The Nervous System - Lecture Presentation PDF

Summary

This lecture presentation provides an overview of the nervous system, discussing its functions, structural organization, and crucial components including neurons and supporting cells. It delves into the central nervous system (CNS) and peripheral nervous system (PNS), with detailed explanations for each. The presentation utilizes various figures and diagrams to aid in understanding.

Full Transcript

Chapter 7
The Nervous
System

Lecture Presentation by
Patty Bostwick-Taylor
Florence-Darlington Technical College

© 2018 Pearson Education, Ltd.
 Functions of the Nervous System

1. Sensory input—gathering information
Sensory receptors monitor changes, called stimuli,
occurring inside and outside the body
2. Integration
Nervous system processes and interprets sensory
input and decides whether action is needed
3. Motor output
A response, or effect, activates muscles or glands

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Figure 7.1 The nervous system’s functions.

Sensory input
Integration
Sensory receptor

Motor output

Brain and spinal cord
Effector

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© 2018 Pearson Education, Ltd.
 Organization of the Nervous System

Nervous system classifications are based on:
Structures (structural classification)
Activities (functional classification)

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Figure 7.2 Organization of the nervous system.

Central Nervous System
(brain and spinal cord)

Peripheral Nervous System
(cranial and spinal nerves)

Sensory Motor
(afferent) (efferent)

Sense Somatic
Autonomic
organs (voluntary)
(involuntary)
Skeletal
Cardiac and
muscles
smooth muscle,
glands

Parasympathetic Sympathetic

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 Structural Classification

Central nervous system (CNS)
Organs
Brain
Spinal cord
Function
Integration; command center
Interprets incoming sensory information
Issues outgoing instructions

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 Structural Classification

Peripheral nervous system (PNS)
Nerves extending from the brain and spinal cord
Spinal nerves—carry impulses to and from the spinal
cord
Cranial nerves—carry impulses to and from the brain
Functions
Serve as communication lines among sensory organs,
the brain and spinal cord, and glands or muscles

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 Functional Classification

Sensory (afferent) division
Nerve fibers that carry information to the central
nervous system
Somatic sensory (afferent) fibers carry information from
the skin, skeletal muscles, and joints
Visceral sensory (afferent) fibers carry information from
visceral organs
Motor (efferent) division
Nerve fibers that carry impulses away from the central
nervous system organs to effector organs (muscles
and glands)

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 Functional Classification

Motor (efferent) division (continued)
Two subdivisions
Somatic nervous system = voluntary
Consciously (voluntarily) controls skeletal muscles
Autonomic nervous system = involuntary
Automatically controls smooth and cardiac muscles and
glands
Further divided into the sympathetic and parasympathetic
nervous systems

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 Nervous Tissue: Support Cells

Support cells in the CNS are grouped together
as neuroglia
General functions
Support
Insulate
Protect neurons

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 Nervous Tissue: Structure and Function

Nervous tissue is made up of two principal cell
types
Supporting cells (called neuroglia, or glial cells, or
glia)
Resemble neurons
Unable to conduct nerve impulses
Never lose the ability to divide
Neurons

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 Nervous Tissue: Supporting Cells

CNS glial cells: astrocytes
Abundant, star-shaped cells
Brace and anchor neurons to blood capillaries
Determine permeability and exchanges between
blood capillaries and neurons
Protect neurons from harmful substances in blood
Control the chemical environment of the brain

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Figure 7.3a Supporting cells (neuroglia) of nervous tissue.

Capillary

Neuron

Astrocyte

(a) Astrocytes are the most abundant
and versatile neuroglia.

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 Nervous Tissue: Supporting Cells

CNS glial cells: microglia
Spiderlike phagocytes
Monitor health of nearby neurons
Dispose of debris

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Figure 7.3b Supporting cells (neuroglia) of nervous tissue.

Neuron
Microglial
cell

(b) Microglial cells are phagocytes that
defend CNS cells.

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 Nervous Tissue: Supporting Cells

CNS glial cells: ependymal cells
Line cavities of the brain and spinal cord
Cilia assist with circulation of cerebrospinal fluid

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Figure 7.3c Supporting cells (neuroglia) of nervous tissue.

Fluid-filled cavity
Ependymal
cells

Brain or
spinal cord
tissue
(c) Ependymal cells line cerebrospinal
fluid–filled cavities.

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 Nervous Tissue: Supporting Cells

CNS glial cells: oligodendrocytes
Wrap around nerve fibers in the central nervous
system
Produce myelin sheaths

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Figure 7.3d Supporting cells (neuroglia) of nervous tissue.

Myelin sheath
Process of
oligodendrocyte

Nerve
fibers

(d) Oligodendrocytes have processes that form
myelin sheaths around CNS nerve fibers.

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 Nervous Tissue: Supporting Cells

PNS glial cells
Schwann cells
Form myelin sheath around nerve fibers in the PNS
Satellite cells
Protect and cushion neuron cell bodies

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Figure 7.3e Supporting cells (neuroglia) of nervous tissue.

Satellite Cell body of neuron
cells
Schwann cells
(forming myelin sheath)
Nerve fiber

(e) Satellite cells and Schwann cells (which form
myelin) surround neurons in the PNS.

