1. Fundamentals of Anatomy & Physiology
Eleventh Edition
Chapter 12
Nervous Tissue
Lecture Presentation by
Deborah A. Hutchinson
Seattle University

2. Learning Outcomes
12-1 Describe the anatomical and functional divisions of the nervous system Sketch and label the structure of a typical neuron, describe the functions of each component, and classify neurons on the basis of their structure and function Describe the locations and functions of the various types of neuroglia Explain how the resting membrane potential is established and maintained and how the membrane potential can change.

3. Learning Outcomes
12-5 Describe the events involved in the generation and propagation of an action potential and the factors involved in determining the speed of action potential propagation Describe the structure of a synapse, and explain the mechanism involved in synaptic activity Describe the major types of neurotransmitters and neuromodulators, and discuss their effects on postsynaptic membranes Discuss the interactions that enable information processing to occur in nervous tissue.

4. Fundamentals of Anatomy & Physiology
Eleventh Edition
Chapter 12
Quiz 1:
Figures 12.2 and 12.5

5. Figure 12–2 The Anatomy of a Typical Neuron.
© 2018 Pearson Education, Inc.
Figure 12–2 The Anatomy of a Typical Neuron.
Dendrites
Perikaryon
Nucleus
Cell body
Telodendria
Nissl bodies (RER
and free ribosomes)
Dendritic branches
Mitochondrion
Axon a
This color-coded diagram shows the
four general regions of a neuron.
Axon hillock
Initial segment
of axon
Axolemma
Axon
Telodendria
Direction of action potential
Golgi apparatus
Axon
terminals
Neurofilament
Nucleolus
Nucleus
Dendrite
See Figure 12–15
Presynaptic cell b
Details of neuron structure and directional
movement of an action potential.
Postsynaptic cell

6. Figure 12–5 Neuroglia in the CNS.
© 2018 Pearson Education, Inc.
Central canal
Gray matter
White matter
Figure 12–5 Neuroglia in the CNS.
CENTRAL CANAL
Neuroglia in the CNS
Ependymal cell
Ependymal cells are
simple cuboidal
epithelial cells that line
fluid-filled passageways
within the brain and
spinal cord.
Neuron
Gray
matter
Neuron
Microglial cell
Microglia are phagocytes
that move through
nervous tissue removing
unwanted substances.
Oligodendrocyte
Myelinated
axons
Oligodendrocytes are
cells with sheet-like
processes that wrap
around axons.
Internode
Astrocyte
Astrocytes are star-
shaped cells with
projections that anchor
to capillaries. They form the blood brain barrier, which isolates the CNS from the general circulation.
Myelin
(cut)
White
matter
Axon
Axolemma
Node
Unmyelinated
axon
Basement
membrane
Capillary
A diagram of nervous tissue in the CNS showing relationships between neuroglia and neurons

7. HOmework

8. Suggested Homework Monday In class: Notes on 12.1 Home:
Review 12.1 Notes
Notes on 12.2
Review Quiz Figures (2/7)
Tuesday
In class: Review/Mark 12.1 and 12.2 Notes
Notes on 12.3
Review/Study Quiz Figures (2/7)

9. Fundamentals of Anatomy & Physiology
Eleventh Edition
Chapter 12
Nervous Tissue
Lecture Presentation by
Deborah A. Hutchinson
Seattle University

10. Organization

11. An Introduction to the Nervous System
Includes various organs
Brain and spinal cord
Receptors of sense organs (eyes, ears, etc.)
Nerves that connect to other systems
Nervous tissue contains two kinds of cells
Neurons for intercellular communication
Neuroglia (glial cells)
Essential to survival and function of neurons
Preserve structure of nervous tissue

12. Divisions of the Nervous System
Anatomical divisions of the nervous system
Central nervous system
Peripheral nervous system

