Nervous System Physiology 2024 PDF

Summary

This document provides an overview of nervous system physiology, including the various components of the nervous system, such as the two anatomical divisions, central and peripheral nervous systems, functions of the brain lobes, etc. The document also touches upon related topics, such as neurological levels, and different types of nerve pathways.

Full Transcript

Nervous System 2024
Nervous System 2024
 The Nervous System

Two Organ Systems Control All the
Other Organ Systems.
– Nervous system characteristics
Rapid response
Brief duration
– Endocrine system characteristics
Slower response
Long duration
 01Nervous Sysytem
https://www.youtube.com/watch?v=44B0ms3XPKU
 The Nervous system
The nervous system is a complicated web of
nerve fibers and cells that run to and from the
brain and spinal cord throughout the body.
It innervates every organ in the body and is
responsible for carrying messages to the brain
to be interpreted.
 Facts About The Nervous System
The more we learn, the more electrical
connections are generated in our brains.
These connections help in establishing
memory, and the more they are reinforced,
the stronger the memory. As they say practice
makes perfect!
electrical impulses that flow through neurons
and nerve cells are conducted by the flow of
tiny chemical.
 Facts About The Nervous System
In total there are 43 pairs of nerves in the peripheral
nervous system, 12 pairs are connected directly with
the brain, and 31 pairs are connected to the spinal
cord.
The connections between neurons in the brain create a
network that resembles a Spider web!
It is a myth that humans use only 10% of their brain!
only 4% of the cells are active and involved in electrical
impulse generation and transmission. The rest of the
cells are in a dormant or resting phase.
 Convolutional Neural Network
(CNN)
Convolutional Neural Network (CNN) is a type
of Deep Learning neural network architecture
commonly used in Computer Vision.
Computer vision is a field of Artificial
Intelligence that enables a computer to
understand and interpret the image or visual
data.
CNN
FOUR PRIMARY FUNCTIONS OF NERVOUS
SYSTEM
1. Sensing the world
 Vision, Hearing, Smell, Taste, Touch
2. Transmitting information
3. Processing information
4. Producing a response
 The Nervous System
Two Anatomical Divisions
– Central nervous system (CNS)
Brain
Spinal cord
– Peripheral nervous system (PNS)
All the neural tissue outside CNS
Afferent division (sensory input)
Efferent division (motor output)
– Somatic nervous system
– Autonomic nervous system

Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings
 Neural Tissue Organization
Anatomic Organization of CNS Neurons
– White matter—Bundles of axons (tracts) that
share origins, destinations, and functions
Anatomic Organization of PNS Neurons
– Ganglia—Groupings of neuron cell bodies
– Nerve—Bundle of axons supported by connective
tissue
Spinal nerves
–To/from spinal cord
Cranial nerves
–To/from brain
Organization of the Nervous System
 Components of the Nervous System
Central Nervous System
– Brain
– Spinal Cord
Peripheral Nervous System
– Sensory and Motor Nerves
– Cranial Nerves
– Spinal Nerves
 02Brain
https://www.youtube.com/watch?v=HVGlfcP3ATI
 The Human Brain
Complex
1.4 kg in weight
Pre frontal cortex
2% of body weight
20% of oxygen
15% of our cardiac input
10% of all energy
 Functions of Brain

Functions of the brain: Major parts of the brain:
Interprets sensations Cerebrum
Determines perception Frontal lobes
Stores memory Parietal lobes
Reasoning Occipital lobes
Makes decisions Temporal lobes
Coordinates muscular movements Insula
Regulates visceral activities Cerebellum
Determines personality Brainstem
Midbrain
Pons
Medulla oblongata
19
 Large front part of the brain
FUNCTIONS:
– Voluntary activity
– Memory
– Language
– Receives and responds to sensory signals
– Controls motor functions
The Central Nervous
Brain Waves
System
(Electroencephalogram)
 Cerebral Cortex
Three kinds of functional areas
Motor areas: movement

Sensory areas: perception

Association areas: integrate
diverse information to enable
purposeful action
 The Cerebrum

