1. Fundamentals of the Nervous System and Nervous Tissue
Chapter 12

2. Introduction
The nervous system is the master controlling and communicating system of the body
It is responsible for all behavior
Along with the endocrine system it is responsible for regulating and maintaining body homeostasis
Cells of the nervous system communicate by means of electrical signals

3. Nervous System Functions
The nervous system has three overlapping functions
Gathering of sensory input
Integration or interpretation of sensory input
Causation of a response or motor output

4. Introduction Sensory input Integration Motor output
The nervous system has millions of sensory receptors to monitor both internal and external change
Integration
It processes and interprets the sensory input and makes decisions about what should be done at each moment
Motor output
Causes a response by activating effector organs (muscles and glands)

5. Organization There is only one, highly integrated nervous system
Basic divisions of the nervous system
Central Nervous Systems
Peripheral Nervous System

6. Organization
In order to discuss the nervous in smaller portions, for convenience the nervous system is divided into two parts
The central nervous system
Brain and spinal cord
Integrative and control centers
The peripheral nervous system
Spinal and cranial nerves
Communication lines between the CNS and the rest of the body

7. Organization of the Nervous System

8. Organization
The peripheral nervous system has two fundamental subdivisions
Sensory (afferent) division
Somatic and visceral sensory nerve fibers
Consists of nerve fibers carrying impulses to the central nervous system
Motor (efferent) division
Motor nerve fibers
Conducts impulses from the CNS to effectors
(glands and muscles)

9. Organization of the Nervous System

10. Organization
The motor division of the peripheral nervous system has two main subdivisions
The Somatic motor
Voluntary motor
Conducts impulses from the CNS to skeletal muscle
The Visceral motor
Involuntary motor
Conducts impulses from the CNS to cardiac muscles, smooth muscles, and glands
Equivalent to the autonomic nervous system (ANS)

11. Organization of the Nervous System

12. Peripheral Nervous System

13. Organization of the Nervous System
Somatic sensory
The sensory receptors that are spread widely throughout the outer tube of the body
These include the many senses experienced on the skin and in the body wall, such as touch, pain, pressure, vibration and temperature
Proprioception provides feedback from the stretch of the muscles, tendons and joint capsules - your “body sense”

14. Organization of the Nervous System
Somatic sensory
The special somatic senses are receptors are more localized and specialized
The special senses include; sight, hearing, balance, smell and taste.

15. Organization of the Nervous System
Visceral sensory
The general visceral senses include stretch, pain, and temperature which can be felt widely in the digestive and urinary tracts, reproductive organs, and other viscera
Sensations such as hunger and nausea are also general visceral sensations
The chemical senses such as taste and smell are considered by some as special visceral senses

16. Organization of the Nervous System
Somatic motor
The general somatic motor is part of the PNS that stimulates contraction of the skeletal muscle in the body
Also referred to as voluntary nervous system
Skeletal muscles are widely distributed throughout the body, and therefore there is no special somatic motor category

17. Organization of the Nervous System
Visceral motor
The general visceral motor part of the PNS regulates the contraction of smooth and cardiac muscle and secretion by the body’s many glands
General visceral motor neurons make up the autonomic nervous (ANS) which controls the function of the visceral organs

18. Organization of the Nervous System
Visceral motor
Because we generally have no voluntary control over such activities as the pumping of the heart and movement of food through the digestive tract
The ANS is also called the involuntary nervous system

19. Organization of ANS
The autonomic nervous system has two principle subdivisions
Sympathetic division
Mobilizes body systems during emergency situations
Parasympathetic division
Conserves energy
Promotes non-emergency functions
The two subdivisions bring about opposite effects on the same visceral organs
What one subdivision stimulates, the other inhibits

20. Nervous Tissue
The nervous system consists mostly of nervous tissue whose cells are densely packed and tightly intertwined
Nervous tissue is made up just two main types of cells
Neurons - the excitable cells that transmit electrical signals
Neuroglia - nonexcitable supporting cells that surround and wrap the neurons
Both cell types develop from the same embryonic tissues: neural tube and crest

21. The Neuron
The human body contains many billions of neurons which are the basic structural units of the nervous system
Neurons are highly specialized cells that conduct electrical signals from one part of the body to another
These signals are transmitted along the plasma membrane in the form of nerve impulses or action potentials

22. Neurons Neurons are the structural units of the nervous system
Neurons are highly specialized cells that conduct messages in the form of nerve impulses from one part of the body to another

23. The Neuron Special characteristics of neurons
They have extreme longevity. Neurons can and must function over a lifetime
They do not divide
As fetal neurons assume their roles as communication links in the nervous system, they lose their ability to undergo mitosis
Cells cannot be replaced if destroyed - Some limited exceptions do exist in the CNS as neural stem cells have been identified

24. The Neuron Special characteristics of neurons
They have an exceptionally high metabolic rate requiring continuous and abundant supplies of oxygen and glucose
Neurons cannot survive for more than a few minutes without oxygen