13. Divisions of the Nervous System
Central nervous system (CNS)
Brain and spinal cord
Consists of nervous tissue, connective tissue, and blood vessels
Functions to process and coordinate sensory data from inside and outside body
Motor commands control activities of peripheral organs (e.g., skeletal muscles)
Higher functions of brain include intelligence, memory, learning, and emotion

14. Divisions of the Nervous System
Peripheral nervous system (PNS)
Includes all nervous tissue outside CNS and ENS
Delivers sensory information to the CNS
Carries motor commands to peripheral tissues
Nerves (peripheral nerves)
Bundles of axons with connective tissues and blood vessels
Carry sensory information and motor commands
Cranial nerves connect to brain
Spinal nerves attach to spinal cord

15. Figure 12–1 An Overview of the Nervous System.
Central Nervous System (CNS)
(brain and spinal cord)
Information processing
integrates, processes, and
coordinates sensory input
and motor commands.
Peripheral Nervous
System (PNS)
(nervous tissue
outside the CNS
and the ENS)
Sensory information
within
afferent division
Motor commands within
efferent division
Somatic nervous
system (SNS)
Autonomic
nervous system (ANS)
Parasympathetic
division
Sympathetic
division
Smooth muscle
Special sensory
receptors
Visceral sensory
receptors
Somatic sensory
receptors
Cardiac muscle
monitor smell,
taste, vision,
balance, and
hearing
monitor internal
organs
monitor skeletal
muscles, joints,
and skin surface
Glands
Skeletal
muscle
Adipose tissue
Receptors
Effectors

16. Divisions of the Nervous System
Functional divisions of the PNS
Afferent division
Carries sensory information
From receptors in peripheral tissues and organs to CNS
Efferent division
Carries motor commands
From CNS to muscles, glands, and adipose tissue

17. Divisions of the Nervous System
Functional divisions of the PNS
Receptors
Detect changes or respond to stimuli
May be neurons or specialized cells
May be single cells or complex sensory organs (e.g., eyes, ears)
Effectors
Target organs that respond to motor commands

18. Divisions of the Nervous System
Efferent division of PNS
Somatic nervous system (SNS)
Controls skeletal muscle contractions
Both voluntary and involuntary (reflexes)

19. Divisions of the Nervous System
Efferent division of PNS
Autonomic nervous system (ANS)
Controls subconscious actions, contractions of smooth and cardiac muscle, and glandular secretions
Sympathetic division has a stimulating effect
Parasympathetic division has a relaxing effect

20. Divisions of the Nervous System
Enteric nervous system (ENS)
100 million neurons in walls of digestive tract
As many or more than in spinal cord
Use the same neurotransmitters as the brain
Initiates and coordinates visceral reflexes locally
Without instructions from CNS
Can be influenced by ANS

21. Figure 12–1 An Overview of the Nervous System.
Central Nervous System (CNS)
(brain and spinal cord)
Information processing
integrates, processes, and
coordinates sensory input
and motor commands.
Peripheral Nervous
System (PNS)
(nervous tissue
outside the CNS
and the ENS)
Sensory information
within
afferent division
Motor commands within
efferent division
Somatic nervous
system (SNS)
Autonomic
nervous system (ANS)
Parasympathetic
division
Sympathetic
division
Smooth muscle
Special sensory
receptors
Visceral sensory
receptors
Somatic sensory
receptors
Cardiac muscle
monitor smell,
taste, vision,
balance, and
hearing
monitor internal
organs
monitor skeletal
muscles, joints,
and skin surface
Glands
Skeletal
muscle
Adipose tissue
Receptors
Effectors

22. Neuron Anatomy

23. Neurons Neurons Basic functional units of the nervous system
Send and receive signals
Function in communication, information processing, and control
Cell body (soma)
Large nucleus and nucleolus
Perikaryon (cytoplasm)
Mitochondria (produce energy)
RER and ribosomes (synthesize proteins)