Controls conscious
activities, intelligence,
memory, language,
muscles.
Wrinkled with countless
folds and grooves and
covered with an outer
layer of gray matter
called the cerebral
cortex.
Divided into 4 lobes
 Frontal lobe
Personality, behavior, emotions
Judgment, planning, problem solving
Speech: speaking and writing (Broca’s area)
Body movement (motor strip)
Intelligence, concentration, self awareness
 Parietal lobe
Interprets language, words
Sense of touch, pain, temperature (sensory
strip)
Interprets signals from vision, hearing, motor,
sensory and memory
Spatial and visual perception
 Occipital lobe
Interprets vision (color, light, movement)
 Temporal lobe
Understanding language (Wernicke’s area)
Memory
Hearing
Sequencing and organization
 Basal Nuclei

Also called basal ganglia Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Masses of gray matter Longitudinal
fissure

deep within cerebral Caudate Right cerebral
hemisphere
hemispheres
nucleus
Basal Putamen
nuclei

Caudate nucleus, Globus
pallidus

putamen, and globus
pallidus Thalamus
Cerebellum

Produce dopamine Hypothalamus

Brainstem
Control certain muscular Spinal cord

activities
Primarily by
inhibiting motor
functions 28
 Thalamus
Gateway for sensory impulses heading to cerebral cortex
Receives all sensory impulses (except smell)
Channels impulses to appropriate part of cerebral cortex for
interpretation
Hypothalamus
Maintains homeostasis by regulating visceral activities
Links nervous and endocrine systems (hence some say the
neuroendocrine system

29
 The Central Nervous System
What are the Functions of the Hypothalamus?
– Produce emotions and behavioral drives
– Coordinate nervous and endocrine systems
– Secrete hormones
– Coordinate voluntary and autonomic functions
– Regulate body temperature

Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings
 Hypothalamus

Control of endocrine
system through
pituitary gland
 Hypothalamus
Main visceral control center
– Autonomic nervous system (peripheral motor neurons
controlling smooth and cardiac muscle and gland
secretions): heart rate, blood pressure, gastrointestinal
tract, sweat and salivary glands, etc.
– Emotional responses (pleasure, rage, sex drive, fear)
– Body temp, hunger, thirst sensations
– Some behaviors
– Regulation of sleep-wake centers: circadian rhythm
(receives info on light/dark cycles from optic nerve)
– Control of endocrine system through pituitary gland
– Involved, with other sites, in formation of memory
 Smaller part of the brain ,towards the
back

FUNCTIONS:

Coordinates all movement
Helps maintain posture, muscle control,
and balance
 Cerebellum
Receives messages from
most of the muscles in
your body
The cerebellum is most
directly involved in
coordinating voluntary
movements. It is also
responsible for a number
of functions including
motor skills such as
balance, coordination,
and posture.
 03BrainStem
https://www.youtube.com/watch?v=dEgaaJWRf7g
 Brainstem
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Hypothalamus

Three parts: Thalamus
Diencephalon

1. Midbrain
2. Pons Corpus
callosum
3. Medulla Oblongata

Corpora
quadrigemina

Midbrain
Cerebral
aqueduct
Pons

Reticular
formation
Medulla
oblongata Spinal cord
36
 Brain Stem
 The brainstem controls several important functions of
the body including:
 Alertness
 Arousal
 Breathing
 Blood Pressure
 Digestion
 Heart Rate
 Other Autonomic Functions
 Relays Information Between the Peripheral Nerves
and Spinal Cord to the Upper Parts of the Brain
 Pons
Regulates breathing.
In addition, the pons is involved in the
transmission of signals to and from other
structures in the brain, such as the cerebrum
or the cerebellum.
The pons is also involved in sensations such
as hearing, taste, and balance.
Finally, the pons is also involved in the
regulation of deep sleep.
 Medulla Oblongata
The medulla oblongata is located in the lower
portion of the brainstem. It is very important
in things like heart rate and blood pressure.
It's responsible for many reflexes in the body,
or involuntarily controls, such as vomiting,
sneezing, and coughing.
 Cerebrospinal Fluid
CSF
Made in choroid plexuses (roofs of ventricles)
Cushions and nourishes brain
Cerebrospinal fluid (CSF) is a clear, colorless body
fluid found within the tissue that surrounds the
brain and spinal cord of all vertebrates.
Cerebrospinal fluid. The cerebrospinal fluid
circulates in the subarachnoid space around the
brain and spinal cord, and in the ventricles of the
brain.
 CSF circulation: through ventricles, median and lateral
apertures, subarachnoid space, arachnoid villi, and into the
blood of the superior sagittal sinus