25. The Neuron Neurons are typically large, complex cells
Neurons vary in their structure but they all have two fundamental components
Neuron cell body
One or more processes

26. The Cell Body The cell body of the neuron is also called a soma
The cell bodies of different neurons vary widely in size (from 5 to 140 m in diameter)
However, all consist of a single nucleus surrounded by cytoplasm

28. The Cell Body
Typically large, complex cells, neurons have the following structures
Cell body
Nuclei
Chromatophilic (Nissl) bodies
Neurofibrils
Axon hillock
Cell processes
Dendrites
Axon
Myelin sheath or neurilemma

29. The Cell Body Cell Body Neuron Processes Nuclei
Chromatophilic (Nissl) bodies
Neurofibrils
Axon hillock
Neuron Processes
Dendrites
Axons
Myelin sheaths
Axon terminals

30. The Cell Body
In all but the smallest neurons, the nucleus is spherical and clear and contains a nucleolus near its center

31. The Cell Body
The cytoplasm contains all the usual cellular organelles with the exception of centrioles (not needed in amitotic cells) as well as Nissl bodies
These cellular organelles continually renew the membranes of the cell

32. The Cell Body
Neurofibrils are bundles of intermediate filaments that run in a network between chromatophilic bodies
These filaments keep the cell from being pulled apart when it is subjected to tensile forces

33. The Cell Body
The cell body is the focal point for the outgrowth of the neuron processes during embryonic development

34. The Cell Body
In most neurons, the plasma membrane of the cell body acts as a receptive surface that receives signals from other neurons

35. The Cell Body Most neuron cell bodies are located within the CNS
However, clusters of cell bodies called ganglia (singular ganglion) lie along the nerves in the PNS

36. Neuron Processes
Bundles of neuron processes in the CNS are called tracts
Bundles of neuron processes in the PNS are called nerves

38. Neuron Processes
Motor
neuron
Armlike processes extend from the cell bodies of all neurons
There are two types of processes
Dendrites
Axons

39. Neuron Processes
Motor
neuron
The cell processes of neurons are described here using a motor neuron
Motor neurons represent a typical neuron, but sensory neurons differ from the typical pattern

40. Dendrites
Dendrites are short, tapering, diffusely branching extensions from the cell body
Motor neurons have hundreds of dendrites clustering close to the cell body
Dendrites function as receptive cites providing an enlarged area for the reception of signals from other neurons
By definition, dendrites conduct electrical signals toward the cell body

41. Dendrites
Dendritic spines represent areas of close contact with other neurons
These electrical signals are not nerve impulses but are short distance signals call graded potentials

42. Axons Each neuron has only one axon
The axon arises from the cone shaped axon hillock
It narrows to form a slender process that stays uniform in diameter the rest of its length
Length varies; short or absent to 3 feet in length

43. Axons Each axon is called a nerve fiber
Axons are impulse generators and conductors that transmit nerve impulses away from the cell body

44. Axons
Chromatophilic bodies (Nissl) and the Golgi apparatus are absent from the axon and the axon hillock
Axons lack ribosomes and all organelles involved in protein synthesis, so they must receive their proteins from the cell body

45. Axons
Neurofilaments, actin microfilaments, and microtubules are especially evident in axons, where they provide structural strength
These cytoskeletal elements also aid in the transport of substances to and from the cell body as the axonal cytoplasm is recycled and renewed
The movement of substances along axons is called axonal transport

46. Axons
The axon of some neurons are short, but in others it can be extremely long
Motor neurons in the CNS have axons that must reach to the musculature that they control that might be 3-4 feet away
Any long axon is called a nerve fiber and travels in a group of fibers composing a nerve

47. Axons
Although axons branch far less frequently than dendrites, occasional branches do occur along their length
These branches, called axon collaterals, extend from the axon at almost right angles

48. Axons Axons branch profusely at its terminus
Ten thousand of these terminal branches per neuron is not unusual
These branches end in knobs called axon terminals or boutons

49. Axon
A nerve impulse is typically generated at the axon’s initial segment and is conducted along the axon to the axon terminals, where it causes the release of chemicals called neurotransmitters into the extracellular space
The neurotransmitters excite or inhibit the neurons or target organs with which the axon is in close contact

50. Axon
Axon diameter varies considerably among the different neurons of the body
Axons with larger diameters conduct impulses faster than those with smaller diameters
Neurons follow the law of physics: The resistance to the passage of an electrical current decreases as the diameter of any “cable” increases

51. Synapses The site at which neurons communicate is called a synapse
Most synapses in the nervous system transmit information through chemical messengers

52. Synapses
Some neurons in certain areas of the CNS transmit signals electrically through gap junctions

53. Synapses
Because signals pass across most synapses in one direction only, synapses determine the direction of information flow through the nervous system