24. Neurons Cytoskeleton of perikaryon Neurofilaments and neurotubules
Similar to intermediate filaments and microtubules
Neurofibrils
Bundles of neurofilaments that provide support for dendrites and axon
Nissl bodies
Dense areas of RER and ribosomes in perikaryon
Make nervous tissue appear gray (gray matter)
Neurons
Neurons

25. Neurons
Dendrites
Short and highly branched processes extending from cell body
Dendritic spines
Fine processes on dendrites
Receive information from other neurons
80–90 percent of neuron surface area

26. Neurons Axon Single, long cytoplasmic process
Propagates electrical signals (action potentials)
Axoplasm
Cytoplasm of axon
Contains neurofibrils, neurotubules, enzymes, and organelles

27. Figure 12–2a The Anatomy of a Typical Neuron.
Dendrites
Perikaryon
Cell body
Telodendria
Nucleus
Axon a
This color-coded diagram shows the
four general regions of a neuron.

28. Neurons Structures of the axon Axolemma Plasma membrane of the axon
Covers the axoplasm
Initial segment
Base of axon
Axon hillock
Thick region that attaches initial segment to cell body

29. Figure 12–2b The Anatomy of a Typical Neuron.
Nissl bodies (RER
and free ribosomes)
Dendritic branches
Mitochondrion
Axon hillock
Initial segment
of axon
Axolemma
Axon
Telodendria
Direction of action potential
Golgi apparatus
Axon
terminals
Neurofilament
Nucleolus
Nucleus
Dendrite
See Figure 12–15 b
Details of neuron structure and directional
movement of an action potential.
Presynaptic cell
Postsynaptic cell

30. Neurons Structures of the axon Collaterals Branches of the axon
Telodendria
Fine extensions of distal axon
Axon terminals (synaptic terminals)
Tips of telodendria

31. Neurons Axonal (axoplasmic) transport
Movement of materials between cell body and axon terminals
Materials move along neurotubules within axon
Powered by mitochondria, kinesin, and dynein

32. Classification of Neurons
Structural and Functional
Classification of Neurons

33. Figure 12–3 Structural Classifications of Neurons.
Anaxonic neuron b
Bipolar neuron c
Unipolar neuron d
Multipolar neuron
Anaxonic neurons have more
than two processes, and
they may all be dendrites;
axons are not obvious.
Bipolar neurons have
two processes
separated by the cell
body.
Unipolar neurons have a
single elongated process,
with the cell body located
off to the side.
Multipolar neurons have
more than two processes;
there is a single axon and
multiple dendrites.
Dendrites
Dendrites
Initial
segment
Dendritic
branches
Cell body
Axon
Dendrite
Cell body
Cell
Axon
body
Cell
body
Axon
Axon
Axon
terminals
Axon
terminals
Axon
terminals

34. Structural Classification of Neurons
Anaxonic neurons
Small
All cell processes look similar
Found in brain and special sense organs

35. Structural Classification of Neurons
Bipolar neurons
Small and rare
One dendrite and one axon
Found in special sense organs (sight, smell, hearing)

36. Structural Classification of Neurons
Unipolar neurons (pseudounipolar neurons)
Axon and dendrites are fused
Cell body to one side
Most sensory neurons of PNS

37. Structural Classification of Neurons
Multipolar neurons
Have one long axon and two or more dendrites
Common in the CNS
All motor neurons that control skeletal muscles

38. Functional Classification of Neurons
Functional classifications of neurons
Sensory neurons
Motor neurons
Interneurons

39. Functional Classification of Neurons
Sensory neurons (afferent neurons)
Unipolar
Cell bodies grouped in sensory ganglia
Processes (afferent fibers) extend from sensory receptors to CNS
Somatic sensory neurons
Monitor external environment
Visceral sensory neurons
Monitor internal environment

40. Functional Classification of Neurons
Types of sensory receptors
Interoceptors
Monitor internal systems (e.g., digestive, urinary)
Internal senses (stretch, deep pressure, pain)
Exteroceptors
Monitor external environment (e.g., temperature)
Complex senses (e.g., sight, smell, hearing)
Proprioceptors
Monitor position and movement of skeletal muscles and joints