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 Nervous Tissue: Neurons

Neurons = nerve cells
Cells specialized to transmit messages (nerve
impulses)
Major regions of all neurons
Cell body—nucleus and metabolic center of the cell
Processes—fibers that extend from the cell body

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 Nervous Tissue: Neurons

Cell body is the metabolic center of the neuron
Nucleus with large nucleolus
Nissl bodies
Rough endoplasmic reticulum
Neurofibrils
Intermediate filaments that maintain cell shape

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Figure 7.4a Structure of a typical motor neuron.
Dendrite Cell
Mitochondrion body

Nissl substance
Axon
hillock
Axon

Neurofibrils Collateral
Nucleus branch
Nucleolus

One
Schwann
cell

Node of
Axon
Ranvier
terminal
Schwann cells,
forming the myelin
sheath on axon

(a)
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Figure 7.4b Structure of a typical motor neuron.

Neuron
cell body

Dendrite

(b)

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 Nervous Tissue: Neurons

Processes (fibers)
Dendrites—conduct impulses toward the cell body
Neurons may have hundreds of dendrites
Axons—conduct impulses away from the cell body
Neurons have only one axon arising from the cell body
at the axon hillock
End in axon terminals, which contain vesicles with
neurotransmitters
Axon terminals are separated from the next neuron by
a gap

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 Nervous Tissue: Neurons

Processes (fibers) (continued)
Synaptic cleft—gap between axon terminals and the
next neuron
Synapse—functional junction between nerves where
a nerve impulse is transmitted

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 Nervous Tissue: Neurons

Myelin
White, fatty material covering axons
Protects and insulates fibers
Speeds nerve impulse transmission

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 Nervous Tissue: Neurons

Myelin sheaths
Schwann cells—wrap axons in a jelly roll–like fashion
(PNS) to form the myelin sheath
Neurilemma—part of the Schwann cell external to the
myelin sheath
Nodes of Ranvier—gaps in myelin sheath along the
axon
Oligodendrocytes—produce myelin sheaths around
axons of the CNS
Lack a neurilemma

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Figure 7.5 Relationship of Schwann cells to axons in the peripheral nervous system.

Schwann cell
cytoplasm
Schwann cell
Axon plasma membrane

Schwann cell
nucleus
(a)

(b)

Neurilemma

Myelin
sheath
(c)
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 Nervous Tissue: Neurons

Terminology
Nuclei—clusters of cell bodies in the CNS
Ganglia—collections of cell bodies outside the CNS in
the PNS
Tracts—bundles of nerve fibers in the CNS
Nerves—bundles of nerve fibers in the PNS
White matter—collections of myelinated fibers (tracts)
Gray matter—mostly unmyelinated fibers and cell
bodies

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 Nervous Tissue: Neurons

Functional classification
Sensory (afferent) neurons
Carry impulses from the sensory receptors to the CNS
Receptors include:
Cutaneous sense organs in skin
Proprioceptors in muscles and tendons

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Figure 7.6 Neurons classified by function.

Central process (axon)
Sensory
neuron Spinal cord
Cell
(central nervous system)
body
Ganglion
Dendrites Peripheral
process (axon)

Afferent
transmission Interneuron
(association
neuron)
Receptors Peripheral
nervous
system
Efferent transmission

Motor neuron

To effectors
(muscles and glands)

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Figure 7.7a Types of sensory receptors.

(a) Free nerve endings (pain
and temperature receptors)
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Figure 7.7b Types of sensory receptors.

(b) Meissner’s corpuscle
(touch receptor)
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Figure 7.7c Types of sensory receptors.

(c) Lamellar corpuscle (deep
pressure receptor)

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Figure 7.7d Types of sensory receptors.

(d) Golgi tendon organ (proprioceptor)

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Figure 7.7e Types of sensory receptors.

(e) Muscle spindle (proprioceptor)

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 Nervous Tissue: Neurons

Functional classification (continued)
Motor (efferent) neurons
Carry impulses from the central nervous system to
viscera and/or muscles and glands
Interneurons (association neurons)
Cell bodies located in the CNS
Connect sensory and motor neurons

© 2018 Pearson Education, Ltd.
Figure 7.6 Neurons classified by function.

Central process (axon)
Sensory
neuron Spinal cord
Cell
(central nervous system)
body
Ganglion
Dendrites Peripheral
process (axon)

Afferent
transmission Interneuron
(association
neuron)
Receptors Peripheral
nervous
system
Efferent transmission

Motor neuron

To effectors
(muscles and glands)

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 Nervous Tissue: Neurons

Structural classification
Based on number of processes extending from the
cell body
Multipolar neurons—many extensions from the cell
body
All motor and interneurons are multipolar
Most common structural type

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Figure 7.8a Classification of neurons on the basis of structure.

Cell body
Axon
Dendrites
(a) Multipolar neuron

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 Nervous Tissue: Neurons

Structural classification (continued)
Bipolar neurons—one axon and one dendrite
Located in special sense organs, such as nose and eye
Rare in adults

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Figure 7.8b Classification of neurons on the basis of structure.

Cell body

Dendrite Axon
(b) Bipolar neuron

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 Nervous Tissue: Neurons

Structural classification (continued)
Unipolar neurons—have a short single process
leaving the cell body
Sensory neurons found in PNS ganglia
Conduct impulses both toward and away from the cell
body

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Figure 7.8c Classification of neurons on the basis of structure.