CSF:
-Made in choroid plexus
-Drained through arachnoid villus
 Blood-Brain Barrier

Tight junctions between endothelial cells of
brain capillaries, instead of the usual
permeability
Highly selective transport mechanisms
Allows nutrients, O2, CO2
Not a barrier against uncharged and lipid
soluble molecules; allows alcohol, nicotine,
and some drugs including anesthetics
 04Blood-Brain Barrier
https://www.youtube.com/watch?v=e9sN9gOEdG4
 Memory
How humans form memories is poorly
understood.
“Working memory” appears to be distinct
from long-term memory. There may be
short-term memory as well, things
remembered for a few days. Is this because
the memory disappears, or because it
cannot be retrieved?
Models of Memory
Models of Memory

Craik & Lockhart, 1972
47
 Peripheral Nervous System

Cranial nerves arising from the brain
Somatic fibers connecting to the skin and skeletal muscles
Autonomic fibers connecting to viscera

Spinal nerves arising from the spinal cord
Somatic fibers connecting to the skin and skeletal muscles
Autonomic fibers connecting to viscera

48
 Peripheral Nervous System

Sensory (Afferent)
– convey impulses from sensory receptors to CNS
– Afferent (sensory) neurons

Motor (Efferent)
– convey impulses away from CNS to periphery
– Efferent (motor) neurons
 Peripheral Nervous System
Nerves are either motor nerves or sensory
nerves.
– Efferent or motor nerves innervate muscles and
glands. In order to accomplish this, they conduct
nerve impulses from the CNS to the muscles and
glands.
– Afferent or sensory nerves send sensory
information and nerve impulses from sensory
receptors in the skin, muscles, and joints to the
brain.
Structure of a Peripheral Nerve
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Fascicle
Peripheral nerve

Epineurium

Motor neuron
ending
Axon

Perineurium
Endoneurium
Node of Ranvier
Schwann cell Sensory receptor
Myelin sheath
Neurilemma
 04Neuron
https://www.youtube.com/watch?v=6qS83wD29PY
 05What are neurons and how do they work
https://www.youtube.com/watch?v=FcMK7qLQ07k
 The Neuron
Dendrites receive
signals.
The cell body
integrates signals.
The axon transmits
action potential.
The myelin sheath
makes the signal
travel faster.
Synaptic terminals
transmit signals.
 06How Neurotransmission Works
https://www.youtube.com/watch?v=p5zFgT4aofA
 Neurotransmitters
There are two kinds of neurotransmitters –
INHIBITORY and EXCITATORY.
stimulate the brain
calm the brain
 Neurotransmitters
Acetylcholine (ACh)
Norepinephrine (NE)( also known as
noradrenaline)
Dopamine(D)
Serotonin (5HT)
Glutamate
Gamma-aminobutyric acid (GABA)
 Acetylcholine (Ach)
Cholinergic pathways
thought to be involved in
cognition (esp. memory) and our
sleep/wake cycle
parasympathetic nervous system
regulating bodily functions such as
heart rate, digestion, secretion of
saliva and bladder function
Alzheimer’s disease and
myathesia gravis (weakness of
skeletal muscles)
Anti-cholinergic effects
 07Acetyl Choline
https://www.youtube.com/watch?v=yPq8qDaj184
 Norepinephrine (NE)
attention, alertness and
arousal
NE levels fluctuate with
sleep and wakefulness and
changes in attention and
vigilance
mood, affective states and
anxiety
antidepressant
 Dopamine(D)
complex movement and
cognition
Emotional responses such as
euphoria or pleasure (seen in
amphetamine/cocaine use).
Significant role in motor
control
 Great influences on
Serotonin (5HT)
behaviour.
Low serotonin activity is
associated with aggression,
suicide, impulsive eating
and disinhibited sexual
behaviour
particularly the onset of
sleep
depression and anxiety
disorders delusions,
hallucinations (LSD)
negative symptoms of
schizophrenia
 Glutamate
Glutamate is found in all cells of the body
control the opening of ion channels that allow
calcium to pass into nerve cells producing
impulses
Blocking of glutamate receptors produces ( eg.
By PCP) schizophrenic like symptoms
Over exposure of neurons to glutamate cause
cell death seen in stroke and Huntington’s
disease (PN).
 Gamma-aminobutyric acid (GABA)

