CH 15 Structure and Function of Neurologic System Lecture Notes 2024 PDF

Summary

This document is a lecture on the structure and function of the nervous system. It covers topics including the somatic and autonomic nervous systems, neurons, neuroglia, and neurotransmitters. The lecture notes appear to be from 2024.

Full Transcript

Structure and Function
of the
Nervous System

Chapter 15

Rebecca Boeschel MSHS, PA-C

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Functional Organization of PNS
Somatic Nervous System – pathways that regulate voluntary
motor control (e.g., skeletal muscle)

Autonomic Nervous System – pathways that regulate the
body’s internal environment (viscera) through the involuntary
control of organ systems
1. Sympathetic Division

2. Parasympathetic Division

What are the target cells (effectors) of the ANS?

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Cells of the Nervous System
Neurons - primary Neuroglia - support cells found in
information/communication cells; the CNS and PNS; provide
working in parallel systems, structural support and nutrition for
neurons can scan the neurons, remove debris and
environment, integrate many increase the transmission speed
systems at higher cognitive of nerve impulses
levels, and maintain homeostasis;
electrically excitable

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Neurons
 Variable size and structure
throughout the nervous system
 Fuel source is predominantly
glucose; however, insulin is not
required for glucose cellular
uptake in the CNS
 CNS starts out with more
neurons than it needs and those
that do not become involved in
functional systems die; some
neurons like olfactory neurons
continue to divide after birth

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 Neuronal Structure

Three common components:
1.Cell body (soma)
densely packed cell bodies in the
CNS are nuclei
densely packed cell bodies in the
PNS are ganglia or plexuses
2.Dendrites - receptive portion of the
neuron
3.Axons - carry nerve impulses away
from the cell body

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Neuron Polarity
Unipolar neuron
Pseudounipolar neuron
Bipolar neuron
Multipolar neurons

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 Myelinated Axons
Myelin sheath
Insulating lipid layer that increases conduction velocity

Myelin in the PNS is formed and maintained by the Schwann cell; in the

CNS it is formed by oligodendrocytes
Regions of CNS with high levels of myelination constitute the white matter;

regions lacking significant myelination are gray matter

Nodes of Ranvier
Regular interruptions of myelin sheath where nutrient/ion exchange can

occur

Saltatory conduction
Mechanism allowing an action potential to leap between nodes of Ranvier

facilitating rapid conduction 0f nerve impulses
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Myelinated Axons in Sequence

Principle of Convergence
branches of multiple neurons
converge on and influence a
single neuron

Principle of Divergence
refers to the ability of axonal
branches to influence many
different neurons
Functional Classification of Neurons
Sensory Neurons - transmit
Association neurons or
impulses from sensory receptors
interneurons - transmit impulses
to the CNS
from neuron to neuron and are
located within the CNS
Major Types of Sensory
Receptors
Motor Neurons -transmit
Nociceptors
impulses from the CNS to an
Mechanoreceptors effector organ (i.e., skeletal
Photochemical receptors muscle, smooth muscle, cardiac
Chemoreceptors muscle, some glands)
Thermoreceptors In skeletal muscle, the end
processes of an axon form a
Proprioception
specialized structure called a
Audition and balance neuromuscular junction
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 Neuroglia (Glial Cells) – Support Cells for Neurons
Astrocytes - form specialized contacts between the neuron
and blood vessels and thought to form an essential
component of blood brain barrier; provide rapid transport for
nutrients and metabolites; appear to work with neurons in
processing information and memory storage; appear to be
scar forming cells of the CNS (my be foci for seizures)

Microglia - clear cellular debris (phagocytic properties); the
key immune cell in the CNS

Ependymal cells - line ventricles and choroid plexuses
involved in cerebrospinal fluid (CSF) production

Oligodendrocytes – formation of myelin sheath in the CNS

Schwann cell – formation of myelin sheath in the PNS;
direct axonal regrowth and functional recovery in the PNS

Non-myelinating Schwann cells - provide neuronal
metabolic support and regeneration in the PNS