54. Synapses
The neuron that conducts signals toward a synapse is called the presynaptic neuron; the neuron that transmits signals away from the synapse is called the postsynaptic neuron

55. Synapses
Most neurons in the CNS function as both presynaptic (information sending) and postsynaptic (information receiving) neurons, getting information from some neurons and dispatching it to others

56. Synapses There are two main types of synapses
Most synapses occur between the axon terminals of one neuron and the dendrites of another neuron
These are called axondendritic synapses

57. Synapses Many synapses also occur between axons and neuron cell bodies
These synapses are called axosomatic synapses

58. Synapses Synapses are elaborate cell junctions
This section shows axodendritic synapses because its structure is representative of both types of synapses

59. Synapses Structurally synapses are elaborate cell junctions
At the typical axodendritic synapse the presynaptic axon terminal contain synaptic vesicles

60. Synapses
Synaptic vesicles are membrane bound sacs filled with molecular neurotransmitters
These molecules transmit signals across the synapse

61. Synapses
Mitochondria are abundant in the axon terminal as the secretion of neurotransmitters requires a great deal of energy

62. Synapses
At the synapse, the plasma membranes of the two neurons are separated by a synaptic cleft
On the under surfaces of the opposing cell membranes are dense materials; the pre- and post- synaptic densities

63. Synapses
When an impulse travels along the axon of the presynaptic neuron, it signals the synaptic vesicles to fuse with the presynaptic membrane at the presynaptic density
The fused area then ruptures releasing neurotransmitter molecules to diffuse across the synaptic cleft and bind to the postsynaptic membrane at the post synaptic density

64. Synapse
The binding of the two membranes changes the membrane charge on the postsynaptic neuron, influencing the membrane’s ability to generate a nerve impulse

65. Signals Carried by Neurons
Neurons carry information via electrical signals called nerve impulses, or action potentials
Signals are relayed from neuron to neuron via chemical neurotransmitters
In essence an impulse is a reversal of electrical charge that travels rapidly along the neuronal membrane

66. Signals Carried by Neurons
In a resting (un-stimulated) neuron, the membrane is polarized which means that the inner cytoplasmic side is negatively charged with respect to its outer, extracellular side

67. Signals Carried by Neurons
In addition, the concentration of potassium ions (K+) is higher inside the neuron and the concentration of sodium ions (Na+) is higher outside the neuron

68. Signals Carried by Neurons
When a neuron is stimulated the permeability of the plasma membrane changes at the site of the stimulus, allowing Na+ ions to rush in.
As a result, the inner face of the membrane becomes less negative or depolarized

69. Signals Carried by Neurons
If the stimulus initiating the depolarization is strong enough, the membrane at the axon’s initial segment is depolarized, so that it is positively charged inside the axon and negatively charged outside

70. Signals Carried by Neurons
Once begun, this depolarization occurs all along the axon length
It is this wave of charge reversal that constitutes the nerve impulse

71. Signals Carried by Neurons
The impulse travels rapidly down the entire length of the axon without decreasing in strength

72. Signals Carried by Neurons
After the impulse has passed the membrane repolarizes itself

73. Signals Carried by Neurons
Neurons in the body receive stimuli either directly from the environment or from signals received at synapses
In signals received at synapses neurotransmitters released by presynaptic neurons alter the permeability of the postsynaptic membrane to certain ions

74. Signals Carried by Neurons
Synapses that result in an influx of positive ions into the postsynaptic neuron depolarize the neuron’s membrane and bring the neuron closer to impulse generation
These synapses are called excitatory synapses because they stimulate the postsynaptic neuron

75. Signals Carried by Neurons
Other synapses increase membrane polarization, making the external surface of the postsynaptic cell even more positive than it was
This makes the postsynaptic cell less likely to generate a nerve impulse
These types of synapses are called inhibitory synapses because they reduce the ability of the postsynaptic neuron to generate a nerve impulse

76. Signals Carried by Neurons
Thousands of excitatory and inhibitory synapses act on every neuron, competing to determine whether or not that neuron will generate an impulse

77. Classification of Neurons
Neurons can be classified structurally or functionally
Neurons are grouped structurally according to the number of processes that extend from the cell body
By this classification there are three types of neurons;
Multipolar
Bipolar
Unipolar

78. Classification of Neurons
Multipolar - many processes extend from cell body, all dendrites except one axon
Bipolar - Two processes extend from cell, one a fused dendrite, the other an axon
Unipolar - One process extends from the cell body and forms the peripheral and central process of the axon

79. Classification of Neurons
Multipolar neurons usually have a single axon and many dendrites
This type of neuron constitutes 99% of the neurons in the body

80. Classification of Neurons
Multipolar neurons have more than two processes
Most common type in humans
Major neuron of the CNS
Some neurons lack an axon

81. Classification of Neurons
Bipolar neurons have two processes that extend from opposite sides of the cell body
This rare type of neuron occurs in the special sensory organs