Inhibitory and its pathways are only found
within the CNS.
control excitatory neurotransmitters in the
brain and controlling spinal and cerebral
reflexes.
anxiety disorders
decreased GABA can lead to seizure activity
Benzodiazepines and barbiturates sedative
medication act on GABA
 Synapse
Neurons usually do
not connect directly
to one another. A
gap called a synapse
controls the
transmission of
signals.
Neurotransmitters
cross the synapse
and stimulate the
next neuron.
 Electrical Transmission
The Information that flows in the neurone
Approximately 10 billion neurons are responsible
for receiving, organising and transmitting
information in the central nervous system
Ions in the intracellular fluid (inside the cell) have
a negative charge
Ions in extracellular fluid (outside the cell) have a
positive charge attracting positively charged cells
(cations)
‘Potential difference’ between the inside and the
outside of the cell
 08Electrical Transmission
https://www.youtube.com/watch?v=b2ctEsGEpe0
 Ions are sodium, potassium, calcium and
chloride
‘voltage gated’
Resting Potential vs. Action potential
 Chemical Neurotransmission
The flow of neurotransmitter across the
synapse
Neurotransmitter;
– Made in the pre synaptic neurone
– Stored inactively in synaptic vesicles
– Released from the synaptic vesicles into the synapse
– Binds to receptors
– Binds to reuptake transporters to be taken back into the
neurone
– Is degraded by specific enzymes
 Resting potential
 Using active
transport, the
neuron moves
Na+ ions to the
outside of the
cell and K+ ions
to the inside of
the cell.
 Large molecules
in the cell
maintain a
negative charge.
 Action potential
 On receiving a
stimulus, sodium
gates and potassium
channels open
briefly, allowing these
ions to diffuse.
 The gates close, and
active transport
restores the resting
potential.
 09Action Potential Explained
https://www.youtube.com/watch?v=ZAmUjvgoO0A
 Nerve Impulse
A change in charge that travels as a wave
along the membrane of a neuron
Called an action potential
Depends on the movement of sodium ions
(Na+) and potassium ions (K+) between the
interstitial fluid and the inside of the
neuron.
 Resting Potential
Sodium ions are in large concentration along the
outside of the cell membrane
Potassium ions are in large concentration along
the inside of the cell membrane

Human Anatomy, 3rd edition
Prentice Hall, © 2001
 Beginning of a Nerve Impulse

Requires a stimulus of adequate strength
Membrane is irritable
– Neuron may respond to a stimulus and convert it
to an impulse.
When?
– If above threshold
 Starting
Depolarization –a a Nerve Impulse
stimulus depolarizes
the neuron’s
membrane
A depolarized
membrane allows
sodium (Na+) to flow
inside the membrane
The exchange of ions
initiates an action
potential in the
neuron
Marieb, Essentials of Human Anatomy and Physiology, 8th edition, 2006
 If the action The Action Potential
potential starts, it
is propogated over
the entire axon
Potassium ions
rush out of the
neuron after
sodium ions rush in
– Repolarizes the
membrane

http://faculty.clintoncc.suny.edu/faculty/Michael.Gregory/files/Bio%20102/Bio%20102%20lectures/nervous%20system/neuron6.gif
 Return to Resting Potential
Sodium-potassium
pump restores original
configuration
– Requires ATP

http://faculty.clintoncc.suny.edu/faculty/Michael.Gregory/files/Bio%20102/Bio%20102%20lectures/nervous%20system/neuron6.gif
 Nerve Impulse Propagation
The impulse continues
to move away from
the cell body
Impulses travel faster
when fibers have a
myelin sheath

Marieb, Essentials of Human Anatomy and Physiology, 8th edition, 2006
 Continuation of the Nerve Impulse
Impulses are ableBetween Neurons
to cross a synapse to another nerve
– Neurotransmitter is
released from
the axon terminal
(synaptic knob) into
synaptic cleft
– The dendrite of the
next neuron has
receptors that are
stimulated by the
neurotransmitter

Marieb, Essentials of Human Anatomy and Physiology, 8th edition, 2006
 Synaptic Cleft

Marieb, Essentials of Human Anatomy and Physiology, 8th edition, 2006
Postsynaptic Membrane Receptor