Satellite glial cells - Surround sensory, sympathetic, and
parasympathetic nerve cell bodies and ganglia to provide
protection and promote cellular communication (similar to
astrocytes in CNS)
Figure 15-03. Types of Neuroglial
Cells. Neuroglia of the central nervous
system (CNS): (A) Astrocytes attached
to the outside of a capillary blood
vessel in the brain. (B) An
oligodendrocyte with processes that
wrap around nerve fibers in the CNS to
form myelin sheaths. (C) Ciliated
ependymal cells forming a sheet that
usually lines fluid cavities in the
brain. (D) A phagocytic microglial
cell. Neuroglia of the peripheral
nervous system (PNS): (E) A Schwann
cell supporting a bundle of nerve fibers
in the PNS. (F) Another type of
Schwann cell encircling a peripheral
nerve fiber to form a thick myelin
sheath. (G) Satellite cells, another type
of Schwann cell, surround and support
cell bodies of neurons in the PNS.

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 Peripheral Nerve Injury and Regeneration
 Mature neurons do not divide; therefore,
injury can cause permanent loss of function
 Neurons in the PNS can repair themselves
through local, anterograde and retrograde
changes – the process is very slow (about 1
mm per day) and limited to myelinated fibers
in the PNS
 Regeneration depends on location and type
of injury, the presence of inflammatory
responses, and the process of scarring
 Injuries close to the neuron’s cell body often
result in cell death - peripheral nerves injured
close to the spinal cord recover poorly and
slowly because of the long distance between
the cell body and the peripheral termination
of the axon
 A crush injury allows for fuller recovery 15
compared with a cut injury
 Nerve Impulse/Action Potential
 Neurons generate and conduct electrical and chemical impulses by
selectively changing the electrical portion of their plasma membranes
and influencing other nearby neurons by the release of neurotransmitters
 Region between adjacent neurons is called a synapse; presynaptic
neurons and postsynaptic neurons
 Impulses are transmitted across the synapse by chemical and electrical
conduction when a stimulus is strong enough; this is an all or none
response; an unexcited neuron maintains a resting membrane potential
 Chemical conducting substances, neurotransmitters, are synthesized
in the neuron and stored in synaptic vessels in the presynaptic terminal
 Neurons can synthesize more than one neurotransmitter and
postsynaptic membranes can contain more than one type of
neurotransmitter-specific receptor
 Animation: Molecular Mechanisms of Synaptic Function
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Figure 15-05. Neuronal Transmission and Synaptic Cleft. Details illustrate the synaptic bouton
(knob) of a presynaptic neuron, the plasma membrane of a postsynaptic neuron, and a synaptic
cleft. At step 1, the action potential arrives at the synaptic bouton. At step 2, the rapid exocytosis of
neurotransmitter molecules from vesicles in the knob occurs. At step 3, neurotransmitter diffuses
into the synaptic cleft and binds to receptor molecules (R) in the plasma membrane of the
postsynaptic neuron. The postsynaptic receptors directly or indirectly trigger the opening of stimulus
gated ion channels, initiating a local potential in the postsynaptic neuron. At step 4, the local
potential may move toward the axon, where an action potential may begin.
 Neurotransmitters
 Binding of the neurotransmitter at the receptor site changes the
permeability of the postsynaptic neuron and consequently its
membrane potential resulting in either excitation (EPSP) or inhibition
(IPSP)
 Usually, a single postsynaptic potential cannot induce an action
potential and the subsequent propagation of a nerve impulse
 Summation refers to the number and frequency of potentials the
postsynaptic neuron receives
Temporal summation - successive, rapid impulses received from a
single neuron on the same synapse
Spatial summation - combined effects of impulses from a number
of neurons on a single synapse at the same time
 Efficient termination of the signal requires rapid degeneration of the
neurotransmitter
 The mechanisms of convergence (many neurons firing and
converging on one neuron), divergence (one neuron firing and
diverging on many neurons), summation, and facilitation allow for the
integrative processes of the nervous system 18
 Table 15.2
Neurotransmitters and Neuromodulators
 Neuromodulators function to Acetylcholine
raise/lower the membrane Norepinephrine
potential – these chemicals
facilitate or inhibit the effect of Serotonin
neurotransmitters Dopamine
 The plasma membrane is Histamine
facilitated when the summation
brings the membrane closer to
GABA
threshold potential and Glycine
decreases the stimulus required Glutamate
to generate an action potential Aspartate
 The effect that a neurotransmitter
has on the plasma membrane
Endorphins
depends on the balance of all of Enkaphalins
these effects Substance P
Vasoactive intestinal peptide 19
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Central Nervous System: Brain

