ANIM 1005 Veterinary Anatomy and Physiology Lecture Notes PDF

Summary

These lecture notes cover the nervous system, including its anatomy and physiology. The notes discuss topics such as nervous system anatomy, cell types of the nervous system, parts of the neuron, and the synapse. The material is geared towards the ANIM 1005 Veterinary Anatomy and Physiology course.

Full Transcript

2024-09-20

ANIM 1005
Veterinary Anatomy
and Physiology
Dr. Pauline Smith

Contact:
[email protected]
Rm 00600

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Outline for today’s class:
▪ Nervous system anatomy
▪ Cell types of the nervous system
▪ Parts of the Neuron
▪ The synapse

Test # 3 Tuesday Oct 15th: Nervous System
and Muscular Contraction
75 min (12:30-1:45),
Format: true/False
Multiple choice
Short Answer
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Nervous System
Nervous System:
Functions:
1) coordinate and control body activity

2) detect and process internal and external information
and formulate appropriate responses (to
maintain homeostasis)

Neuron: basic unit of the NS
Nerves: one or more bundles neurons (impulse-carrying
fibers) that connect the central nervous system (CNS)
to other parts of the body
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Organization of Nervous System
Anatomical
Central nervous system (CNS)
– Brain and spinal cord
– Regenerative Capacity: axons do not effectively regenerate
Peripheral nervous system (PNS)
– Extends outward from the central axis toward the
periphery of the body
– Composed of
1) Cranial nerves originate directly from the brain
2) Spinal nerves emerge from the spinal cord
– Regenerative Capacity: axons can slowly regrow and
connect to their peripheral targets

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Organization of the Nervous System

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Central Nervous System (CNS)

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CNS (cont)
1) Brain: located in the cranium

2) Spinal Cord: protected by vertebrae
intervertebral disks: layers of cartilage between
the vertebrae that separate and cushion the
vertebrae from each other

Regenerative Capacity: axons of the CNS do not effectively
regenerate

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Anatomical Organization of the CNS
Brain: Regions: Telencephalon (Cerebrum);
Diencephalon (thalamus, hypothalamus);
Cerebellum;
Brainstem (Midbrain, pons, medulla oblongata)

Spinal cord

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CNS: Spinal Cord Anatomy
Grey matter: Central portion containing neuronal cell
bodies
White matter: Outer portion containing neuronal axon
tracts
Protected within vertebral canal
-

sensory information

motor information

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CNS: Meninges
Meninges: 3 layers of connective tissue that surrounds the
brain and spinal cord
Dura mater: tough fibrous outer layer, fused to
periosteum of cranial bones
epidural: located above the dura mater

Arachnoid: middle layer

Pia mater: attached to the surface of the brain
anchored by processes of astrocytes

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CNS: Meninges (cont)

Contains the CSF

Brain Spinal Cord

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Peripheral Nervous System

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Peripheral Nervous System (PNS)
Extends outward from the central axis (brain and spinal cord)
toward the periphery of the body
Composed of: cranial nerves originate directly from the brain
spinal nerves emerge from the spinal cord

Regenerative Capacity: axons can slowly regrow and connect
to their peripheral targets

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PNS: Cranial Nerves
originate directly
from the brain
I
II
III
IV V

VI
VII
VIII
IX
XII
X
XI

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PNS: Spinal Nerves
Originate from the spinal cord
Carries motor, sensory, and autonomic signals between the
spinal cord and the body

- 38 pairs of spinal nerves in the cat, each roughly
corresponding to a segment of the vertebral
column

(thorac/o) (lumbo/o) (sacr/o)
(cervic/o) (coccyg/o)
Coccygeal

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PNS: Spinal Nerves (cont)

receives sensory input
along sensory dorsal root
axons from receptors in
the skin, muscle, tendons,
joints and visceral organs

motor neurons exit
to innervate skeletal
muscle or toward
smooth muscle

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PNS: Sensory and Motor Neurons

Brings info to the CNS Sends info to the periphery

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PNS: Sensory and Motor Neurons (cont)
The PNS consists of sensory neurons running from stimulus
receptors that inform the CNS of the stimuli and motor
neurons travelling from the CNS to the muscles and
glands (effectors) that take action.