Marieb, Essentials of Human Anatomy and Physiology, 8th edition, 2006
 Synapse

Human Anatomy, 3rd edition
Prentice Hall, © 2001
Section 35-3

The Nervous
System

is divided into

Central nervous Peripheral nervous
system system

Motor nerves which consists of Sensory nerves

that make up

Somatic nervous Autonomic nervous
system system

which is divided into

Sympathetic Parasympathetic
nervous system nervous system
 The Peripheral Nervous System
The 12 pairs of cranial nerves are responsible
for the special senses of smell, sight, and
hearing/balance, and control movement of
the eye, jaw, face, tongue, and muscles of the
neck, back, and shoulders. They also provide
sensation from the face, neck, and upper chest
and autonomic innervation to thoracic and
abdominopelvic organs.
The Peripheral Nervous
The Cranial Nerves System
Peripheral nervous system…
The network of nerves
branching out throughout
the body from the brain
and spinal cord is called the
peripheral nervous system.
In addition to the 31 pairs
of spinal nerves mentioned
in the slides on the spinal
cord, there are 12 pairs of
cranial nerves that attach
to the brain:
I. The olfactory nerve
carries sensory input for
smell
Peripheral nervous system…
II. The optic nerve carries
sensory input for vision
III. The oculomotor nerve
controls muscles of the
eye and eyelid
IV. The trochlear nerve
controls the eyeball
V. The trigeminal nerve
controls the face, nose,
mouth, forehead, top of
head, and jaw. VI. The abducens
nerve (ab DŪ senz)
also controls the
eyeball
Peripheral nervous system…
VII. The facial nerve
controls muscles
of the face and
scalp, and part of
the tongue for
sense of taste.
VIII. The auditory or
cochlear nerve
provides sensory
input for hearing and equilibrium.
IX. The glossopharyngeal
nerve controls saliva, swallowing, and taste.
Peripheral nervous system…
X. The vagus nerve is the
longest cranial nerve,
extending to and controlling
the heart, lungs, stomach,
and intestines.
XI. The accessory nerve permits
movement of the head and
shoulders.
XII.The hypoglassal nerve
controls the muscles of the
tongue.
 Cranial Nerve
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Superior ganglion
Vagus nerve (X) Meningeal branch
Auricular branch
of vagus nerve

Pharyngeal branch Inferior ganglion
Mixed nerve Palate of vagus nerve
Nerve XI
Somatic motor to muscles Superior laryngeal
nerve
Nerve XII

of speech and swallowing Carotid body

Autonomic motor to Recurrent laryngeal
Left vagus
nerve
viscera of thorax and nerve
Cardiac nerves
abdomen Lung

Sensory from pharynx, Heart

larynx, esophagus, and
viscera of thorax and Liver
Stomach

abdomen Spleen

Pancreas

Kidney
Small
intestine

Large intestine
94
 Peripheral Nervous System
Spinal Nerves – there are 31 pairs of spinal
nerves branching off the spinal cord.
– 8 cervical
– 12 thoracic
– 5 lumbar
– 5 sacral
– 1 coccygeal
 Dermatomes
The surface of the skin is divided into specific
areas called dermatomes
There are 31 segments of the spinal cord, each
with a pair (right and left) of ventral (anterior)
and dorsal (posterior) nerve roots that
innervate motor and sensory function,
respectively. The anterior and posterior nerve
roots combine on each side to form the spinal
nerves as they exit the vertebral canal through
the intervertebral foramina or neuroforamina.
 Dermatomes
The 31 spine segments on each side give rise
to 31 spinal nerves, which are composed of 8
cervical, 12 thoracic, 5 lumbar, 5 sacral, and 1
coccygeal spinal nerve.
Dermatomes exist for each of these spinal
nerves, except the first cervical spinal nerve.
Sensory information from a specific
dermatome is transmitted by the sensory
nerve fibers to the spinal nerve of a specific
segment of the spinal cord.
 Clinical significance
Dermatomes are useful to help localize
neurologic levels, particularly in radiculopathy.
Effacement or encroachment of a spinal nerve
may or may not exhibit symptoms in the
dermatomic area covered by the compressed
nerve roots in addition to weakness, or deep
tendon reflex loss.
Innervation of the
skin:
dermatomes-
each spinal
nerves
innervates a
skin zone
 Motor Component