Contained within the cranial vault
and divided into three distinct
regions, based on embryological
origin (refer to Table 15.3)
1.Forebrain
2.Midbrain
3.Hindbrain

Understanding functional specificity
is useful when trying to understand
pathological conditions

What is neuroplasticity? 20
Forebrain
Telencephalon (cerebral hemispheres) consists of cerebral cortex and
the basal ganglia and is associated with conscious perception of internal
and external stimuli, cognition and memory processes and voluntary
control of skeletal muscles

Diencephalon made up of the epithalamus, subthalamus, hypothalamus
and thalamus which relay sensory information, control autonomic
functions and links to the limbic system for memory and emotion

Limbic system is a group of interconnected structures located between
the telencephalon and the diencephalon involved in primitive behavioral
responses, visceral reactions to emotions, motivation, mood, feeding
behavior, rhythms, sense of smell

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Figure 15-08. The Cerebral Hemispheres. (A) Left hemisphere of cerebrum, lateral view. (B) Functional
areas of the cerebral cortex, midsagittal view. (C) Functional areas of the cerebral cortex, lateral view.
 Figure 15-09. Primary Somatic Sensory (A) and Motor (B) Areas of
the Cortex. (A) The motor homunculus shows proportional somatotopic
representation in the main motor area. (B) The sensory homunculus shows
proportional somatotopic representation in the somaesthetic cortex.
Figure 15-10. Basal Ganglia. (A) The basal ganglia seen through the cortex of the
left cerebral hemisphere. (B) The basal ganglia seen in a frontal (coronal) section of25
the brain.
Midbrain (Mesencephalon)
Mesencephalon connects the
forebrain with the hindbrain and is
made up of:
tectum (the corpora quadrigemina)

tegmentum (red nucleus, substangia

nigra
cerebral peduncles (link the cortex to

the brainstem)

Primarily a relay center for motor and
sensory tracts, as well as a center for
auditory and visual reflexes

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Hindbrain (Metencephalon and Myelencephalon)
Metencephalon consists of the Myelencephalon is usually
cerebellum and pons called the medulla
Cerebellum is responsible for reflexive, oblongata, the lowest portion
involuntary fine-tuning of motor control and for of the brainstem.
maintaining balance and posture; allows Contains vital centers for reflex
sampling and comparison of sensory data control of heart rate, respiration,
from the periphery and motor impulses from blood pressure; coughing,
the cerebral hemispheres for the purpose of sneezing, vomiting, swallowing
coordination and refinement of skeletal Contains nuceli of the 9th -12th
muscle movement; has 2 lobes/hemispheres
cranial nerves
with ipsilateral control of the body in contrast
Major portion of the descending
to the cerebral cortex which has contralateral
control motor tracts decussate at the
Pons (bridge) transmits information from the
inferior medulla (other areas of
crossover in the CNS as well)
cerebellum to the brainstem and between the
Contains elements of the reticular
cerebellar hemispheres; the nuclei of the 5th
through 8th cranial nerves are located in the activating system
pons
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Reticular Formation
 Large network of diffuse nuclei
that connect the brainstem to the
cortex
 Control vital reflexes, such as
cardiovascular function and
respiration
 Essential for maintaining
wakefulness/consciousness
 Some nuclei within the reticular
formation support specific motor
movements, such as balance and
posture