Dendrites
Cell body
Short single
process

Axon
Peripheral Central
process process
(c) Unipolar neuron

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 Nervous Tissue: Neurons

Functional properties of neurons
Irritability
Ability to respond to a stimulus and convert it to a nerve
impulse
Conductivity
Ability to transmit the impulse to other neurons,
muscles, or glands

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 Nervous Tissue: Neurons

Electrical conditions of a resting neuron’s
membrane
The plasma membrane at rest is inactive (polarized)
Fewer positive ions are inside the neuron’s plasma
membrane than outside
K+ is the major positive ion inside the cell
Na+ is the major positive ion outside the cell
As long as the inside of the membrane is more
negative (fewer positive ions) than the outside, the cell
remains inactive

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Figure 7.9 The nerve impulse. Slide 2

[Na+ ]
1 Resting membrane is polarized. In the resting state, the
[K+] external face of the membrane is slightly positive; its internal
face is slightly negative. The chief extracellular ion is sodium
(Na+), whereas the chief intracellular ion is potassium (K+). The
membrane is relatively impermeable to both ions.

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 Nervous Tissue: Neurons

Action potential initiation and generation
A stimulus changes the permeability of the neuron’s
membrane to sodium ions
Sodium channels now open, and sodium (Na+)
diffuses into the neuron
The inward rush of sodium ions changes the polarity
at that site and is called depolarization

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Figure 7.9 The nerve impulse. Slide 3

Na+
2 Stimulus initiates local depolarization. A stimulus
Na+ changes the permeability of a local “patch” of the membrane,
and sodium ions diffuse rapidly into the cell. This changes the
polarity of the membrane (the inside becomes more positive;
the outside becomes more negative) at that site.

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 Nervous Tissue: Neurons

Action potential initiation and generation
(continued)
A graded potential (localized depolarization) exists
where the inside of the membrane is more positive and
the outside is less positive
If the stimulus is strong enough and sodium influx
great enough, local depolarization activates the neuron
to conduct an action potential (nerve impulse)

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Figure 7.9 The nerve impulse. Slide 4

Na+
3 Depolarization and generation of an action potential.
If the stimulus is strong enough, depolarization causes
Na+
membrane polarity to be completely reversed, and an action
potential is initiated.

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 Nervous Tissue: Neurons

Propagation of the action potential
If enough sodium enters the cell, the action potential
(nerve impulse) starts and is propagated over the
entire axon
All-or-none response means the nerve impulse either
is propagated or is not
Fibers with myelin sheaths conduct nerve impulses
more quickly

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Figure 7.9 The nerve impulse. Slide 5

4 Propagation of the action potential. Depolarization of the
first membrane patch causes permeability changes in the
adjacent membrane, and the events described in step 2 are
repeated. Thus, the action potential propagates rapidly along the
entire length of the membrane.

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 Nervous Tissue: Neurons

Repolarization
Membrane permeability changes again—becoming
impermeable to sodium ions and permeable to
potassium ions
Potassium ions rapidly diffuse out of the neuron,
repolarizing the membrane
Repolarization involves restoring the inside of the
membrane to a negative charge and the outer surface
to a positive charge

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Figure 7.9 The nerve impulse. Slide 6

K+
5 Repolarization. Potassium ions diffuse out of the cell as
K+ the membrane permeability changes again, restoring the
negative charge on the inside of the membrane and the
positive charge on the outside surface. Repolarization occurs
in the same direction as depolarization.

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 Nervous Tissue: Neurons

Repolarization (continued)
Initial conditions of sodium and potassium ions are
restored using the sodium-potassium pump
This pump, using ATP, restores the original
configuration
Three sodium ions are ejected from the cell while two
potassium ions are returned to the cell
Until repolarization is complete, a neuron cannot
conduct another nerve impulse

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Figure 7.9 The nerve impulse. Slide 7

Cell
Na+ – K+
exterior pump
6 Initial ionic conditions restored. The ionic conditions
Na+ Diffusion
K+ Diffusion

of the resting state are restored later by the activity of the
Plasma
membrane sodium-potassium pump. Three sodium ions are ejected for
every two potassium ions carried back into the cell.
Cell
interior

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 Nervous Tissue: Neurons

Transmission of the signal at synapses
Step 1: When the action potential reaches the axon
terminal, the electrical charge opens calcium channels

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Figure 7.10 How neurons communicate at chemical synapses. Slide 2

Axon of
transmitting
neuron
Receiving
neuron

1 Action
Dendrite potential
arrives.
Vesicle
Axon terminal sSynaptic
cleft

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 Nervous Tissue: Neurons

Transmission of the signal at synapses
(continued)
Step 2: Calcium, in turn, causes the tiny vesicles
containing the neurotransmitter chemical to fuse with
the axonal membrane

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Figure 7.10 How neurons communicate at chemical synapses. Slide 3

2 Vesicle Transmitting neuron
fuses with
plasma
membrane.

Synaptic
cleft Ion Neurotransmitter
channels molecules

Receiving neuron

Receiving neuron
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 Nervous Tissue: Neurons

Transmission of the signal at synapses
(continued)
Step 3: The entry of calcium into the axon terminal
causes porelike openings to form, releasing the
neurotransmitter into the synaptic cleft

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Figure 7.10 How neurons communicate at chemical synapses. Slide 4

2 Vesicle Transmitting neuron
fuses with
plasma 3 Neurotrans-
membrane. mitter is
released into
synaptic cleft.

Synaptic
cleft Ion Neurotransmitter
channels molecules

Receiving neuron

Receiving neuron
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 Nervous Tissue: Neurons

Transmission of the signal at synapses
(continued)
Step 4: The neurotransmitter molecules diffuse across
the synaptic cleft and bind to receptors on the
membrane of the next neuron

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Figure 7.10 How neurons communicate at chemical synapses. Slide 5

2 Vesicle Transmitting neuron
fuses with 4 Neurotrans-
plasma 3 Neurotrans- mitter binds
membrane. mitter is to receptor
released into on receiving
synaptic cleft. neuron’s
membrane.