Somatic Nervous System (Voluntary)
– conduct impulses from CNS to skeletal muscles

Autonomic Nervous System (Involuntary)
– convey impulses from CNS to smooth muscle,
cardiac muscle and glands
 The Peripheral Nervous System
Nerve Plexus
—A complex,
interwoven
network of nerves

Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings
 The
Peripheral
Peripheral Nervous System
Nerves and
Nerve Plexuses
 The Peripheral Nervous System
Reflex—An automatic involuntary motor
response to a specific stimulus
 REFLEX ARC
https://www.youtube.com/watch?v=aaQWxko6qmk
 The Peripheral Nervous System
Reflex—An automatic involuntary motor
response to a specific stimulus
Arrival of
stimulus and
activation of
receptor

Stimulus
 Dorsal
Arrival of Activation of a root
stimulus and sensory neuron
activation of
receptor

Receptor
Stimulus

KEY
Sensory neuron
(stimulated)
 Dorsal Sensation
Arrival of Activation of a root relayed to
stimulus and sensory neuron the brain by
activation of collateral
receptor

Receptor
Stimulus

Information
processing
in CNS

KEY
Sensory neuron
(stimulated)
Excitatory
interneuron
 Dorsal Sensation
Arrival of Activation of a root relayed to
stimulus and sensory neuron the brain by
activation of collateral
receptor

REFLEX
Receptor ARC
Stimulus

Ventral
root Information
processing
in CNS
Activation of a
motor neuron
KEY
Sensory neuron
(stimulated)
Excitatory
interneuron
Motor neuron
(stimulated)
 Dorsal Sensation
Arrival of Activation of a root relayed to
stimulus and sensory neuron the brain by
activation of collateral
receptor

REFLEX
Receptor ARC
Stimulus

Effector Ventral
root Information
processing
in CNS
Response Activation of a
by effector motor neuron
KEY
Sensory neuron
(stimulated)
Excitatory
interneuron
Motor neuron
(stimulated)
Stretching of muscle tendon
stimulates muscle spindles
Muscle spindle
(stretch receptor)
Stretch

Spinal
cord
REFLEX
ARC

Contraction

Activation of motor
neuron produces reflex
muscle contraction
Stretching of muscle tendon
stimulates muscle spindles
Muscle spindle
(stretch receptor)
Stretch

Spinal
cord
Stretching of muscle tendon
stimulates muscle spindles
Muscle spindle
(stretch receptor)
Stretch

Spinal
cord
REFLEX
ARC

Contraction

Activation of motor
neuron produces reflex
muscle contraction

The Peripheral Nervous System
The Flexor Reflex, a Type of Withdrawal Reflex
Organization of Nervous
System
Nervous System

Central Nervous Peripheral
System Nervous
Brain & spinal
System
cord
Autonomic N.S. Somatic N.S.
 10Autonomic Nervous System – Physiology
https://www.youtube.com/watch?v=D96mSg2_h0c
 Autonomic Nervous System
2 divisions:
– Sympathetic
“Fight or flight”
“E” division
– Exercise,
excitement,
emergency, and
embarrassment
– Parasympathetic
“Rest and digest”
“D” division
– Digestion,
defecation, and
diuresis
 Peripheral Nervous System
Autonomic division of the nervous system can
be subdivided into 2 divisions:
(1) Parasympathetic
– Decreases heart rate, bronchiole dilation, blood
glucose, blood to skeletal muscle
– Increases digestion, pupil size, urinary output
– “rest and digest”
(2) Sympathetic
– Decreases digestion, pupil size, urinary output
– Increases heart rate, bronchiole dilation, blood
glucose, blood to skeletal muscle
– “fight or flight”
 Peripheral Nervous
System

PNS can be
subdivided into 2
divisions:
(1) Autonomic
– Cranial & spinal
nerves connecting
CNS to heart,
stomach, intestines,
glands
– Controls unconscious
activities
 Peripheral Nervous System
(2) Somatic
– Cranial & spinal nerves connecting CNS to
skin & skeletal muscles
– Oversees conscious activities
Adrenergic and Cholinergic Synaptic
Transmission
 Parasympathetic vs.
Sympathetic Divisions
 Sympathetic Effects

