Principles of Anatomy and Physiology: Nervous Tissue PDF

Summary

This document is a chapter on nervous tissue from a textbook called Principles of Anatomy and Physiology, 16th edition. It provides an introduction to the nervous system, its branches, and different types of cells found in nervous tissue. The document includes diagrams and figures to illustrate the discussed topics.

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Principles of Anatomy
and Physiology
Gerard Tortora and Bryan Derrickson
Sixteenth Edition

Chapter 12

Nervous Tissue
Introduction
The purpose of the chapter is to:
1. Understand how the nervous system
helps to keep controlled conditions
within limits that maintain health and
homeostasis
2. Learn about the different branches of
the nervous system
3. Identify and describe the various types
of cells that are found in nervous tissue

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Functions of the Nervous
System
To collect information from the
environment, outside and inside the body
To integrate and process the information
To act upon the information by
coordinating the actions of muscles and
glands (the effectors of the nervous
system) to bring about the appropriate
response or to maintain homeostasis

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Nervous System Overview
Interactions Animation:
Introduction to Structure and Function of the N
ervous System

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Layout of the Nervous
System

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Organization of the Nervous
System

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Functions of the Nervous
System
Sensory
 Sense changes through sensory receptors
Motor
 Respond to stimuli
Integrative
 Analyze incoming sensory information,
store some aspects, and make decisions
regarding appropriate behaviors

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Organization of the Nervous
System Interactions
Animation:
Nervous System

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Histology of Nervous Tissue

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Nervous Tissue
Anatomy Overview:
Neurons and Nerves
Neuroglia

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Neurons
Neurons
 Electrically
excitable
 Cellular
structures

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Structural Classification of
Neurons
Neurons can be classified based on the
number of processes extending from the cell
body

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Examples of Dendritic
Branching

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Functional Classification of Neurons (1 of
2)

Neurons can be classified based on the
direction of nerve impulse propagation
 Sensory/afferent neurons
 Motor/efferent neurons
 Inter/association neurons

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Functional Classification of
Neurons (2 of 2)

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Neuron Structure and
Function Interactions
Animation:
Types of Neurons

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Neuroglia
Neuroglia
 Not electrically excitable
 Make up about half the volume of the
nervous system
 Can multiply and divide
 6 kinds total (4 in CNS, 2 in PNS)

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Neuroglia of the CNS

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Neuroglia of the PNS

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Myelination of Neurons (1 of 2)

The myelin sheath is produced by Schwann
cells (PNS) and oligodendrocytes (CNS) and it
surrounds the axons of most neurons

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Myelination of Neurons (2 of 2)

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Gray Matter vs. White
Matter

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 Electrical Signals in
Neurons: An Overview

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Electrical Signals in Neurons
Excitable cells communicate with each other
via action potentials or graded potentials
Action potentials (AP) allow communication
over short and long distances whereas
graded potentials (GP) allow communication
over short distances only
 Production of an AP or a GP depends upon
the existence of a resting membrane
potential and the existence of certain ion
channels

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Excitable Cells and the
Resting Membrane Potential
3D Physiology:
Membrane Potentials: Excitable Cells and the
Resting Membrane Potential

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Graded Potentials & Action
Potentials

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3D Physiology
Membrane Potentials: Graded and Action Pot
entials

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Ion Channels in Neurons (1 of 5)

Leak channels alternate between open and
closed
K+ channels are more numerous than Na+
channels

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Ion Channels in Neurons (2 of 5)

Ligand-gated channels respond to chemical
stimuli (ligand binds to receptor)

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Ion Channels in Neurons (3 of 5)

Mechanically-gated channels respond to
mechanical vibration or pressure stimuli

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Ion Channels in Neurons (4 of 5)

Voltage-gated channels respond to direct
changes in membrane potential

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Ion Channels in Neurons (5 of 5)