Synaptic
cleft Ion Neurotransmitter
channels molecules

Receiving neuron

Receiving neuron
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 Nervous Tissue: Neurons

Transmission of the signal at synapses
(continued)
Step 5: If enough neurotransmitter is released, a
graded potential will be generated
Eventually an action potential (nerve impulse) will occur
in the neuron beyond the synapse

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Figure 7.10 How neurons communicate at chemical synapses. Slide 6

5 Ion channel opens.

Neurotransmitter

Receptor
Na+

Receiving neuron
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 Nervous Tissue: Neurons

Transmission of the signal at synapses
(continued)
Step 6: The electrical changes prompted by
neurotransmitter binding are brief
The neurotransmitter is quickly removed from the
synapse either by reuptake or by enzymatic activity
Transmission of an impulse is electrochemical
Transmission down neuron is electrical
Transmission to next neuron is chemical

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Figure 7.10 How neurons communicate at chemical synapses. Slide 7

6 Ion channel closes.

Neurotransmitter is
broken down and
released.
Na+

Receiving neuron
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 BioFlix: How Synapses Work

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 Nervous Tissue: Neurons

Reflexes are rapid, predictable, and involuntary
responses to stimuli
Reflexes occur over neural pathways called
reflex arcs
Two types of reflexes
Somatic reflexes
Autonomic reflexes

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Figure 7.11a Simple reflex arcs.

Stimulus at distal Skin Spinal cord
end of neuron (in cross section)
2 Sensory neuron
3Integration
1 Receptor center
4 Motor neuron
5 Effector Interneuron

(a) Five basic elements of reflex arc

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 Nervous Tissue: Neurons

Somatic reflexes
Reflexes that stimulate the skeletal muscles
Involuntary, although skeletal muscle is normally
under voluntary control
Example: pulling your hand away from a hot object
Autonomic reflexes
Regulate the activity of smooth muscles, the heart,
and glands
Example: regulation of smooth muscles, heart and
blood pressure, glands, digestive system

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 Nervous Tissue: Neurons

Five elements of a reflex arc
1. Sensory receptor—reacts to a stimulus
2. Sensory neuron—carries message to the integration
center
3. Integration center (CNS)—processes information and
directs motor output
4. Motor neuron—carries message to an effector
5. Effector organ—is the muscle or gland to be
stimulated

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Figure 7.11a Simple reflex arcs. Slide 2

Stimulus at distal Skin
end of neuron

1 Receptor

(a) Five basic elements of reflex arc

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Figure 7.11a Simple reflex arcs. Slide 3

Stimulus at distal Skin Spinal cord
end of neuron (in cross section)
2 Sensory neuron
1 Receptor

Interneuron

(a) Five basic elements of reflex arc

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Figure 7.11a Simple reflex arcs. Slide 4

Stimulus at distal Skin Spinal cord
end of neuron (in cross section)
2 Sensory neuron
3 Integration
1 Receptor center

Interneuron

(a) Five basic elements of reflex arc

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Figure 7.11a Simple reflex arcs. Slide 5

Stimulus at distal Skin Spinal cord
end of neuron (in cross section)
2 Sensory neuron
3 Integration
1 Receptor center
4 Motor neuron
Interneuron

(a) Five basic elements of reflex arc

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Figure 7.11a Simple reflex arcs. Slide 6

Stimulus at distal Skin Spinal cord
end of neuron (in cross section)
2 Sensory neuron
3 Integration
1 Receptor center
4 Motor neuron
5 Effector Interneuron

(a) Five basic elements of reflex arc

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 Nervous Tissue: Neurons

Two-neuron reflex arcs
Simplest type
Example: patellar (knee-jerk) reflex

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Figure 7.11b Simple reflex arcs. Slide 1

1 Sensory (stretch) receptor

2 Sensory (afferent) neuron

3

4 Motor (efferent) neuron

5 Effector organ

(b) Two-neuron reflex arc

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Figure 7.11b Simple reflex arcs. Slide 2

1 Sensory (stretch) receptor

(b) Two-neuron reflex arc

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Figure 7.11b Simple reflex arcs. Slide 3

1 Sensory (stretch) receptor

2 Sensory (afferent) neuron

(b) Two-neuron reflex arc

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Figure 7.11b Simple reflex arcs. Slide 4

1 Sensory (stretch) receptor

2 Sensory (afferent) neuron

3

(b) Two-neuron reflex arc

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Figure 7.11b Simple reflex arcs. Slide 5

1 Sensory (stretch) receptor

2 Sensory (afferent) neuron

3

4 Motor (efferent) neuron

(b) Two-neuron reflex arc

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Figure 7.11b Simple reflex arcs. Slide 6

1 Sensory (stretch) receptor

2 Sensory (afferent) neuron

3

4 Motor (efferent) neuron

5 Effector organ

(b) Two-neuron reflex arc

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 Nervous Tissue: Neurons

Three-neuron reflex arcs
Consists of five elements: receptor, sensory neuron,
interneuron, motor neuron, and effector
Example: flexor (withdrawal) reflex

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Figure 7.11c Simple reflex arcs. Slide 1

1 Sensory receptor 2 Sensory (afferent) neuron

3 Interneuron

4 Motor (efferent) neuron

5 Effector organ
(c) Three-neuron reflex arc

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Figure 7.11c Simple reflex arcs. Slide 2