Fight, Fright or flight response
Release of Neurotransmitters (NT)-
Norepinephrine (NT) from
postganglionic fibers
Epinephrine (NT) from adrenal medulla
 Sympathetic Effects

Mass activation prepares for intense
activity
Heart rate (HR) increases
Bronchioles dilate
Blood [glucose] increases
 Sympathetic Effects

GI motility decreases
Contraction of sphincters
Relaxation of
Detrusor muscle
Ciliary muscle
Mydriasis
 Parasympathetic Effects
Normally not activated as a whole
Stimulation of separate parasympathetic
nerves.
Release ACh as NT
Relaxing effects-
Decreases HR.
Dilates visceral blood vessels.
Increases digestive activity.
 Parasympathetic Effects

Bronchonstriction
GI motility increases
Relaxation of sphincters
Contraction of
Detrusor muscle
Ciliary muscle
Miosis
Somatic Nervous System Structure

Single motor neuron cell
leading from the CNS
directly to the muscle
Cell body of motor
neurons located in CNS
The Autonomic Nervous System
What Is The Autonomic Nervous
System?
Branch of nervous system that
coordinates cardiovascular, digestive,
excretory, and reproductive functions
The Autonomic Nervous System
What are the Two Divisions of the ANS?
– Sympathetic division
“Fight or flight” system
– Parasympathetic division
“Rest and digest” system
The Autonomic Nervous System
The two divisions of the ANS operate
largely without our awareness. The
sympathetic division increases alertness,
metabolic rate, and muscular abilities; the
parasympathetic division reduces metabolic
rate and promotes visceral activities such as
digestion.
 The Autonomic Nervous System
The Somatic and
Autonomic Nervous
Systems
 The Autonomic Nervous System
The Somatic and
Autonomic Nervous
Systems

The Organization of
the Somatic and
Autonomic Nervous
System
The Autonomic Nervous System
The Sympathetic Division

Figure 8-34
The Autonomic Nervous System
What are the Effects of Sympathetic
Activation?
– Generalized response in crises
– Increased alertness
– Feeling of euphoria and energy
– Increased cardiovascular activity
– Increased respiratory activity
– Increased muscle tone
The Autonomic Nervous System
The Parasympathetic Division
The Autonomic Nervous System
What are the Effects of Parasympathetic
Activation?
– Relaxation
– Food processing
– Energy absorption
– Brief effects at specific sites
 Autonomic nervous System

Neurotransmitters of ANS
Neurotransmitters of sympathetic
nervous system

Neurotransmitters of parasympathetic
nervous system
Sympathetic Nervous System

Neurotransmitters at-
A. Preganglionic nerve endings
B. Postganglionic nerve endings
C. Target tissue
Sympathetic Nervous System

Neurotransmitters at-
A. Preganglionic nerve endings
 Acetylcholine (ACh)
B. Postganglionic nerve endings
 Norepinephrine (NE)
Sympathetic Nervous System

Neurotransmitters at-
Target tissue
Epinephrine (Ep)
Norepinephrine (NE)
Parasympathetic Nervous System

Neurotransmitters at-
A. Preganglionic nerve endings
 Acetylcholine (ACh)
B. Postganglionic nerve endings
 Acetylcholine (ACh)
Aging and the Nervous System
What are Age-Related Changes?
– Reduction in brain size and weight
– Loss of neurons
– Decreased brain blood flow
– Changes in synaptic organization of the brain
 Autonomic Nervous System (ANS)
The autonomic or involuntary nervous system
is that portion of the nervous system which
regulates the activity of cardiac muscle,
smooth muscle, and the glands.
The ANS has two parts:
– Sympathetic
– Parasympathetic
Comparison of autonomic and somatic motor systems- the motor unit of
autonomic system includes two motor neurons: preganglionic neuron
(myelinated) has an axon that synapses with the postganglionic neuron
(unmyelinated) in autonomic ganglion, then the axon of the postganglionic
neuron synapses with the viscera. A somatic motor unit contains one
myelinated axon per innervated muscle cell
 Autonomic Nervous System
Structure