(Visceral Afferent Neurons) (Somatic Afferent Neurons)

(Visceral Motor Neurons) (Somatic Motor Neurons)

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PNS: Direction of Impulses
Direction of Impulses (action potentials)
Afferent nerves: conduct impulses toward CNS
Also called sensory nerves: conduct sensations from
sensory receptors in the skin and other
locations in the body to the CNS
Efferent nerves: conduct impulses away from CNS
Also called motor nerves: cause skeletal muscle
contraction and movement, gland secretion etc

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PNS: Direction of Impulses (cont)

(sensory neuron)

(motor neuron)

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Organization of the Nervous System

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PNS: Somatic vs
Autonomic Nervous System
Somatic Nervous System: actions under conscious
(voluntary) control (conscious perception by the brain)
→ Somatic afferent and efferent neurons

Autonomic Nervous System: controls & coordinates
automatic (involuntary) functions including life support
functions (no conscious perception by the brain)
→ Visceral afferent and efferent neurons

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PNS: Autonomic Nervous System
Autonomic Nervous System (ANS):
controls and coordinates automatic (involuntary) functions
controls muscle (smooth and cardiac) and glands
3 divisions 1) parasympathetic: rest and digest Work together

2) sympathetic: fight or flight } to maintain
homeostasis
3) enteric: in the GI tract

Visceral afferent neurons: conduct impulses toward CNS
from receptors in visceral organs of the chest, abdomen
(include stretch receptors, chemoreceptors (CO2 or O2),
olfactory epithelium, taste buds)

Visceral efferent neurons: conduct impulses away from CNS to
smooth muscle, cardiac muscle and some exocrine glands

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Functional Organization of the Nervous
System

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Functional Organization of the
Nervous System: another look

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CNS: Cerebral Spinal Fluid
Cerebrospinal Fluid (CSF):
- clear fluid that 1) nourishes
2) cools
3) cushions
- produced by the choroid plexus
- contains very few cells and little
protein
- absorbed into the venous circulation
through the arachnoid villi into the
dural sinus to mix with venous blood
- replaced several times daily
CSF tap

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Cerebrospinal Fluid (CSF)
Produced by choroid plexus
– Circulates
– Contains very few cells
and little protein
– absorbed into the venous
circulation through the
arachnoid villi into the
dural sinus to mix with
venous blood
– replaced several times
daily

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Location of Ventricles (Lateral View)

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Roles of the CSF
1) Protection
– Cushions the brain from blows to the head
2) Maintains consistent environment for neurons and glia
– Composition of CSF is controlled and in equilibrium with
extracellular fluid of the brain
3) Buoyancy
– Immersion of brain in CSF ↓ pressure on base of brain
4) Excretion of waste products
– 1-way flow of CSF to the blood removes potentially harmful
substances from the brain
5) Endocrine medium for the brain
– CSF transports hormones to other areas of the brain

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Circulation of CSF
CSF is orange

: common CSF
sampling location

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CSF is Absorbed into Venous System

CSF enters subarachnoid space,
flows into the arachnoid villi which
project into the sagital sinus. The
CSF crosses into the venous sinus.
CSF pressure is regulated by
absorption rate.
Obstruction of CSF absorption
results in ↑ CSF pressure.
↑ pressure seen with brain
Figure 15-4
tumors and meningitis

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Cerebrospinal Fluid: Tests
Spinal Tap
– common diagnostic procedure
– pressure, cell count, biochemical composition

Myelography
– radiopaque dye into subarachnoid space to assess
integrity of spinal canal

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Blood Brain Barrier (Anatomy)
Protects neurons and glia: hormones, large molecules,
charged molecules & circulating chemicals
How do we know this barrier exists? Systemic dyes do not stain the
brain!