82. Classification of Neurons
Bipolar neurons are found only in special sense organs where they function as receptor cells
Examples include those found in the retina of the eye, inner ear, and epithelium of the olfactory mucosa
They are primarily sensory neurons

83. Classification of Neurons
Unipolar neurons have a short, single process that emerges from the cell body and divides like a “T” into two long branches

84. Classification of Neurons
Unipolar neurons have a single process that emerges from the cell body
The central process (axon) is more proximal to the CNS and the peripheral is closer to the PNS
Unipolar neurons are chiefly found in the ganglia of the peripheral nervous system
Function primarily as sensory neurons

85. Functional Classification
The functional classification scheme groups neurons according to the direction in which the nerve impulse travels relative to the CNS
Based on this criterion there are three types of neurons
Sensory neurons
Motor neurons
Interneurons

86. Functional Classification

87. Sensory Neurons
These afferent neurons make up the sensory division of the PNS
They transmit impulses toward the CNS from sensory receptors in the PNS

88. Sensory Neurons
Sensory neurons have their cell bodies in ganglia outside of the CNS
The single (unipolar) process is divided into the central process and the peripherial process

89. Sensory Neuron
The central process is clearly an axon because it carries a nerve impulse and carries that impulse away from the cell body which meet the criteria which define an axon
The peripheral by contrast carries nerve impulses toward the cell body which suggests that it is a dendrite
However, the basic convention is that the central process and the peripheral process are parts of a unipolar neuron

90. Motor Neurons
Neurons that carry impulses away from the CNS to effector organs (muscles and glands) are called motor or efferent neurons
Upper motor neurons are in the brain
Lower motor neurons are in PNS

91. Motor Neurons
Motor neurons are multipolar and their cell bodies are located in the CNS (except autonomic)
Motor neurons form junctions with effector cells, signaling muscle to contract or glands to secrete

92. Interneuron or Association Neurons
These neurons lie between the motor and sensory neurons
Form complex neural pathways
Confined to CNS
Make up 99.98% of the neurons of the body and are the principle neuron of the CNS

93. Interneuron Neurons Almost all interneurons are multipolar
Interneurons show great diversity in the size and branching patterns of their processes

94. Interneurons
The Pyramidal cell is the large neuron found in the primary motor cortex of the cerebrum
The Purkinje cell is from the cerebellum

95. Supporting Cells
All neurons associate closely with non-nervous supporting cells called neuroglia
Support cells of the CNS
Astrocytes
Microglial
Ependymal
Oligodendrocyte
Support cells of the PNS
Schwann cells
Satellite cells

96. Supporting Cells
While each support cell has a unique specific function, in general these cells provide a supportive scaffolding for neurons
In addition, they all cover nonsynaptic parts of the neurons thereby insulating the neurons and keeping the electrical activities of adjacent neurons from interfering with each other

97. Supporting Cells in the CNS
Like neurons, glial cells have branching processes and a central cell body
Neuroglia can be distinguished from neurons by their much smaller size and darker staining nuclei
They outnumber neurons in the CNS by a ratio of 10 to 1
Make up half of the mass of the brain
Unlike neurons, glial cells divide throughout one’s lifetime

99. Astrocytes Star shaped Most abundant type of glial cell
Radiating projections cling to neurons and capillaries, bracing the neurons to their blood supply
Astrocytes play a role in exchanges of ions between capillaries and neurons

100. Astrocytes
Astrocytes take up and release ions to control the environment around neurons
Concentrations of ions must be kept within narrow limits for nerve impulses to be generated & conducted
Astrocytes recapture and recycle potassium ions and released neuro- transmitters

101. Astrocytes
Astrocytes contact both the neuron and the capillary in order to sense when the neuron are highly active and releasing large amounts of neurotransmitters (glutamate)
Astrocytes then extract blood sugar from the capillaries they contact to obtain the energy they need to fuel the process of glutamate uptake

102. Astrocytes
Astrocytes also are involved with synapse formation in developing neural tissue, produce molecules necessary for neural growth (brain-derived trophic factor BDTF) and propagate calcium signals that may be involved in memory
Understanding the role of these abundant glial cells in neural functioning is an area of ongoing research

104. Microglial Smallest and least abundant type of neuroglial cell
The elongated cells have relatively long “thorny” processes
They are phagocytes, the macrophages of the CNS

105. Microglial
Microglial derive from blood cells and migrate to the CNS during embryonic and fetal development
Microglial engulf invading microogranisms and injured or dead neurons

106. Microglial
When invading micro- organisms are present or damaged neurons have died, the micro- glial transforms into a special type of macro- phage that protects the CNS by phagocytizing the microorganisms or neuronal debris
Important because cells of the immune system can enter CNS

108. Ependymal
CNS tissue originates in the embryo as a hollow neural tube and retains a central cavity throughout life
Form a simple epithelium that lines the central cavity of the spinal cord and brain