Two neurons involved in
efferent pathway (CNS to
effector)
1rst (preganglionic) has cell
body in CNS
– synapses with 2nd in the
autonomic ganglion
2nd (postganglionic) sends
signal from auton. gang. to the
effector organ
11Autonomic Nervous System
https://www.youtube.com/watch?v=eeQ6c5nu-ck
 Autonomic Nervous System
Sympathetic – stimulates viscera
– Prepares the body for emergency situations (“fight
or flight” response to stress)
– Fear, emergency, physical exertion, and
embarrassment are responded to by this system
– This system shifts energy and blood toward the
skeletal muscles, cardiac muscles, and respiration
 Autonomic Nervous System
Parasympathetic – inhibits viscera
– Energy conservation system
– Restores body energy during rest
– Responses toward digestion, elimination of waste,
and decreases heart rate
Sympathetic and X Parasympathetic
Divisions

Sympathetic (thoracolumnar)
– dominates in stressful situations
– prepares body for activity ('Fight or Flight’)
– adrenergic effects (use norepinephrine)
Parasympathetic (craniosacral)
– dominates during relaxed situations
– precise control over the body
– cholinergic effects (use acetylcholine)
 Sympathetic vs. Parasympathetic
Effects
Organ Sympathetic Parasympathetic

Heart increases HR decreases HR

Blood vessels
to visceral organs constrict dilate

Blood vessels to heart
+ skeletal muscle dilate constrict

Digestive tract decreases motility increases motility
 THE STRESS REACTION
When stress occurs, the
sympathetic nervous system is
triggered. Norepinephrine is
released by nerves, and
epinephrine is secreted by the
adrenal glands. By activating
receptors in blood vessels and
other structures, these
substances ready the heart and
working muscles for action.
Acetylcholine is released in the
parasympathetic nervous
system, producing calming
effects. The digestive tract is
stimulated to digest a meal, the
heart rate slows, and the pupils
of the eyes become smaller. The
neuroendocrine system also
maintains the body’s normal
internal functioning.
 Chronic stress
When glucocorticoids or adrenaline are secreted in
response to the prolonged psychological stress
commonly encountered by humans, the results are not
ideal. Normally, bodily systems gear up under stress and
release hormones to improve memory, increase
immune function, enhance muscular activity, and
restore homeostasis. If you are not fighting or fleeing,
but standing frustrated in a supermarket checkout line
or sitting in a traffc jam, you are not engaging in
muscular exercise.
Yet these systems continue to be stimulated, and when
they are stimulated chronically, there are different
consequences: Memory is impaired, immune function is
suppressed, and energy is stored as fat.
Response to stress
Senses
 Sensory receptors
Receptors are found in the sense organs.
They receive stimuli from the environment
and transmit stimuli to neurons.
Primary humans senses: photoreception,
chemoreception, mechanoreception,
thermoreception.
 Thermoreception
 Free nerve
endings in the
skin sense
changes in
temperature
(differences
rather than
absolutes).
 These are directly
transmitted
through the PNS.
 Mechanoreception
Hearing is a form of
mechanoreception.
Ears gather sound
waves from the
environment.
The inner ear bones
amplify sounds.
Sounds are
transmitted to the
cochlea.
 Sound transmission
Within the cochlea,
hair cells on the
basilar membrane
vibrate to certain
frequencies, and
send signals down
the auditory nerve.
Loud sounds can
damage these
sensitive hairs
permanently.
 Photoreception
Sight is
photoreception.
Light enters the eye
through the cornea
and pupil.
Light is focused by the
lens.
Light strikes the
retina, and stimulates
receptors.
 Photoreceptors
Light breaks
pigments in the
receptor cells,
releasing energy that
stimulates neurons
connecting to the
optic nerve.
Rod cells detect
amount of light,
cone cells
distinguish colors.
 Chemoreceptioin
Taste is one form
of
chemoreception.
Taste buds detect
certain ions
dissolved in saliva.
Tastes: salty,
sweet, sour, bitter,
 Chemoreception
Smell is another
form of
chemoreception.
Receptors in the
olfactory patch in
the human nose
can distinguish
between about
1000 different
chemicals in the
air.
 “Flavor”
What we sense as the “flavor” of food is not
taste alone. Smell and taste together create
the sensation of “flavor.”
This is why things don’t “taste” good when
we have a cold; we lose the sense of “flavor.”
 Chemoreception
The sense of pain is
another form of
chemoreception.
Injured tissues
release chemicals as a
response. These
chemicals stimulate
free nerve endings in
the skin and the
stimulation is
perceived as pain.
 The End
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