1 Sensory receptor

(c) Three-neuron reflex arc

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Figure 7.11c Simple reflex arcs. Slide 3

1 Sensory receptor 2 Sensory (afferent) neuron

(c) Three-neuron reflex arc

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Figure 7.11c Simple reflex arcs. Slide 4

1 Sensory receptor 2 Sensory (afferent) neuron

3 Interneuron

(c) Three-neuron reflex arc

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Figure 7.11c Simple reflex arcs. Slide 5

1 Sensory receptor 2 Sensory (afferent) neuron

3 Interneuron

4 Motor (efferent) neuron

(c) Three-neuron reflex arc

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Figure 7.11c Simple reflex arcs. Slide 6

1 Sensory receptor 2 Sensory (afferent) neuron

3 Interneuron

4 Motor (efferent) neuron

5 Effector organ
(c) Three-neuron reflex arc

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 Central Nervous System (CNS)

Functional anatomy of the brain
Brain regions
Cerebral hemispheres
Diencephalon
Brain stem
Cerebellum

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 Functional Anatomy of the Brain

Cerebral hemispheres are paired (left and right)
superior parts of the brain
Include more than half of the brain mass
The surface is made of ridges (gyri) and grooves
(sulci)
Fissures are deeper grooves
Lobes are named for the cranial bones that lie over
them

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 Functional Anatomy of the Brain

Three main regions of cerebral hemisphere
1. Cortex is superficial gray matter
2. White matter
3. Basal nuclei are deep pockets of gray matter

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Figure 7.12a Development and regions of the human brain.

Cerebral
hemisphere
Outline of
diencephalon
Midbrain
Cerebellum
Brain stem

(a) 13 weeks

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Figure 7.12b Development and regions of the human brain.

Cerebral
hemisphere

Diencephalon

Cerebellum

Brain stem

(b) Adult brain

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Figure 7.13ab Left lateral view of the brain.

Precentral gyrus Central sulcus Parietal lobe
Postcentral gyrus
Frontal lobe Parietal lobe
Left cerebral
Parieto-occipital
hemisphere
sulcus (deep)

Lateral sulcus
Frontal
Occipital lobe lobe
Occipital
Temporal lobe Temporal lobe
Cerebellum lobe
Pons Superior
Cerebral cortex Medulla Brain Cerebellum
Inferior
(gray matter) oblongata stem
Spinal (b)
Gyrus
cord
Sulcus
Cerebral
Fissure white
(a deep sulcus) matter
(a)

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Table 7.1 Functions of Major Brain Regions (1 of 2)

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Table 7.1 Functions of Major Brain Regions (2 of 2)

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 Functional Anatomy of the Brain

Cerebral cortex
Primary somatic sensory area
Located in parietal lobe posterior to central sulcus
Receives impulses from the body’s sensory receptors
Pain, temperature, light touch (except for special senses)
Sensory homunculus is a spatial map
Left side of the primary somatic sensory area receives
impulses from right side (and vice versa)

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Figure 7.13c Left lateral view of the brain.

Central sulcus
Primary motor area Primary somatic sensory
Premotor area area
Anterior Gustatory area (taste)
association area
Working memory Speech/language
and judgment (outlined by dashes)
Problem Posterior association
solving area
Language
comprehension
Visual area
Broca’s area
(motor speech)
Olfactory
Auditory area
area
(c)

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Figure 7.14 Sensory and motor areas of the cerebral cortex.
Posterior

Motor Sensory
Motor map in Anterior Sensory map in

Shoul
precentral gyrus postcentral gyrus

Head

Ha earm
kNeck
Trun
Trun
k

Elb rm
ow
Hip
L eg
d er

Knee
Elb t
Arm
Wri

Hip
Ha

s
A

r
nd

er
Fi

Fo
n

ow
s
ng

ng
d
er

Fi
Knee
Th
s

b
um

um
Foot
b

Th
Nec

e
Ey
Bro k se
w o
N
Eye Toe ce
Fa
s s
F ace Genitals L ip

Lips T eet s
m
h uw
G
Ja
Jaw
Tongu
e
Tongu Primary motor Primary somatic Pharynx
e cortex sensory cortex Intra-
Swallowing
(precentral gyrus) (postcentral gyrus) abdominal

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 Functional Anatomy of the Brain

Cerebral areas involved in special senses
Visual area (occipital lobe)
Auditory area (temporal lobe)
Olfactory area (temporal lobe)

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 Functional Anatomy of the Brain

Cerebral cortex (continued)
Primary motor area
Located anterior to the central sulcus in the frontal lobe
Allows us to consciously move skeletal muscles
Motor neurons form pyramidal (corticospinal) tract,
which descends to spinal cord
Motor homunculus is a spatial map

© 2018 Pearson Education, Ltd.
Figure 7.13a Left lateral view of the brain.