109. Ependymal
Forms a fairly permeable barrier between cerebrospinal fluid of those cavities and the cells of the CNS
Ependymal cells bear cilia that helps circulate the cerebrospinal fluid

111. Oligodendro- cytes Fewer branches than astrocytes
Cells wrap their cytoplasmic extensions tightly around the thicker neurons in the CNS
Produce insulating coverings called myelin sheaths

112. Neuroglia in the PNS There are two supporting cells in the PNS
Satellite cells
Schwann cells
These cells are similar in type and differ mainly in location

113. Satellite Cells
Somewhat flattened satellite cells surround cell bodies within ganglia
Thought to play some role in controlling the chemical environment of neurons with which they are associated, but function is largely unknown

114. Schwann Cells
Surround and form myelin sheaths around the larger nerve fibers in PNS
Similar to the oligodendrocytes of CNS
Schwann cells are vital to peripheral nerve fiber regeneration

115. Myelin Sheaths
Myelin sheaths are produced by oligo dendrocytes in the CNS and Schwann cells in the PNS
Myelin sheaths are segmented structures, each composed of the lipoprotein myelin and surround the thicker axons of the body

116. Myelin Sheaths
Each segment of myelin consists of a plasma membrane of a supporting cell rolled in concentric layers around the axon

117. Myelin Sheaths Myelin sheaths form an insulating layer that…
Prevents the leakage of electrical current from the axon
Increases the speed of impulse conduction
Makes impulse propagation more energy efficient

118. Myelin Sheaths in PNS
Myelin sheaths in the PNS are formed by Schwann cells
Myelin sheaths develop during the fetal period and continue to develop during the first year of postnatal life

119. Myelin Sheaths in the PNS
In forming, the cells indent to receive the axon and then wrap themselves around the axon repeatedly in a jellyroll fashion
Initially loose, the wrapping eventually squeeze the cytoplasm outward between cell membrane layers

120. Myelin Sheaths in the PNS
When the process is complete many concentric layers of Schwann cell plasma membrane wrap the axon in tightly packed coil of membranes
The nucleus and most of the cytoplasm of the Schwann cell end up just external to the myelin layers
This external material is called the neurilemma

121. Myelin Sheaths - PNS
Because the adjacent Schwann cells along a myelinated axon do not touch one another, there are gaps in the myelin sheath
These gaps called the Nodes of Ranvier, occur at regular intervals about 1mm apart

122. Myelin Sheaths - PNS
In myelinated axons, nerve impulses do not travel along the myelin-covered regions of the axonal membrane, but instead jumps from the membrane of one Node of Ranvier to the next greatly increasing impulse conduction

123. Myelin Sheaths in the PNS
Only thick, rapidly conducting axons are sheathed in myelin
Thin, slowly conducting axons lack a myelin sheath and are called unmyelinated axons

124. Myelin Sheaths in the PNS
In unmyelinated axons the Schwann cells surround the axons but do not wrap around them in concentric layers of membrane
A single Schwann cell can partly enclose 15 or more unmyelinated axons with each in a separate tubular recess on the surface of the cell

125. Myelin Sheath
Myelin increases the speed of transmission of nerve impulses
Myelinated axons transmit nerve impulses rapidly; 150 meters/second
Unmyelinated axons transmit quite slowly; 1 meter/second

126. Myelin Sheaths in the PNS
Unmyelinated axons are found in portions of the autonomic nervous system as well as in some sensory fibers

127. Myelin Sheaths of the PNS
Electron micrograph of an unmyelinated axon
Note the tubular tunnels that separate the axons

128. Myelin Sheaths in the CNS
Oligodendrocytes form the myelin sheaths in the brain and spinal cord
Each oligodendrocyte has multiple processes that coil around several different axons

129. Myelin Sheaths - PNS
The nucleus of the cell and most of the cytoplasm end up just external to the myelin layers

130. Myelin Processes - PNS
Myelin sheaths are associated only with axons and their collaterals as these are impulse conducting fibers and need insulation
Dendrites which carry only graded potentials are always unmyelinated

131. Myelin Sheaths - PNS
When the wrapping process is complete many concentric layers wrap the axon
Plasma membranes of myelinating cells have less protein which makes them good electrical insulators

132. Myelin Sheaths - PNS
Because the adjacent Schwann cells do not touch one another there are gaps in the myelin sheath
These gaps, called nodes of Ranvier, occur at regular intervals about 1 mm apart

133. Myelin Sheaths - PNS
Since the axon is only exposed at these nodes nerve impulses are forced to jump from one node to the next which greatly increases the rate of impulse conduction

134. Myelin Sheaths - PNS
Schwann cells that surround but do not coil around peripheral fibers are considered unmyelinated
A single Schwann cell can partly enclose 15 or more axons
Each ends occupying a separate tubular recess