Type of Ion Description Location
Channel
Leak channels Gated channels that Found in nearly all cells,
randomly open and close. including dendrites, cell bodies,
and axons of all types of
neurons.
Ligand-gated Gated channels that open Dendrites of some sensory
channels in response to binding of neurons such as pain receptors
ligand (chemical) stimulus. and dendrites and cell bodies of
interneurons and motor
neurons.
Mechanically- Gated channels that open Dendrites of some sensory
gated channels in response to mechanical neurons such as touch
stimulus (such as touch, receptors, pressure receptors,
pressure, vibration, or and some pain receptors.
tissue stretching).
Voltage-gated Gated channels that open Axons of all types of neurons.
channels in response to voltage
stimulus (change
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membrane potential).
Resting Membrane Potential

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Membrane Potentials
Interactions Animation:
Membrane Potentials

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Resting Membrane Potential
The membrane of a non-conducting neuron is
positive outside and negative inside. This is
determined by:
1. Unequal distribution of ions across the
plasma membrane and the selective
permeability of the neuron’s membrane
to Na+ and K+
2. Most anions cannot leave the cell
3. Na+/K+ pumps

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Resting Membrane Potential: Voltage
Difference

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Factors Contributing to Resting Membrane
Potential

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Graded Potentials (1 of 2)

Small deviations in
resting membrane
potential

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Graded Potentials (2 of 2)

A graded potential occurs in response to the
opening of a mechanically-gated or ligand-
gated ion channel

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Graded Potentials: Stimulus
Strength
The amplitude of a graded potential depends
on the stimulus strength

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Graded Potentials:
Summation
Graded potentials can be added together to
become larger in amplitude

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Action Potentials

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Action Potentials (1 of 2)

An action potential is a sequence of rapidly
occurring events that decrease and eventually
reverse the membrane potential
(depolarization) and eventually restore it to
the resting state (repolarization)

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Action Potentials (2 of 2)

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Action Potentials: Stimulus
Strength
Action potentials can only occur if the
membrane potential reaches threshold

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Action Potentials: the Status of Na+ and K+
Voltage-Gated Channels

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Comparison of Graded & Action
Potentials (1 of 2)

Characteristi Graded Potentials Action Potentials
c
Origin Arise mainly in dendrites Arise at trigger zones and
and cell body. propagate along axon.
Types of Ligand-gated or Voltage-gated channels for
channels mechanically-gated ion Na+ and K+.
channels.
Conduction Decremental (not Propagate and thus permit
propagated); permit communication over longer
communication over short distances.
distances.
Amplitude Depending on strength of All or none; typically about
(size) stimulus, varies from less 100 mV.
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Comparison of Graded & Action
Potentials (2 of 2)

Characteristi Graded Potentials Action Potentials
c
Duration Typically longer, ranging Shorter, ranging from 0.5
from several milliseconds to 2 msec.
to several minutes.
Polarity May be hyperpolarizing Always consist of
(inhibitory to generation depolarizing phase
of action potential) or followed by repolarizing
depolarizing (excitatory phase and return to resting
to generation of action membrane potential.
potential).
Refractory Not present; summation Present; summation cannot
period can occur. occur.

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Propagation of Action
Potentials
In order for communication to occur from
one body part to another, action potentials
must travel from where they arise at the
trigger zone to the axon terminals
Action potentials do not die out; they keep
their strength as they spread across the
membrane of a neuron

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Continuous vs. Saltatory
Conduction

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Factors That Affect
Propagation

Speed
Axon diameter
Amount of myelination
Temperature

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Factors That Affect
Propagation Speed
Interactions Animation:
Myelination and Conduction Rates

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Signal Transmission at
Synapses

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Signal Transmission at
Synapses
A synapse is the junction between neurons or
between a neuron and an effector
 Electrical Synapse
Gap junctions connect cells and allow
the transfer of information to
synchronize the activity of a group of
cells
 Chemical Synapse
One-way transfer of information from a
presynaptic neuron to a postsynaptic
neuron
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Synapses Between Neurons

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Events at the Synapse
Interactions Animation:
Events at the Synapse

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Signal Transmission at a
Chemical Synapse

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Synapses and
Neurotransmitter Action 3D
Physiology:
Synapses and Neurotransmitter Action