Precentral gyrus Central sulcus
Postcentral gyrus
Frontal lobe Parietal lobe
Parieto-occipital
sulcus (deep)

Lateral sulcus
Occipital lobe

Temporal
lobe
Cerebellum
Pons
Cerebral cortex Medulla
(gray matter) oblongata
Gyrus Spinal
cord
Sulcus
Cerebral
Fissure white
(a deep sulcus) matter
(a)
© 2018 Pearson Education, Ltd.
Figure 7.14 Sensory and motor areas of the cerebral cortex.
Posterior

Motor Sensory
Motor map in Anterior Sensory map in

Shoul
precentral gyrus postcentral gyrus

Head

Ha earm
kNeck
Trun
Trun
k

Elb rm
ow
Hip
L eg
d er

Knee
Elb t
Arm
Wri

Hip
Ha

s
A

r
nd

er
Fi

Fo
n

ow
s
ng

ng
d
er

Fi
Knee
Th
s

b
um

um
Foot
b

Th
Nec

e
Ey
Bro k se
w o
N
Eye Toe ce
Fa
s s
F ace Genitals L ip

Lips T eet s
m
h uw
G
Ja
Jaw
Tongu
e
Tongu Primary motor Primary somatic Pharynx
e cortex sensory cortex Intra-
Swallowing
(precentral gyrus) (postcentral gyrus) abdominal

© 2018 Pearson Education, Ltd.
 Functional Anatomy of the Brain

Cerebral cortex (continued)
Broca’s area (motor speech area)
Involved in our ability to speak
Usually in left hemisphere
Other specialized areas
Anterior association area (frontal lobe)
Posterior association area (posterior cortex)
Speech area (for sounding out words)

© 2018 Pearson Education, Ltd.
Figure 7.13c Left lateral view of the brain.

Central sulcus
Primary motor area Primary somatic sensory
Premotor area area
Anterior Gustatory area (taste)
association area
Working memory Speech/language
and judgment (outlined by dashes)
Problem Posterior association
solving area
Language
comprehension
Visual area
Broca’s area
(motor speech)
Olfactory
Auditory area
area
(c)

© 2018 Pearson Education, Ltd.
 Functional Anatomy of the Brain

Cerebral white matter
Composed of fiber tracts deep to the gray matter
Corpus callosum connects hemispheres
Tracts, such as the corpus callosum, are known as
commissures
Association fiber tracts connect areas within a
hemisphere
Projection fiber tracts connect the cerebrum with lower
CNS centers

© 2018 Pearson Education, Ltd.
Figure 7.13a Left lateral view of the brain.

Precentral gyrus Central sulcus
Postcentral gyrus
Frontal lobe Parietal lobe
Parieto-occipital
sulcus (deep)

Lateral sulcus
Occipital lobe

Temporal
lobe
Cerebellum
Pons
Cerebral cortex Medulla
(gray matter) oblongata
Gyrus Spinal
cord
Sulcus
Cerebral
Fissure white
(a deep sulcus) matter
(a)
© 2018 Pearson Education, Ltd.
Figure 7.15 Frontal section (facing posteriorly) of the brain showing commissural, association, and projection fibers running through the cerebrum
and the lower CNS.

Longitudinal fissure Association fibers
Superior
Lateral Commissural fibers
ventricle (corpus callosum)
Corona
Basal nuclei radiata

Fornix
Internal
Thalamus capsule

Third
ventricle
Pons Projection
fibers
Medulla oblongata
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 Functional Anatomy of the Brain

Basal nuclei
“Islands” of gray matter buried deep within the white
matter of the cerebrum
Regulate voluntary motor activities by modifying
instructions sent to skeletal muscles by the primary
motor cortex

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 Functional Anatomy of the Brain

Diencephalon
Sits on top of the brain stem
Enclosed by the cerebral hemispheres
Made of three structures
1. Thalamus
2. Hypothalamus
3. Epithalamus

© 2018 Pearson Education, Ltd.
Figure 7.12b Development and regions of the human brain.

Cerebral
hemisphere

Diencephalon

Cerebellum

Brain stem

(b) Adult brain

© 2018 Pearson Education, Ltd.
Figure 7.16a Diencephalon and brain stem structures.

Cerebral hemisphere
Corpus callosum
Third ventricle
Choroid plexus of third
ventricle
Occipital lobe of
cerebral hemisphere
Thalamus
Anterior (encloses third ventricle)
commissure Pineal gland
(part of epithalamus)
Hypothalamus Corpora
quadrigemina
Optic chiasma
Cerebral Midbrain
aqueduct
Pituitary gland
Cerebral
peduncle
Mammillary body
Fourth ventricle
Pon
s Choroid plexus
Medulla oblongata (part of epithalamus)
Spinal cord Cerebellum
(a)

© 2018 Pearson Education, Ltd.
Figure 7.16b Diencephalon and brain stem structures.

Radiations
to cerebral
cortex

Auditory
Visual impulses impulses

Reticular formation Descending
motor projections
Ascending general sensory to spinal cord
tracts (touch, pain, temperature)
(b)

© 2018 Pearson Education, Ltd.
 Functional Anatomy of the Brain

Diencephalon: thalamus
Encloses the third ventricle
Relay station for sensory impulses passing upward to
the cerebral cortex
Transfers impulses to the correct part of the cortex for
localization and interpretation

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 Functional Anatomy of the Brain

Diencephalon: hypothalamus
Makes up the floor of the diencephalon
Important autonomic nervous system center
Regulates body temperature
Regulates water balance
Regulates metabolism
Houses the limbic center for emotions
Regulates the nearby pituitary gland
Houses mammillary bodies for olfaction (smell)

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 Functional Anatomy of the Brain

Diencephalon: epithalamus
Forms the roof of the third ventricle
Houses the pineal body (an endocrine gland)
Includes the choroid plexus—forms cerebrospinal fluid

© 2018 Pearson Education, Ltd.
 Functional Anatomy of the Brain

Brain stem
Attaches to the spinal cord
Parts of the brain stem
1. Midbrain
2. Pons
3. Medulla oblongata

© 2018 Pearson Education, Ltd.
Figure 7.16a Diencephalon and brain stem structures.