135. CNS Axons Oligodendrocytes form the CNS myelin sheaths
In contast to Schwann cells, oligodendrocytes can form the sheaths of as many as 60 processes at one time
Nodes are spaced more widely than in PNS
Axons can be myelinated or unmyelinated

136. CNS Axons
Regions of the brain containing dense collections of myelinated fibers are referred to as white matter and are primarily fiber tracts
Gray matter contains mostly nerve cell bodies and unmyelinated fibers

137. Graded Potential
In humans, natural stimuli are not applied directly to axons, but to dendrites and the cell body which constitute the receptive zone of the neuron
When the membrane of this receptive zone is stimulated it does not undergo a polarity reversal
Instead it undergoes a local depolarization in which the inner surface of the membrane merely becomes less negative

138. Graded Potential
This local depolarization is called a graded potential which spreads from the receptive zone to the axon hillock (trigger zone) decreasing in strength as it travels
If this depolarizing signal is strong enough when it reaches the initial segment of the axon, it acts as the trigger that initiates an action potential in the axon
Signals from the receptive zone determine if the axon will fire an impulse

139. Synaptic Potential
Most neurons in the body do not receive stimuli directly from the environment but are stimulated only by signals received at synapses from other neurons
Synaptic input influences impulse generation through either excitatory or inhibitory synapses

140. Synaptic Potential
In excitatory synapses, neurotransmitters released by presynaptic neurons alter the permeability of the postsysnaptic membrane to certain ions, this depolarizes the postsynapatic membrane and drives the postsynaptic neuron toward impulse generation

141. Synaptic Potential
Inhibitory synapses cause the external surface of the postsynaptic membrane to become even more positive, thereby reducing the ability of the postsynaptic neuron to generate an action potential
Thousands of excitatory and inhibitory synapses act on every neuron, competing to determine whether or not that neuron will generate an impulse

142. Neural Integration
The organization of the nervous system is hierarchical
The parts of the system must be integrated into a smoothly functioning whole
Neuronal pools represent some of the basic patterns of communication with other parts of the nervous system

143. Neuronal Pools
Note: The illustrations presented are a gross oversimplification of an actual neuron pool
Most neuron pools consist of thousands of neurons and include inhibitory as well as excitatory neurons

144. Neuronal Pools
Neuronal pools are functional groups of neurons that process and integrate incoming information from other sources and transmit it forward
One incoming presynaptic fiber synapses with
Several different neurons in the pool. When
Incoming fiber is excited it will excite some
Postsynaptic neurons and facilitate others.

145. Neuronal Pools
Neurons most likely to generate impulses are those most closely associated with the incoming fiber because they receive the bulk of the synaptic contacts
These neurons are in the discharge zone
Discharge Zone

146. Neuronal Pools
Neurons farther away from the center are not excited to threshold by the incoming fiber, but are facilitated and can easily brought to threshold by stimuli from another source
The periphery of the pool is the facilitated zone
Facilitated
zone

147. Types of Circuits
Individual neurons in a neuron pool send and receive information and synaptic contacts may cause either excitation or inhibition
The patterns of synaptic connections in neuronal pools are called circuits and they determine the functional capabilities of each type of circuit
There are four basic types of circuits
Diverging, converging, reverberating, and parallel discharge circuits

148. Diverging Circuits
In diverging circuits one incoming fiber triggers responses in ever-increasing numbers of neurons farther and farther along in the circuit
Diverging circuits are often called amplifying circuits because they amplify the response

149. Diverging Circuits
These circuits are common in both sensory and motor systems
Input from a single receptor may be relayed up the spinal cord to several different brain regions
Impulses from the brain can activate a hundred neurons and thousands of muscle fibers

150. Converging Circuits
The pattern of converging circuits is opposite to that of diverging circuits
Common in both motor and sensory pathways
In these circuits, the pool receives inputs from several presynaptic neurons, and the circuit as a whole has a funneling or concentrating effect

151. Converging Circuits
Incoming stimuli may converge from many different areas or from the same source, which results in strong stimulation or inhibition

152. Reverberating (oscillating) Circuits
In reverberating circuits the incoming signal travels through a chain of neurons, each of which makes collateral synapses with neurons in the previous part of the pathway
As a result of this positive feedback, the impulses reverberates through the circuit again and again

153. Reverberating (oscillating) Circuits
Reverberating circuits give a continuous signal until one neuron in the circuit is inhibited and fails to fire
These circuits are involved in the control of rhythmic activities such as the sleep-wake cycle and breathing
The circuits may oscillate for seconds, hours, or years

154. Parallel After-Discharge Circuits
The incoming fiber stimulates several neurons arranged in parallel arrays that eventually stimulate a common output cell
Impulses reach the output cell at different times, creating a burst of impulses called an after discharge that may last 15 ms after initial input ends

155. Parallel After-Discharge Circuits
This circuit has no positive feedback and once all the neurons have fired, circuit activity ends
These circuit may be involved with complex problem solving activities