Figure 15-07. Reticular Activating System. The reticular activating system
consists of nuclei in the brainstem reticular formation plus fibers that conduct
sensory information to the nuclei and fibers that conduct from the nuclei to
widespread areas of the cerebral cortex. Functioning of the reticular activating
system is essential for consciousness. 28
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Figure 15-15. Examples of Somatic Motor and Sensory Pathways. (A) Motor tracts. The pyramidal pathway
through the lateral corticospinal tract and the extrapyramidal pathways through the rubrospinal, reticulospinal, and
vestibulospinal tracts. Note that the pathways from the motor cortex cross over to the opposite side of the body,
demonstrating contralateral control. (B) Sensory tracts. 1, The dorsal column-medial lemniscal pathway for
transmitting critical types of tactile signals: touch/proprioception. Note the lateral corticospinal tract decussation;
the point where it crosses to the other side is in the lower medulla. 2, Anterior and lateral divisions of the 29

anterolateral spinothalamic sensory tract: pain/temperature. Note the decussation is in the spinal cord.
 Spinal Cord
Lies within the vertebral canal and is
protected by the vertebral column;
continues from the medulla oblongata
and ends at the conus medullaris (level
of the first and second lumbar vertebra
in adults)

Spinal nerves extend from the conus
medullaris and form a nerve bundle
called the cauda equina

Transmits long motor and sensory tracts
that originate in the brain and synapse
with cell bodies in gray matter of the
spinal cord before exiting to the body

Conducts somatic and autonomic
reflexes and modulates sensory and
motor function 30
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Reflex Arcs

 Form basic units that respond to stimuli and provide protective
circuitry for motor output
 The motor effects of reflex arcs generally occur before the event is
perceived in the brain’s higher centers
 Much internal environmental regulation is mediated by reflex activity
involving the ANS (cardiac and smooth muscle
contraction/relaxation and glandular responses)

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 Reflex Arc Components

 Receptor
 Afferent (sensory) neuron
 Interneuron
 Efferent (motor) neuron
 Effector muscle or gland
Upper and Lower Motor Neurons
Upper motor neurons (completely contained within the CNS)
Efferent pathways primarily relaying information from the cerebrum to
the brain stem or spinal cord
Synapse with interneurons which then synapse with lower motor

neurons
Control fine motor movement and influence/modify reflex arcs and

circuits

Lower motor neurons (extend into the periphery)
Have direct influence on muscles
Cell bodies originate in the gray matter of the spinal cord, but their axons

extend out of the CNS into the PNS, terminating at the neuromuscular
junction
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Neuromuscular Junction

Figure 15-14. Normal Neuromuscular Junction. This figure shows how the distal
end of a motor neuron fiber forms a synapse, or “chemical junction,” with an adjacent
muscle fiber. Neurotransmitters (specifically, acetylcholine [ACh]) are released from
the neuron's synaptic vesicles and diffuse across the synaptic cleft. There they
stimulate receptors in the motor end-plate region of the sarcolemma
 Protective Structures
 Galea aponeurotica - thick band of fibrous tissue overlying
the cranium
 Subgaleal space - has venous connections with the dural
sinuses (If there is increased intracranial pressure, blood can
be shunted to the space, thus reducing pressure in the
intracranial cavity; the subgaleal space is also a common site
for wound drains after intracranial surgery)
 Cranium - eight bones
 Meninges x 3
 Vertebral Column
 Cerebral spinal fluid and the ventricular system
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Meninges
CSF and the Ventricular System
CSF is a clear, colorless fluid similar to blood plasma and
interstitial fluid (see Table 15.4); protects intracranial and spinal
cord structures from jolts and blows
125 to 150 ml circulating at any given time (approx. 600 ml produced daily)
within the ventricles and subarachnoid space; formed continuously but does
not accumulate
Produced by the ependymal cells lining the choroid plexuses in the lateral,

third, and fourth ventricles
Tight junctions of the choroid blood vessels provide a limiting barrier

between the CSF and blood that functions similarly to the blood- brain
barrier
CSF is reabsorbed into the venous circulatory system through the

arachnoid villi which act as one-way valves directing CSF outflow into the
blood
Exerts pressure within the brain and the spinal cord