41. Functional Classification of Neurons
Motor neurons (efferent neurons)
Carry instructions from CNS to peripheral effectors
Via efferent fibers (axons)
Somatic motor neurons of SNS
Innervate skeletal muscles
Visceral motor neurons of ANS
Innervate all other peripheral effectors
Smooth and cardiac muscle, glands, adipose tissue

42. Functional Classification of Neurons
Motor neurons
Signals from CNS to visceral effectors cross autonomic ganglia that divide axons into
Preganglionic fibers
Postganglionic fibers

43. Functional Classification of Neurons
Interneurons
Most are in brain and spinal cord
Some in autonomic ganglia
Located between sensory and motor neurons
Responsible for
Distribution of sensory information
Coordination of motor activity
Involved in higher functions
Memory, planning, learning

44. Suggested Homework Tuesday In class: Revise 12.1 and 12.2 Notes
Actively Read 12.3
Review Guide on Anatomy
eText
Video (on Teacher Page)
PAL – Histology – Nervous Tissue
Home:
Finish Notes on 12.3
Review/Study Quiz Figures (2/7)

46. Neuroglia Neuroglia Support and protect neurons
Make up half the volume of the nervous system
Many types in CNS and PNS

47. Neuroglia Types of neuroglia in the CNS Astrocytes Ependymal cells
Oligodendrocytes
Microglia

48. Neuroglia Astrocytes Have large cell bodies with many processes
Function to
Maintain blood brain barrier (BBB)
Create three-dimensional framework for CNS
Repair damaged nervous tissue
Guide neuron development
Control interstitial environment

49. Neuroglia Ependymal cells
Form epithelium that lines central canal of spinal cord and ventricles of brain
Produce and monitor cerebrospinal fluid (CSF)
Have cilia that help circulate CSF

50. Neuroglia Oligodendrocytes Have small cell bodies with few processes
Many cooperate to form a myelin sheath
Myelin insulates myelinated axons
Increases speed of action potentials
Makes nerves appear white

51. Neuroglia Where axons may branch Oligodendrocytes
Internodes—myelinated segments of axon
Nodes (nodes of Ranvier) lie between internodes
Where axons may branch
White matter
Regions of CNS with many myelinated axons
Gray matter of CNS
Contains unmyelinated axons, neuron cell bodies, and dendrites

52. Figure 12–5 Neuroglia in the CNS (Part 2 of 2).
Central canal
Gray matter
White matter
Neuroglia in the CNS
Oligodendrocyte
Oligodendrocytes are
cells with sheet-like
processes that wrap
around axons.
Myelinated
axons
Internode
Astrocyte
Astrocytes are star-
shaped cells with
projections that anchor
to capillaries. They form the blood brain barrier, which isolates the CNS from the general circulation.
Myelin
(cut)
White
matter
Axon
Axolemma
Node
Unmyelinated
axon
Basement
membrane
Capillary
A diagram of nervous tissue in the CNS showing relationships between neuroglia and neurons

53. Neuroglia Microglia Smallest and least numerous neuroglia
Have many fine- branched processes
Migrate through nervous tissue
Clean up cellular debris, wastes, and pathogens

54. Figure 12–5 Neuroglia in the CNS (Part 1 of 2).
Central canal
Gray matter
White matter
CENTRAL CANAL
Neuroglia in the CNS
Ependymal cell
Ependymal cells are
simple cuboidal epithelial
cells that line fluid-filled
passageways within the
brain and spinal cord.
Neuron
Gray
matter
Neuron
Microglial cell
Microglia are phagocytes
that move through
nervous tissue removing
unwanted substances.