156. Patterns of Neural Processing
Processing of inputs in the various circuits is both serial and parallel
In serial processing, the input travels along a single pathway to a specific destination
In parallel processing, the input travels along several different pathways to be integrated in different CNS regions
Each pattern has its advantages
The brain derives its power from its ability to process in parallel

157. Serial Processing
In serial processing the whole system works in a predictable all-or-nothing manner
One neurons stimulates the next in sequence, producing a specific, anticipated response
Reflexes are examples of serial processing but there are others

158. Parallel Processing
In parallel processing inputs are segregated into many different pathways
Information delivered by each pathway is dealt with simultaneously by different parts of neural circuitry
During parallel processing several aspects of the stimulus are processed
Barking dog
The same stimulus can hold common or unique meaning to different individuals

159. Parallel Processing
Parallel processing is not repetitious because the circuits do different things with more information
Each parallel path is decoded in relation to all the others to produce a total picture of the stimulus

160. Parallel Processing
Even simple reflex arcs do not operate in complete isolation
As an arc moves through an association neuron this activates parallel processing of the same input at higher brain levels
The reflex arc may cause you to pull away from a negative stimulus while parallel processing of the stimulus initiates problem solving about what need to be done

161. Parallel Processing
Parallel processing is extremely important for higher level mental functioning
An integrated look at the whole problem allows for faster processing
Parallel processing allows you to store a large amount of information in a small volume
This allows logic systems to work much faster

162. Reflexes
Reflexes are rapid, automatic responses to stimuli, in which a particular stimulus always causes the same motor response
Reflex activity is stereotyped and dependable
Some your are born with and some you acquire as a consequence of interacting with your environment

163. Reflex Arcs
Reflex arcs are simple chains of neurons that explain our simplest, reflective behaviors and determine the basic structural plan of the nervous system
Reflex arcs are responsible for reflexes, which are defined as rapid, automatic motor responses to stimuli

164. Reflex Arcs
Reflexes that involve the contraction of skeletal muscle are referred to as somatic reflexes
Reflexes that involve the contraction of smooth muscle, cardiac muscle, or glands are referred to as visceral reflexes

165. Serial Processing: A Reflex Arc
Reflexes occurs over neural pathways called reflex arcs that contain five essential components
Receptor
Sensory neuron
CNS integration center
Motor neuron
Effector

166. Reflex Arcs
The receptor, sensory neuron, motor neuron, and effector are all relatively straightforward components
When considering the integration center associated with reflex arcs, it is important to understand that the number of synapses involved can vary
The simplest reflex arcs involve only one synapse in the CNS while others involve multiple synapses and interneurons

167. Reflex Arcs
At the top is a reflex arc, at the left is a monosynaptic reflex and on the right is a poly synaptic reflex

168. Reflex Arcs
The monosynaptic reflex has only one synapse and no interneuron, while the polysynaptic has multiple synapses and an interneuron

169. Reflex Arcs - Monosynaptic
This is the simple knee-jerk reflex
The impact of the hammer on the patellar tendon stretches the quadriceps muscles

170. Reflex Arcs - Monosynaptic
Stretching activates a sensory neuron that directly activates a motor neuron in the spinal cord, which then signals the quadriceps muscle to contract
This contraction counteracts the original stretching caused by the hammer

171. Reflex Arcs - Monosynaptic
Many skeletal muscles of the body can be activated by monosynaptic stretch reflexes
These reflexes help maintain equilibrium and upright posture
In these postural muscles, sensory neurons sense the stretching of muscles that occurs when the body begins to sway
Motor neurons activate muscles that adjust the body’s position to prevent a fall

172. Reflex Arcs - Monosynaptic
Because stretch reflexes contain just one synapse monosynaptic reflexes are the fastest of all reflexes
They are used in the body to maintain balance and equilibrium where speed of adjustment is essential to keep from falling

173. Reflex Arcs - Polysynaptic
Polysynaptic reflexes are the more common reflexes in the body
In these reflexes, one or more interneurons are part of a reflex pathway between the sensory and motor neurons

174. Reflex Arcs - Polysynaptic
Most of the simple reflex arcs in the body contain a single interneuron and therefore have a total of three neurons
Since there are two synapses joining the three neurons they are referred to as polysynaptic

175. Reflex Arcs - Polysynaptic
Withdrawal reflexes by which we pull away from danger are three-neuron reflexes
Pricking a finger with a tack initiates an impulse in the sensory neuron, which activates the interneuron in the CNS

176. Reflex Arcs - Polysynaptic
The interneuron signals the motor neuron to contract the muscle that withdraws the hand from the negative stimulus

177. Reflex Arcs - Polysynaptic
The three neuron reflex arc are of special importance in the science of neuroanatomy
Three neuron reflex arcs reveal the fundamental design of the entire nervous system

178. Design of the Nervous System
Three neuron reflex arcs from the basis of the structural plan of the nervous system

179. Design of the Nervous System
Note that the cell bodies of the sensory neurons lie outside the CNS in sensory ganglia and that their central processes enter the dorsal aspect of the cord