Cerebral hemisphere
Corpus callosum
Third ventricle
Choroid plexus of third
ventricle
Occipital lobe of
cerebral hemisphere
Thalamus
Anterior (encloses third ventricle)
commissure Pineal gland
(part of epithalamus)
Hypothalamus Corpora
quadrigemina
Optic chiasma
Cerebral Midbrain
aqueduct
Pituitary gland
Cerebral
peduncle
Mammillary body
Fourth ventricle
Pon
s Choroid plexus
Medulla oblongata (part of epithalamus)
Spinal cord Cerebellum
(a)

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 Functional Anatomy of the Brain

Brain stem: midbrain
Extends from the mammillary bodies to the pons
inferiorly
Cerebral aqueduct (tiny canal) connects the third and
fourth ventricles
Two bulging fiber tracts, cerebral peduncles, convey
ascending and descending impulses
Four rounded protrusions, corpora quadrigemina, are
visual and auditory reflex centers

© 2018 Pearson Education, Ltd.
 Functional Anatomy of the Brain

Brain stem: pons
The rounded structure protruding just below the
midbrain
Mostly composed of fiber tracts
Includes nuclei involved in the control of breathing

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 Functional Anatomy of the Brain

Brain stem: medulla oblongata
The most inferior part of the brain stem that merges
into the spinal cord
Includes important fiber tracts
Contains important centers that control:
Heart rate
Blood pressure
Breathing
Swallowing
Vomiting
Fourth ventricle lies posterior to pons and medulla

© 2018 Pearson Education, Ltd.
 Functional Anatomy of the Brain

Brain stem: reticular formation
Diffuse mass of gray matter along the brain stem
Involved in motor control of visceral organs
Reticular activating system (RAS)
Plays a role in awake/sleep cycles and consciousness
Filter for incoming sensory information

© 2018 Pearson Education, Ltd.
Figure 7.16b Diencephalon and brain stem structures.

Radiations
to cerebral
cortex

Auditory
Visual impulses impulses

Reticular formation Descending
motor projections
Ascending general sensory to spinal cord
tracts (touch, pain, temperature)
(b)

© 2018 Pearson Education, Ltd.
 Functional Anatomy of the Brain

Cerebrum
Two hemispheres with convoluted surfaces
Outer cortex of gray matter and inner region of white
matter
Controls balance
Provides precise timing for skeletal muscle activity
and coordination of body movements

© 2018 Pearson Education, Ltd.
Figure 7.16a Diencephalon and brain stem structures.

Cerebral hemisphere
Corpus callosum
Third ventricle
Choroid plexus of third
ventricle
Occipital lobe of
cerebral hemisphere
Thalamus
Anterior (encloses third ventricle)
commissure Pineal gland
(part of epithalamus)
Hypothalamus Corpora
quadrigemina
Optic chiasma
Cerebral Midbrain
aqueduct
Pituitary gland
Cerebral
peduncle
Mammillary body
Fourth ventricle
Pon
s Choroid plexus
Medulla oblongata (part of epithalamus)
Spinal cord Cerebellum
(a)

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 Protection of the Central Nervous System

Meninges
Cerebrospinal fluid (CSF)
Blood-brain barrier

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 Protection of the Central Nervous System

Meninges (continued)
Dura mater
Outermost leathery layer
Double-layered external covering
Periosteum—attached to inner surface of the skull
Meningeal layer—outer covering of the brain
Folds inward in several areas
Falx cerebri
Tentorium cerebelli

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 Protection of the Central Nervous System

Meninges (continued)
Arachnoid layer
Middle layer
Weblike extensions span the subarachnoid space to
attach it to the pia mater
Subarachnoid space is filled with cerebrospinal fluid
Arachnoid granulations protrude through the dura mater
and absorb cerebrospinal fluid into venous blood
Pia mater
Internal layer
Clings to the surface of the brain and spinal cord

© 2018 Pearson Education, Ltd.
Figure 7.17a Meninges of the brain.

Skin of scalp
Periosteum
Bone of skull
Periosteal Dura
Meningeal mater
Superior
sagittal sinus Arachnoid mater
Subdural Pia mater
space Arachnoid granulation
Subarachnoid Blood
space vessel
Falx cerebri
(in longitudinal
(a)
fissure only)

© 2018 Pearson Education, Ltd.
Figure 7.17b Meninges of the brain.

Skull
Scalp
Superior
sagittal sinus
Occipital lobe Dura mater
Tentoriu
m Transvers
Cerebellum
cerebelli e
Tempora
sinus
Arachnoid mater l
over medulla oblongata bone
(b)

© 2018 Pearson Education, Ltd.
 Protection of the Central Nervous System

Cerebrospinal fluid
Similar to blood plasma in composition
Formed continually by the choroid plexuses
Choroid plexuses—capillaries in the ventricles of the
brain
CSF forms a watery cushion to protect the brain and
spinal cord
Circulated in the arachnoid space, ventricles, and
central canal of the spinal cord

© 2018 Pearson Education, Ltd.
 Protection of the Central Nervous System

Cerebrospinal fluid circulation
1. CSF is produced by the choroid plexus of each
ventricle
2. CSF flows through the ventricles and into the
subarachnoid space via the median and lateral
apertures. Some CSF flows through the central canal
of the spinal cord
3. CSF flows through the subarachnoid space
4. CSF is absorbed into the dural venous sinuses via
the arachnoid villi

© 2018 Pearson Education, Ltd.
Figure 7.18a Ventricles and location of the cerebrospinal fluid.

