1. THE NERVOUS SYSTEM
PART 1
CHAPTER 11

2. Nervous System
Figure 11.1

3. The master controlling and communicating system of the body Functions
Nervous System
The master controlling and communicating system of the body
Functions
Sensory input – monitoring stimuli occurring inside and outside the body
Integration – interpretation of sensory input
Motor output – response to stimuli by activating effector organs

4. Organization of the Nervous System
Central nervous system (CNS)
Brain and spinal cord
Integration and command center
Peripheral nervous system (PNS)
Paired spinal and cranial nerves
Carries messages to and from the spinal cord and brain

5. Levels of Organization

6. Peripheral Nervous System (PNS): Two Functional Divisions
Sensory (afferent) division
Sensory afferent fibers – carry impulses from skin, skeletal muscles, and joints to the brain
Visceral afferent fibers – transmit impulses from visceral organs to the brain
Motor (efferent) division
Transmits impulses from the CNS to effector organs

7. Motor Division: Two Main Parts
Somatic nervous system
Conscious control of skeletal muscles
Autonomic nervous system (ANS)
Regulates smooth muscle, cardiac muscle, and glands
Divisions – sympathetic and parasympathetic

8. Peripheral Nervous System
Central
Nervous
System
brain
spinal
cord
AFFERENT
EFFERENT
sensory
nerves
axons of
motor nerves
somatic
subdivision
(motor functions)
autonomic
subdivision
(visceral
functions)
para-
sympathetic
sympathetic
Peripheral Nervous System

9. Autonomic nervous system (ANS)

10. Histology of Nerve Tissue
The two principal cell types of the nervous system are:
Neurons – excitable cells that transmit electrical signals
Supporting cells – cells that surround and wrap neurons

11. Supporting Cells: Neuroglia
The supporting cells (neuroglia or glial cells):
Provide a supportive scaffolding for neurons
Segregate and insulate neurons
Guide young neurons to the proper connections
Promote health and growth

12. Most abundant, versatile, and highly branched glial cells
Astrocytes
Most abundant, versatile, and highly branched glial cells
They cling to neurons and their synaptic endings, and cover capillaries
Functionally, they:
Support and brace neurons
Anchor neurons to their nutrient supplies
Guide migration of young neurons
Control the chemical environment

13. Astrocytes
Figure 11.3a

14. Microglia and Ependymal Cells
Microglia – small, ovoid cells with spiny processes
Phagocytes that monitor the health of neurons
Ependymal cells – range in shape from squamous to columnar
They line the central cavities of the brain and spinal column

15. Microglia and Ependymal Cells
Figure 11.3b, c

16. Oligodendrocytes, Schwann Cells, and Satellite Cells
Oligodendrocytes – branched cells that wrap CNS nerve fibers
Schwann cells (neurolemmocytes) – surround fibers of the PNS
Satellite cells surround neuron cell bodies with ganglia

17. Oligodendrocytes, Schwann Cells, and Satellite Cells
Figure 11.3d, e

18. Structural units of the nervous system
Neurons (Nerve Cells)
Structural units of the nervous system
Composed of a body, axon, and dendrites
Long-lived, amitotic, and have a high metabolic rate
Their plasma membrane functions in:
Electrical signaling
Cell-to-cell signaling during development

19. blood
vessels
axon of one neuron
many neurons bundled together inside a connective tissue sheath
outer connective tissue of one nerve
myelin sheath
unsheathed node
axon

20. receptor endings
cell body
cell body
peripheral axon
axon ending
cell body
axon
axon endings
axon
dendrites
Sensory Neuron
Interneuron
Motor Neuron

21. Neurons (Nerve Cells)
Figure 11.4b

22. Nerve Cell Body (Perikaryon or Soma)
Contains the nucleus and a nucleolus
Is the major biosynthetic center
Is the focal point for the outgrowth of neuronal processes
Has no centrioles (hence its amitotic nature)
Has well-developed Nissl bodies (rough ER)
Contains an axon hillock – cone-shaped area from which axons arise

23. Armlike extensions from the soma
Processes
Armlike extensions from the soma
Called tracts in the CNS and nerves in the PNS
There are two types: axons and dendrites

24. Dendrites of Motor Neurons
Short, tapering, and diffusely branched processes
They are the receptive, or input, regions of the neuron
Electrical signals are conveyed as graded potentials (not action potentials)

25. Slender processes of uniform diameter arising from the hillock
Axons: Structure
Slender processes of uniform diameter arising from the hillock
Long axons are called nerve fibers
Usually there is only one unbranched axon per neuron
Rare branches, if present, are called axon collaterals
Axonal terminal – branched terminus of an axon

26. Generate and transmit action potentials
Axons: Function
Generate and transmit action potentials
Secrete neurotransmitters from the axonal terminals
Movement along axons occurs in two ways
Anterograde — toward axonal terminal
Retrograde — away from axonal terminal

27. Myelin Sheath
Whitish, fatty (protein-lipoid), segmented sheath around most long axons
It functions to:
Protect the axon
Electrically insulate fibers from one another
Increase the speed of nerve impulse transmission

28. Myelin Sheath and Neurilemma: Formation
Formed by Schwann cells in the PNS
A Schwann cell:
Envelopes an axon in a trough
Encloses the axon with its plasma membrane
Has concentric layers of membrane that make up the myelin sheath
Neurilemma – remaining nucleus and cytoplasm of a Schwann cell

30. Schwann cell

31. Myelin Sheath and Neurilemma: Formation
Figure 11.5a-c

32. Nodes of Ranvier (Neurofibral Nodes)
Gaps in the myelin sheath between adjacent Schwann cells
They are the sites where axon collaterals can emerge

33. A Schwann cell surrounds nerve fibers but coiling does not take place
Unmyelinated Axons
A Schwann cell surrounds nerve fibers but coiling does not take place
Schwann cells partially enclose 15 or more axons

34. Amyotrophic Lateral Sclerosis ALS
Amyotrophic Lateral Sclerosis (ALS), nicknamed Lou Gehrig’s disease after its legendary victim, is a progressive, ultimately fatal disorder that damages the motor neurons. While motor neuron damage does not affect the senses, personality, thought, or memory, it does weaken and eventually paralyze the body.
What causes amyotrophic lateral sclerosis?
The human brain is an extremely complex organ composed of billions of cells called neurons. Different groups of neurons perform different functions, such as controlling movement, processing sensory information, and making decisions. ALS somehow damages the motor neurons, which control movement, and when this happens, the brain can no longer direct the muscles of the body.

35. Both myelinated and unmyelinated fibers are present
Axons of the CNS
Both myelinated and unmyelinated fibers are present
Myelin sheaths are formed by oligodendrocytes
Nodes of Ranvier are widely spaced
There is no neurilemma

36. Regions of the Brain and Spinal Cord
White matter – dense collections of myelinated fibers
Gray matter – mostly soma and unmyelinated fibers

37. Neuron Classification
Structural:
Multipolar — three or more processes
Bipolar — two processes (axon and dendrite)
Unipolar — single, short process

38. Neuron Classification
Functional:
Sensory (afferent) — transmit impulses toward the CNS
Motor (efferent) — carry impulses away from the CNS
Interneurons (association neurons) — shuttle signals through CNS pathways

39. Comparison of Structural Classes of Neurons
Table

40. Comparison of Structural Classes of Neurons
Table

41. Comparison of Structural Classes of Neurons
Table