55. Neuroglia Neuroglia of the PNS
Insulate neuronal cell bodies and most axons
Two types
Satellite cells
Schwann cells

56. Figure 12–4 An Introduction to Neuroglia (Part 2 of 2).
are found in
Peripheral Nervous System
contains
Satellite cells
Schwann cells
Surround neuron
cell bodies in
ganglia; regulate O2,
CO2, nutrient, and
neurotransmitter
levels around
neurons in ganglia
Surround all axons in
PNS; responsible for
myelination of
peripheral axons;
participate in repair
process after injury

57. Neuroglia Neuroglia of the PNS Satellite cells
Surround ganglia (clusters of neuronal cell bodies)
Regulate interstitial fluid around neurons

58. Neuroglia Neuroglia of the PNS Schwann cells (neurolemmocytes)
Form myelin sheath or indented folds of plasma membrane around axons
Neurolemma—outer surface of Schwann cell
A myelinating Schwann cell sheaths only one axon
Many Schwann cells sheath entire axon

59. A myelinated axon, showing the organization
Figure 12–6a Schwann Cells, Peripheral Axons, and Formation of the Myelin Sheath in the PNS (Part 2 of 2).
Schwann
cell nucleus
Myelin covering
internode
Neurolemma
Axon
Myelin sheath
TEM × 20,600 a
A myelinated axon, showing the organization
of Schwann cells along the length of the axon.

60. The enclosing of a group of unmyelinated axons by a
Figure 12–6b Schwann Cells, Peripheral Axons, and Formation of the Myelin Sheath in the PNS (Part 1 of 2).
Schwann
cell #1
Schwann
cell
Schwann
cell #2
Schwann
cell nucleus
Neurolemma
Axons
Schwann
cell #3
nucleus
Axons b
The enclosing of a group of unmyelinated axons by a
single Schwann cell. A series of Schwann cells is
required to cover the axons along their entire length.

61. The enclosing of a group of unmyelinated axons by a
Figure 12–6b Schwann Cells, Peripheral Axons, and Formation of the Myelin Sheath in the PNS (Part 2 of 2).
Neurolemma
Axons
Schwann
cell #3
nucleus
Axons
Unmyelinated axons
TEM × 27,625 b
The enclosing of a group of unmyelinated axons by a
single Schwann cell. A series of Schwann cells is
required to cover the axons along their entire length.

62. 1 2 3 c A Schwann cell first surrounds a portion of the axon within
Figure 12–6c Schwann Cells, Peripheral Axons, and Formation of the Myelin Sheath in the PNS. 1
A Schwann cell first surrounds a
portion of the axon within
a groove of its
cytoplasm. 2
The Schwann cell then begins to
rotate around the axon. 3
As the Schwann cell rotates, myelin
is wound around the axon in
multiple layers,
forming a tightly
packed
membrane.
Schwann
cell
Myelin
Axon
Schwann cell
cytoplasm c
Stages in the formation of a myelin sheath by a single Schwann cell along a portion of a single axon.

64. Neural Response to Injury
Neural responses to injuries
Wallerian degeneration
Axon distal to injury degenerates
Schwann cells
Form path for new growth
Wrap around new axon
Nerve regeneration in CNS
Limited by astrocytes, which
Produce scar tissue
Release chemicals that block regrowth

65. Figure 12–7 Peripheral Nerve Regeneration after Injury (Part 1 of 4).
Fragmentation of
axon and myelin
occurs in distal
stump.
Axon
Myelin
Proximal stump
Distal stump

66. Figure 12–7 Peripheral Nerve Regeneration after Injury (Part 2 of 4).
Schwann cells form
cord, grow into cut,
and unite stumps.
Macrophages
engulf
degenerating axon
and myelin.
Macrophage
Cord of proliferating Schwann cells

67. Figure 12–7 Peripheral Nerve Regeneration after Injury (Part 3 of 4).
Axon sends buds
into network of
Schwann cells
and then starts
growing along
cord of Schwann
cells.

68. Figure 12–7 Peripheral Nerve Regeneration after Injury (Part 4 of 4).
Axon continues to
grow into distal
stump and is
enclosed by
Schwann cells.