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Postsynaptic Potentials
Excitatory postsynaptic potentials
 A depolarizing postsynaptic potential
Inhibitory postsynaptic potentials
 A hyperpolarizing postsynaptic potential
A postsynaptic neuron can receive many
signals at once

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Structure of Neurotransmitter
Receptors
Neurotransmitters at chemical synapses
cause either an excitatory or inhibitory
graded potential
Neurotransmitter receptors have two
structures
 Ionotropic receptors
 Metabotropic receptors

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Ionotropic & Metabotropic
Receptors

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Removal of
Neurotransmitter
Neurotransmitter can be removed from the
synaptic cleft by:
1. Diffusion
2. Enzymatic degradation
3. Uptake into cells

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Summation
If several presynaptic end bulbs release their
neurotransmitter at about the same time, the
combined effect may generate a nerve
impulse due to summation
 Summation may be spatial or temporal

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Spatial Summation

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Temporal Summation

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Summation of Postsynaptic
Potentials

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Summary of Neuronal Structure and
Function (1 of 2)

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Summary of Neuronal Structure and
Function (2 of 2)

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Neurotransmitters

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Neurotransmitters (1 of 2)

Small molecule neurotransmitters
 Acetylcholine
 Amino acids
 Biogenic amines
 ATP and other purines
 Nitric oxide
 Carbon monoxide

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Neurotransmitters (2 of 2)

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Neuropeptides (1 of 3)

Neuropeptides
 Substance P
 Enkephalins
 Endorphins
 Dynorphins
 Hypothalamic
releasing and
inhibiting hormones
 Angiotensin II
 Cholecystokinin
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Neuropeptides (2 of 3)

Substance Description
Substance P Found in sensory neurons, spinal cord pathways, and
parts of brain associated with pain; enhances perception
of pain.
Enkephalins Inhibit pain impulses by suppressing release of
substance P; may have role in memory and learning,
control of body temperature, sexual activity, and mental
illness.
Endorphins Inhibit pain by blocking release of substance P; may
have role in memory and learning, sexual activity,
control of body temperature, and mental illness.
Dynorphins May be related to controlling pain and registering
emotions.
Hypothalamic Produced by hypothalamus; regulate release of
releasing and hormones by anterior pituitary.
inhibiting
hormones
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Neuropeptides (3 of 3)

Substance Description
Angiotensin II Stimulates thirst; may regulate blood pressure in brain.
As a hormone, causes vasoconstriction and promotes
release of aldosterone, which increases rate of salt and
water reabsorption by kidneys.
Cholecystokinin Found in brain and small intestine; may regulate feeding
(CCK) as a “stop eating” signal. As a hormone, regulates
pancreatic enzyme secretion during digestion, and
contraction of smooth muscle in gastrointestinal tract.
Neuropeptide Y Stimulates food intake; may play a role in the stress
response.

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Neural Circuits

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Neural Circuits
A neural circuit is a functional group of
neurons that process specific types of
information
Types of circuits
 Simple series
 Diverging
 Converging
 Reverberating
 Parallel after-discharge

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Neural Circuits: Diverging &
Converging

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Neural Circuits: Reverberating & Parallel
After-Discharge

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Regeneration & Repair of Nervous Tissue

Although the nervous system exhibits
plasticity, neurons have a limited ability to
regenerate themselves
 Plasticity – the capability to change based
on experience
 Regenerate – the capability to replicate or
repair

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Neurogenesis in the CNS
In the CNS, there is little or no repair due to:
 Inhibitory influences from neuroglia,
particularly oligodendrocytes
 Absence of growth-stimulating cues that
were present during fetal development
 Rapid formation of scar tissue

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Damage and Repair in the
CNS (1 of 2)
In the PNS repair is possible if the cell body is
intact, Schwann cells are functional, and scar
tissue formation does not occur too rapidly
Steps involved in the repair process are:
 Chromatolysis
 Wallerian degeneration
 Formation of a regeneration tube

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Damage and Repair in the
CNS (2 of 2)

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Disorders
Multiple Sclerosis
Epilepsy
Excitotoxicity
Depression

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Copyright
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