathetic
1Origin From CNS Thoracolumbar
segments of spinal cord
(T1-T12, L1-L3)
Craniosacral regions (Cranial
nerves 3, 7,9,10 & sacral
segments of spinal cord S 2,3,4)
2Preganglionic
fiber
Short Myelinated Long Myelinated
3Ganglia Located away from the
organs of innervation
Located very close to organs of
innervation
4Post ganglionic
Fiber
Long non myelinated Short non myelinated
5Response to
stimulation
Diffused or generalized Localized reaction
6 Neurotransmitter
Preganglionic
Post Ganglionic
Acetylcholine
Noradrenaline
Acetylcholine
Acetylcholine
7Important
function
Tackling stress and
Emergency
Assimilation of food and
conservation of energy
Neurohumoral transmission
Mechanisms of
termination of
neurotransmitter
action
termination of
neurotransmitter
action
Co-transmission
Examples of co-transmitters
•Purines : ATP, Adenosine
•VIP, NPY
•Substance P, enkephalins
•Somatostatin
•Nitric oxide
Examples of co-transmitters
•Purines : ATP, Adenosine
•VIP, NPY
•Substance P, enkephalins
•Somatostatin
•Nitric oxide
Synthesis of catechol amines
Synthesis of acetyl choline
Cholinergic receptors
Nicotinic
Muscarinic
NM
(Skeletal
muscle)
NN
(Ganglia)
M
1
•CNS
•GASTRIC
SECRETION
M
2
Heart
M
3
Smooth muscle
& Gland
secretion
Nicotinic
Muscarinic
NM
(Skeletal
muscle)
NN
(Ganglia)
M
1
•CNS
•GASTRIC
SECRETION
M
2
Heart
M
3
Smooth muscle
& Gland
secretion
Adrenergic receptors
Important terminology
•Sympathomimetic (Adrenergic)
•Sympatholytic (Antiadrenergic)
•Parasympathomimetic (Cholinergic)
•Parasympatholytic (Anticholinergic)
•Sympathomimetic (Adrenergic)
•Sympatholytic (Antiadrenergic)
•Parasympathomimetic (Cholinergic)
•Parasympatholytic (Anticholinergic)
Summary
•Distribution
•Neurohumoral transmission
•Main neurotransmitters
•Main receptors
•Distribution
•Neurohumoral transmission
•Main neurotransmitters
•Main receptors
Which of the following is correct regarding the autonomic
nervous system (ANS)?
A. Afferent neurons carry signals from the CNS to the
effector organs.
B. The neurotransmitter at the parasympathetic ganglion is
norepinephrine (NE).
C. The neurotransmitter at the sympathetic ganglion is
acetylcholine (ACh).
D. Sympathetic neurons release AChin the effector organs.
E. Parasympathetic neurons release NE in the effector
organs.
nervous system (ANS)?
A. Afferent neurons carry signals from the CNS to the
effector organs.
B. The neurotransmitter at the parasympathetic ganglion is
norepinephrine (NE).
C. The neurotransmitter at the sympathetic ganglion is
acetylcholine (ACh).
D. Sympathetic neurons release AChin the effector organs.
E. Parasympathetic neurons release NE in the effector
organs.
Which of the following is correct regarding
somatic motor neurons?
A.The neurotransmitter at the somatic motor
neuron ganglion is acetylcholine.
B.The neurotransmitter at the somatic motor
neuron ganglion is norepinephrine.
C.Somatic motor neurons innervate smooth
muscles.
D.Somatic motor neurons do not have ganglia.
E.Responses in the somatic motor neurons are
generally slower than in the autonomic nervous
system.
somatic motor neurons?
A.The neurotransmitter at the somatic motor
neuron ganglion is acetylcholine.
B.The neurotransmitter at the somatic motor
neuron ganglion is norepinephrine.
C.Somatic motor neurons innervate smooth
muscles.
D.Somatic motor neurons do not have ganglia.
E.Responses in the somatic motor neurons are
generally slower than in the autonomic nervous
system.
Which of the following physiological changes could happen
when a person is attacked by a dog?
A.Increase in heart rate.
B.Increase in lacrimation (tears).
C.Constriction of the pupil (miosis).
D.Increase in gastric motility.
when a person is attacked by a dog?
A.Increase in heart rate.
B.Increase in lacrimation (tears).
C.Constriction of the pupil (miosis).
D.Increase in gastric motility.
A.Reduction in heart rate.
B.Constriction of the pupil (miosis).
C.Increase in gastric motility.
D.Dry mouth (xerostomia).
E.Contraction of detrusor muscle in the
bladder.
Which of the following changes could theoretically
happen in a person when the parasympathetic
system is inhibited using a pharmacological agent?
B.Constriction of the pupil (miosis).
C.Increase in gastric motility.
D.Dry mouth (xerostomia).
E.Contraction of detrusor muscle in the
bladder.
Which of the following changes could theoretically
happen in a person when the parasympathetic
system is inhibited using a pharmacological agent?
Which of the following is correct regarding
neurotransmitters and neurotransmission?
A.Neurotransmitters are released from the
presynaptic nerve terminals.
B.Neurotransmitter release is triggered by the
arrival of action potentials in the postsynaptic
cell.
C.Intracellular calcium levels drop in the neuron
before the neurotransmitter is released.
D.Serotonin and dopamine are the primary
neurotransmitters in the ANS.
neurotransmitters and neurotransmission?
A.Neurotransmitters are released from the
presynaptic nerve terminals.
B.Neurotransmitter release is triggered by the
arrival of action potentials in the postsynaptic
cell.
C.Intracellular calcium levels drop in the neuron
before the neurotransmitter is released.
D.Serotonin and dopamine are the primary
neurotransmitters in the ANS.
All of the following statements regarding central
control of autonomic functions are correct except
A.Baroreceptors are pressure sensors located
at various cardiovascular sites.
B.The parasympathetic system is activated by
the CNS in response to a sudden drop in
blood pressure.
C.The parasympathetic system is activated by
the CNS in response to a sudden increase
in blood pressure.
D.The sympathetic system is activated by the
CNS in response to a sudden drop in blood
pressure.
control of autonomic functions are correct except
A.Baroreceptors are pressure sensors located
at various cardiovascular sites.
B.The parasympathetic system is activated by
the CNS in response to a sudden drop in
blood pressure.
C.The parasympathetic system is activated by
the CNS in response to a sudden increase
in blood pressure.
D.The sympathetic system is activated by the
CNS in response to a sudden drop in blood
pressure.
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