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Circumventricular Organs
Specialized areas of the brain that lack the normal
blood brain barrier
– Brain capillaries do not form tight junctions
– Important to detect levels of circulating substances from the
periphery

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Damage to the Blood Brain Barrier
1) Hypertension
– high BP opens BBB by expanding vessels
2) Development
– BBB not fully formed at birth
3) Hyperosmolarity
– High concentration of solutes can open BBB
4) Infection
– Exposure to infection agents can open BBB
5) Trauma, Ischemia, Inflammation, Pressure
– Injury to brain can open BBB

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Cell Types of the Nervous System
Neurons and Neuroglia (Glia)

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Neuroglia (Glia)
2nd cell type in the NS (10-50x the number of neurons)
do not conduct action potentials
Structural and functional support to neurons
Produce myelin sheaths
Modulate growth of developing neurons
Buffer ion and neurotransmitter concentrations
Immune response of the nervous system
Modulate effectiveness of neural communication by
monitoring electrical activity of neurons

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Glial Cell Functions

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Neurons
Basic functional unit of the nervous system
Conduct action potentials (how neurons send messages -
more to follow)
Cannot reproduce but can regenerate cell processes if the
cell body remains intact
Complexity of the brain is due:
1) to large # of neurons (1012 neurons in the brain)
2) the interconnections of the neurons.

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Diverse Neuron Forms and Functions

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Parts of the Neuron

(presynaptic
terminal)

Direction of Impulse
(action potential)

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The Neuron: Anatomical Regions
Dendrites: Carry impulses (information) toward the cell body
Cell Body (soma): processes information
and manufactures proteins for
cell function
Axons: integrates and carries information
(via action potentials – more to follow)
Presynaptic terminals: transmits information to
adjacent cells
Together, these regions:
1) collect information from the environment,
2) integrate that information, and
3) produce an output that can change the environment
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Dendrites
▪ Receive signals from neighboring neurons
signals (neurotransmitters) from neighboring cells act
on receptors on the dendrites
multiple branchlike extensions from the cell body

SYNAPSE
(more to follow!)

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Cell Body (soma)
▪ process the information it receives
and manufactures proteins for neuron function
nucleus (contains DNA)
free ribosomes (cytosolic protein
assembly)
rough endoplasmic reticulum
(assembly of secretory and
membrane proteins)
Golgi apparatus (processing and sorting of secretory
and membrane proteins for transport)

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Axons
conducts electrical impulses (action potentials),
generated at the cell body, to presynaptic terminal
single, often very long process (>1 m in some large animals)
carries proteins (synthesized at cell body)
to presynaptic terminals
insulated by myelin (specialized glial cells)
Schwann cells in periphery
oligodendrocytes in the CNS
- gaps at regular intervals along myelin sheath
(nodes of Ranvier)
- function of myelin sheath: to ↑ the speed
of action potential propagation

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Presynaptic Terminal
▪ transmits signal (via a neurotransmitter) to adjacent cell
when electrical impulses arrive
contains synaptic vesicles filled with neurotransmitters
Synapse: site of contact between presynaptic terminal and
adjacent cell
1) presynaptic terminal
2) receptive surface of the
postsynaptic cell
3) the space in between
(synaptic cleft)

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The Synapse (Chemical)
Synapse: the space between two neurons or between a
neuron and a receptor
synaps/o, synapt/o
Neurotransmitters: chemical substances released into the
space to allow information to be relayed.
Synaptic transmission: perpetuation of the impulse from the
neuron to the next cell.

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The Chemical Synapse
Neurotransmitters are released
from the axon terminal of the
presynaptic membrane into the
synapse where they combine
with receptors on the
postsynaptic membrane

Presynaptic terminal

Synaptic cleft

Postsynaptic cell

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Cell to Cell Conduction: the Synapse
Types of Synapses:
a) Electrical synapses: gap junctions
very fast conduction; (eg cardiac muscle)

b) Chemical synapses: involves the synthesis and release of
neurotransmitters
Once the action potential reaches the end of the
axon, the information must be conveyed to the
next neuron, or cells of the target organ or tissue

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