Lateral ventricle

Anterior horn
Septum
pellucidum Interventricular
foramen
Inferior
horn
Third ventricle
Lateral Cerebral aqueduct
aperture
Fourth ventricle

Central canal

(a) Anterior view

© 2018 Pearson Education, Ltd.
Figure 7.18b Ventricles and location of the cerebrospinal fluid.

Lateral ventricle

Anterior horn
Posterior
Interventricular horn
foramen

Third ventricle Inferior horn

Cerebral aqueduct Median
aperture
Fourth ventricle
Lateral
Central canal
aperture
(b) Left lateral view

© 2018 Pearson Education, Ltd.
Figure 7.18c Ventricles and location of the cerebrospinal fluid.

4
Superior
sagittal sinus Arachnoid granulation

Choroid plexuses Subarachnoid space
of lateral and Arachnoid mater
third ventricles
Meningeal dura mater
Corpus callosum
Periosteal dura mater
1
Interventricular Right lateral ventricle
foramen (deep to cut)
Third ventricle
3
Choroid plexus
of fourth ventricle
Cerebral aqueduct
Lateral aperture
1 CSF is produced by the
Fourth ventricle 2 choroid plexus of each
Median aperture ventricle.
2 CSF flows through the ventricles
and into the subarachnoid space via
Central canal the median and lateral apertures.
of spinal cord
Some CSF flows through the central
canal of the spinal cord.
3 CSF flows through the
subarachnoid space.
4 CSF is absorbed into the dural
venous sinuses via the arachnoid
granulations.
(c) CSF circulation
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 Protection of the Central Nervous System

Blood-brain barrier
Includes the least permeable capillaries of the body
Allows water, glucose, and amino acids to pass
through the capillary walls
Excludes many potentially harmful substances from
entering the brain, such as wastes
Useless as a barrier against some substances

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 Brain Dysfunctions

Traumatic brain injuries
Concussion
Slight brain injury
Typically little permanent brain damage occurs
Contusion
Marked nervous tissue destruction occurs
Coma may occur
Death may occur after head blows due to:
Intracranial hemorrhage
Cerebral edema

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 Brain Dysfunctions

Cerebrovascular accident (CVA), or stroke
Results when blood circulation to a brain area is
blocked and brain tissue dies
Loss of some functions or death may result
Hemiplegia—one-sided paralysis
Aphasia—damage to speech center in left hemisphere
Transient ischemic attack (TIA)
Temporary brain ischemia (restriction of blood flow)
Numbness, temporary paralysis, impaired speech

© 2018 Pearson Education, Ltd.
 Spinal Cord

Extends from the foramen magnum of the skull
to the first or second lumbar vertebra
Cauda equina is a collection of spinal nerves at
the inferior end
Provides a two-way conduction pathway to and
from the brain
31 pairs of spinal nerves arise from the spinal
cord

© 2018 Pearson Education, Ltd.
Figure 7.19 Anatomy of the spinal cord, posterior view.

Cervical
Cervical spinal nerves
enlargement C8

Dura and
Thoracic
arachnoid
mater spinal nerves

Lumbar
enlargement T12
End of spinal cord

Lumbar
Cauda spinal nerves
equina L5
End of S1 Sacral
meningeal
spinal nerves
coverings
S5

© 2018 Pearson Education, Ltd.
 Spinal Cord

Gray matter of the spinal cord and spinal roots
Internal gray matter is mostly cell bodies
Dorsal (posterior) horns house interneurons
Receive information from sensory neurons in the dorsal
root; cell bodies housed in dorsal root ganglion
Anterior (ventral) horns house motor neurons of the
somatic (voluntary) nervous system
Send information out ventral root
Gray matter surrounds the central canal, which is filled
with cerebrospinal fluid

© 2018 Pearson Education, Ltd.
 Spinal Cord

White matter of the spinal cord
Composed of myelinated fiber tracts
Three regions: dorsal, lateral, ventral columns
Sensory (afferent) tracts conduct impulses toward
brain
Motor (efferent) tracts carry impulses from brain to
skeletal muscles

© 2018 Pearson Education, Ltd.
Figure 7.20 Spinal cord with meninges (three-dimensional, anterior view).

White matter Dorsal (posterior)
Dorsal root Central canal horn of gray matter
ganglion Lateral horn of
gray matter

Spinal nerve
Ventral (anterior)
Dorsal root of
horn of gray matter
spinal nerve

Ventral root Pia mater
of spinal nerve

Arachnoid mater

Dura mater

© 2018 Pearson Education, Ltd.
Figure 7.21 Schematic of ascending (sensory) and descending (motor) pathways between the brain and the spinal cord.

Interneuron carrying sensory
information to cerebral cortex

Integration (processing and
interpretation of sensory input)
Cerebral cortex occurs
(gray matter) Interneuron carrying
White matter response to
Thalamus motor neurons
Cerebrum

Interneuron
carrying response Brain stem
to motor neuron
Cell body of sensory
neuron in sensory
ganglion
Interneuron carrying
Nerve
sensory information to
Skin
cerebral cortex
Sensory
receptors
Cervical spinal cord

Muscle
White matter
Motor output Gray matter
Interneuron
Motor neuron
cell body
© 2018 Pearson Education, Ltd.
 Peripheral Nervous System (PNS)