Lumbar puncture, spinal anesthesia procedures provide access to CSF 38
Figure 15-16. Flow of Cerebrospinal Fluid and Meninges of the Brain. (A) Ventricles highlighted in
blue within a translucent brain in a left lateral view. (B) Flow of cerebral spinal fluid. The fluid produced
by filtration of blood by the choroid plexus of each ventricle flows inferiorly through the lateral
ventricles, interventricular foramen, third ventricle, cerebral aqueduct, fourth ventricle, and subarachnoid
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space to the blood. (C) Meninges of the brain in relation to cerebrospinal fluid and venous blood flow
Protective Structure of the Spinal Cord

33 vertebrae
7cervical, 12 thoracic, 5
lumbar, 5 fused sacral,
and 4 fused coccygeal
Intervertebral disks
Nucleus pulposus
Functions to absorb

shocks, preventing
damage to the vertebrae
Common source of back

problems
See Fig. 15-18
Figure 15-17. Vertebral Column. (A) The normal curves
and regions of the vertebral column. The vertebrae in each
40
region are numbered. (B) Lateral view of several vertebrae
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showing how they articulate.
Blood Supply to the Brain
 800 to 1000 mL per minute or
20% of CO
 CO2 is the primary regulator for
CNS blood flow; potent
vasodilator in the CNS and its
effects ensure an adequate
blood supply
 Paired carotid and vertebral
arteries supply blood to the
brain and connect to form the
circle of Willis
 Drainage from the brain is
accomplished through the
venous sinuses and jugular
veins
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 Arterial Circle of Willis
 Provides an alternative
route for blood flow when
one of the contributing
arteries is obstructed
 Formed by the posterior
cerebral arteries,
posterior communicating
arteries, internal carotid
arteries, anterior
cerebral arteries, and
anterior communicating
arteries

Figure 15-20. Arteries at the Base of the Brain. (A) View of the arteries at the base of the
brain. (B) Circle of Willis. The arteries that compose the circle of Willis are the two anterior
cerebral arteries, joined to each other by the anterior communicating artery and two short segments
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of the internal carotids, off of which the posterior communicating arteries connect to the posterior
cerebral arteries.
Figure 15-21. Areas of the Brain Affected by Occlusion of the Anterior, Middle, and
Posterior Cerebral Artery Branches. ACA, Gray area affected by occlusion of branches of
anterior cerebral artery; MCA, pink area affected by occlusion of branches of middle cerebral
artery; PCA, orange area affected by occlusion of branches of posterior cerebral artery.
Occlusions can occur in the cortical or deep areas of the border zone.

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Blood Supply to the Brain
 Drainage from the brain is
accomplished through the
venous sinuses and jugular
veins
 Cerebral venous drainage does
not parallel its arterial supply –
these veins are classified as
superficial and deep and drain
into venous plexuses and dural
sinuses and eventually join the
jugular veins at the skull base
 Adequacy of venous outflow
can significantly affect
intracranial pressure

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 Blood Brain Barrier
 Describes cellular structures that
selectively inhibit certain potentially
harmful substances in the blood
from entering the interstitial spaces
of the brain or CSF
 Endothelial cells in brain capillaries
(with intracellular tight junctions)
are the site of the BBB; supporting
cells include astrocytes, pericytes,
and microglia
 Some substances, including
glucose, lipid-soluble molecules,
electrolytes, and chemicals, can
cross into and out of the brain Figure 15-23. Blood-Brain Barrier.
facilitated by transport molecules (A) Cellular structure of brain capillary.
 Has implications for drug therapy Endothelial cell membranes with tight junctions
create a physical barrier between capillary
blood and the brain, restricting movement of
Predict what could happen if the BBB bacteria or neurotoxic substances. The pia 45
mater is present only in larger vessels.
breaks down?
Peripheral Nervous System