180. Design of the Nervous System
In the CNS the cell bodies of most interneurons lie dorsal to those of the motor neurons and the long axons exit the ventral aspect of the spinal cord

181. Design of the Nervous System
The nerves of the PNS consist of the motor axons plus the long peripheral process of the sensory neurons

182. Design of the Nervous System
These motor and sensory nerve fibers extend throughout the body to reach the peripheral effectors and receptors

183. Design of the Nervous System
Even though reflex arcs determine its basic organization, the human nervous system is obviously more complex than a series of simple reflex arcs
To appreciate its complexity, we must expand our conception of interneurons
Interneurons include not only the inter- mediate neurons of reflex arcs, but also all the neurons that are entirely confined within the CNS

184. Design of the Nervous System
The complexity of the CNS arises from the organization of the vast numbers of interneurons in the spinal cord and brain into complex neural circuits that process information
The complexity of the CNS results from long chains of interneurons that are interposed between each sensory and motor neuron

185. Design of the Nervous System
Although tremendously oversimplified, the infor-mation depicted is a useful way to conceptualize the organization of neurons in the CNS

186. Design of the Nervous System
The CNS has distinct regions of gray and white matter that reflect the arrangement of its neurons
The gray matter is a gray colored zone that surrounds the hollow cavity of the CNS
It is H-shaped in the spinal cord, where its dorsal half contains cell bodies of interneurons and its ventral half contains cell bodies of motor neurons

187. Design of the Nervous System
Gray matter is a site where neuron cell bodies are clustered
Specifically, gray matter is a mixture of neuron cell bodies, dendrites, and short unmyelinated axons

188. Design of the Nervous System
White matter which contains no neuron cell bodies but millions of axons
Its white color comes from the myelin sheaths around many of the axons
Most of these axons ascend from the spinal cord to the brain or descend from the brain to the spinal cord, allowing these two regions of the CNS to communicate with each other

189. Design of the Nervous System
White matter consists of axons running between different parts of the CNS
Within the white matter, axons traveling to similar destinations form axon bundles called tracts

190. Nervous Tissue Development
During the embryonic period, which spans 8 weeks, the embryo goes from zygote to blastocyst, to two layer embryo, to three layer embryo
The embryo upon reaching three layers begins to form the neural tube from which will differentiate the brain and spinal cord

196. Nervous Tissue Development
The nervous system develops from the dorsal section of the ectoderm, which invaginates to form the neural tube and the neural crest

197. Nervous System Development
The walls of the neural tube begin as a layer of neuroepithelial cells become the CNS
These cells divide, migrate externally, and become neuroblasts (future neurons) which never again divide

198. Nervous System Development
These cells divide, migrate externally, and become neuroblasts (future neurons) which never again divide
They cluster as future interneurons and motor neurons

199. Nervous System Development
Just external to the neuroepithelium, the neuroblasts cluster into alar and basal plates

200. Nervous System Development
Dorsally, the neurons of the alar plate become interneurons
Ventrally, the neuroblasts of the basal plate become motor neurons and sprout axons that grow out to the effector organs

201. Nervous System Development
Axons that sprout from the young interneurons form the white matter by growing outward the length of the CNS
These events occur in both the spinal cord and the brain

202. Nervous System Development
Most of the events described take place in the second month of development, but neurons continue to form rapidly until the about the sixth month
At the sixth month neuron formation slows markedly, although it may continue at a reduced rate into childhood

203. Nervous System Development
Just before neuron formation slows, the neuroepithelium begins to produce astrocytes and oligiodendrocytes
The earliest of these glial cells extend outward from the neuroepithelium and provide pathways along which young neurons migrate to reach their final destination
As the division of its cells slows, the neuroepithelium becomes the ependymal layer

204. Nervous System Development
Sensory neurons do not arise from the neural tube but from the neural crest
This explains why the cell bodies of the sensory neurons lie outside the CNS
Sensory neurons also stop dividing during the fetal period

205. Nervous System Development
Sensory neurons cell bodies develop outside the CNS in the neural crest
Sensory neurons also stop dividing during the fetal period

206. Nervous System Development
Neuroscientists are actively investigating how forming neurons “hook up” with each other during development
As the growing axons elongate at growth cones, they are attached by chemical signals from other neurons called neurotrophins
At the same time, the receiving dendites send out thin, extensions to reach the approaching axons to form synapses

207. Nervous System Development
Which synaptic connections are made, and which persist, are determined by two factors;
The amount of neurotrophin initially received
The degree to which a synapse is used after being established

208. Nervous System Development
Neurons that make “bad” connections are signaled to die via apoptosis
Of the neurons formed during the embryonic period, about two-thirds die before birth
This initial overproduction of neurons ensures that all necessary neural connections will be made and that mistaken connections will be eliminated