31 pairs of spinal nerves
Names correlate with the

vertebral level from which they
exit
Mixed nerves containing sensory

and motor neurons

12 pairs of cranial nerves
Sensory, motor, and mixed

Animation: Cranial Nerves

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Peripheral Nervous System
Cranial and spinal nerves, including their branches and
ganglia, constitute the PNS
Spinal nerves originate in the spinal cord
Cranial nerves originate in the brain and pass out of the skull
A peripheral nerve is composed of individual
axons/dendrites, with most wrapped in a myelin sheath;
these individual fibers are arranged in bundles called
fascicles (Fig. 15.25B)
Coverings provide structural support, a blood supply,
and interstitial compartments necessary to deliver
essential electrolytes to support nerve impulse
conduction.
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Figure 15-25. Cranial and Peripheral Nerves and Skin Dermatomes. (A) Ventral surface of the
brain showing attachment of the cranial nerves. The red lines indicate motor function, and the blue
lines indicate sensory function. (B) Peripheral nerve trunk and coverings. (C) Dermatome map, 48
anterolateral view (left), and posterolateral view (right).
Autonomic Nervous System (ANS)
 Coordinates and
maintains a steady
state among the body
organs and regulates
cardiac muscle,
smooth muscle and
some glands
 Components are
located both the PNS
and CNS; however, the
ANS is considered to
be part of the efferent
division of the PNS
 Two divisions – effects
are usually antagonistic
Sympathetic nervous
system
Parasympathetic
nervous system 49
Sympathetic Nervous System
 Mobilizes energy stores in times of need
 Predominates during emergency “fight or flight’ reactions and
physical exercise
 Receives innervation from cell bodies located from the first thoracic
through the second lumbar; sometimes referred to as the
thoracolumbar division (T1-L2)
 Paravertebral sympathetic chain ganglia or collateral ganglia
 Short preganglionic fibers and long adrenergic postganglionic fibers;
ratio of preganglionic fibers to postganglionic fibers is 1:20
 Divergence coordinates activity of neurons at multiple levels of the
spinal cord
 Activity often involves mass discharge of the entire system
 Primary neurotransmitter of postganglionic neuron is norepinephrine
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Parasympathetic Nervous System
 Functions to conserve and restore energy
 Predominates during quiet resting conditions
 Originate in the brainstem (CNs III, VII, IX, and X) and sacral region
of spinal cord (S2-S4)
 Long cholinergic preganglionic fibers and short cholinergic post-
ganglionic fibers; ration of preganglionic to postganglionic fibers is
3:1
 Limited divergence
 Activity normally to discreet organs
 Primary neurotransmitter of postganglionic neurons is acetylcholine

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Figure 15-26. Sympathetic and Parasympathetic Divisions of the Autonomic Nervous System
 Neurotransmitters and Neuroreceptors of the ANS

Sympathetic preganglionic fibers
 Acetylcholine and cholinergic receptors

Sympathetic postganglionic fibers
 Norepinephrine and adrenergic receptors

Parasympathetic pre- and postganglionic fibers
 Acetylcholine and cholinergic receptors

Animation: Autonomic Neurotransmitters
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55
Geriatric Considerations:
Aging and the Nervous System
 CNS mechanisms involved
in the aging brain are
complex and many
questions are yet to be
answered concerning the
neurologic effects of aging

 Ambiguous distinctions
between mechanisms of
normal aging and those
that are pathologic

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Geriatric Considerations:
Aging and the Nervous System

Structural Changes with Aging
Decreased brain weight and size, particularly frontal regions
Increase in ventricular volume
Fibrosis and thickening of the meninges
Narrowing of gyri and widening of sulci
Increase in size of ventricles

Cerebrovascular Changes with Aging
Arterial atherosclerosis (may cause infarcts and scars)
Increased permeability of blood-brain barrier
Decreased vascular density

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 Geriatric Considerations:
Aging and the Nervous System

Cellular Changes with Aging
Decrease in number of neurons not consistently related to changes in
mental function
Decreased myelin
Lipofuscin deposition (a pigment resulting from cellular autodigestion)
Decreased number of dendritic processes and synaptic connections
Intracellular neurofibrillary tangles; significant accumulation in cortex
associated with Alzheimer dementia
Imbalance in amount and distribution of neurotransmitters
Decrease in glucose metabolism

59
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 Geriatric Considerations:
Aging and the Nervous System

Functional Changes with Aging
Decreased tendon reflexes
Progressive deficit in taste and smell

Decreased vibratory sense

Decrease in accommodation and color vision

Decrease in neuromuscular control with change in gait and posture

Sleep disturbances

Memory impairments

Cognitive alterations associated with chronic disease

Functional changes and nervous system aging have significant individual

variation

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