1. Nervous System
What allows you to perceive the world around you, to recognize the incoming stimuli and to react to the environment
Sensory systems
Motor systems
Memory/learning

2. Nervous System Central Nervous System (CNS)
Brain and Spinal Cord
Peripheral Nervous System (PNS)
All nervous tissue outside the CNS
Somatic Nervous System (SNS)---voluntary
Sensory and motor neurons to skeletal muscle
Autonomic Nervous System (ANS)---Involuntary
Sensory and motor neurons to viscera
Sympathetic Division (increase heart rate)
Parasympathetic Division (decrease heart rate)

3. Neurons (=nerve cells) general characteristics:
Nervous System
Neurons (=nerve cells)
general characteristics:
- can be very long---6 feet or more
- conduct nervous impulses---communication
- long lived---entire life span
- high metabolic rate; high O2 and glucose needs---brain accounts for less than 10% of body mass, yet gets over 25% of body’s energy

4. Types of Neurons (functional classification)
Motor Neurons---
carry info from brain to body
Sensory Neurons---
carry info from body to brain
Interneurons---
carry info within the Central Nervous System (CNS). These account for 90% of the neurons in the body
Neuroglia---support cells
Oligodendrocytes---CNS
Schwann cells---PNS

5. Types of Neurons (structural classification)
Multipolar---many processes located in CNS
Bipolar---2 processes located in sensory organs (eye, ear & nose)
Unipolar--1 process these are sensory neurons. The axon and dendrite fuse into one process.
Interneurons---Named based on looks or after the person who first described them (fig. 12.5)
Purkinje cells, Pyramidal cells

7. Anatomy of a `typical’ motor neuron
nucleus

8. Anatomy of a `typical’ motor neuron
nucleus
cell body = soma = perikaryon

9. Anatomy of a `typical’ motor neuron
nucleus
Nissl bodies = rough endoplamic reticulum
cell body = soma = perikaryon

10. Anatomy of a `typical’ motor neuron
nucleus
Nissl bodies
cell body = soma = perikaryon
Golgi apparatus

11. Anatomy of a `typical’ motor neuron
other organelles:
mitochondria
lysosomes
neurofilaments
nucleus
Nissl bodies
cell body = soma = perikaryon
Golgi apparatus

12. Anatomy of a `typical’ motor neuron
neural processes:
axon = nerve fiber
dendrites

13. Anatomy of a `typical’ motor neuron
Flow of Information:
axon
dendrites

14. Anatomy of a `typical’ motor neuron
axon hillock
(trigger zone)
axon
dendrites

15. Anatomy of a `typical’ motor neuron
terminal branches= telodendria
axon hillock
axon
dendrites

16. Anatomy of a `typical’ motor neuron
terminal branches
axon hillock
axon
axonal terminals =
synaptic knobs =
synaptic boutons
dendrites

17. Anatomy of a `typical’ motor neuron
terminal branches
axon hillock
axon
axonal terminals =
synaptic knobs =
synaptic boutons
dendrites

18. Anatomy of a `typical’ motor neuron
axonal terminals =
synaptic knobs =
synaptic boutons

19. Anatomy of a `typical’ motor neuron
synaptic vesicles
with neurotransmitters

20. Anatomy of a `typical’ motor neuron

21. Anatomy of a `typical’ motor neuron

22. Anatomy of a `typical’ motor neuron

23. Anatomy of a `typical’ motor neuron

24. Anatomy of a `typical’ motor neuron

25. Anatomy of a `typical’ motor neuron

26. Anatomy of a `typical’ motor neuron

27. Anatomy of a `typical’ motor neuron

28. Anatomy of a `typical’ motor neuron

29. Anatomy of a `typical’ motor neuron

30. Anatomy of a `typical’ motor neuron

31. Anatomy of a `typical’ motor neuron

32. Myelin Sheath Some Axons are myelinated
Myelin Sheath (schwann cell in PNS and oligodendrocyte in CNS) axon
Multiple layers wrapped around = myelin
Cell body and cytoplasm (outer most layer) = Neurolemma

33. Anatomy of a `typical’ motor neuron
myelination:

34. Anatomy of a `typical’ motor neuron
myelination:
Special Glial cells -- make up the myelin sheath

35. Anatomy of a ‘typical’ motor neuron
Myelin

36. Anatomy of a `typical’ motor neuron
nodes of Ranvier

37. Resting Membrane Potential
Voltage across the membrane
Electric potential energy
Due to separation of ions
All cells have a resting membrane potential

38. Resting Membrane Potential+ - - + + + + - + - - + + - - -

39. Resting Membrane Potential+ - + - + - - - - + + +

40. Resting Membrane Potential
Amplifier
Electrode
Oscilloscope
0 mV

41. Resting Membrane Potential
Amplifier
Electrode
Oscilloscope
-70 mV

42. Resting Membrane Key Players
Sodium-Potassium (Na+/K+) Pump
Moves Sodium and Potassium against their concentration gradients
Moves 3 Na+ out of the cell and 2 K+ into the cell

43. Resting Membrane Potential Key Players:
Na+/ K+ Pump:
3 Na+ out
Cell exterior
cell membrane
ATP
NA/K pump establishes and maintains resting membrane potential
Cell interior
2 K+ in

44. Na+ K+ Resting Membrane Potential Key Players: Leaky Channels K+ Na+
Cell exterior
cell membrane
Cell interior K+
Na+
Many K+ “leak” channels
Few Na+ “leak” channels

45. Together creates -70 mV Resting Membrane PotentialK+
2 K+ K+
ATP K+
2 K+
Pumps
3 Na+ K+
Leak Channels
2 K+ K+ _ + K+
3 Na+
Na+
Together creates -70 mV Resting Membrane Potential
3 Na+
2 K+
Na+
Leak Channels
Na+

46. Resting Membrane Potential
Voltage across the membrane
Electric potential energy
Due to separation of ions
All cells have a resting membrane potential

47. Electrical Signaling Through Changes in Membrane Potential
Describing Changes in Membrane Potential
Graded Potentials
Action Potentials
Propagation of Action Potentials

48. Two Types of Change: Depolarizing Hyperpolarizing
-70 mV
0 mV
-90 mV
Depolarizing
reduce membrane potential
make inside less negative
Na+ move into cell
-70 mV
0 mV
-90 mV
Hyperpolarizing
increase membrane potential
make inside more negative
K+ move out of cell

49. Signals produced by a change in membrane potential
Graded potentials
Short lived
Local Signaling
Either depolarizing or hyperpolarizing

50. Graded Potentials are the first step in neuronal communication
are essential in initiating action potentials
typical of dendrites and cell body (NOT axons)

51. Graded Potentials
“graded” because - magnitude of the potential change varies directly with the strength of the stimulus
Can be hyperpolarizing or depolarizing
-70
+70
weak
hyperpolarized
strong
depolarized

52. Graded Potentials
Cause current flow that decreases in magnitude with distance (Signal dies out with distance) due to leaky membrane
Distance (mm)
Membrane Potential (mV)
Site of stimulus
-70

53. Graded Potentials
Cause current flow that decreases in magnitude with distance (Signal dies out with distance) due to leaky membrane

54. How are graded potentials produced?
Changing the membrane’s permeability to different ions by opening/closing ion channels

55. Na+ How are graded potentials produced?
Changing the membrane’s permeability to different ions by opening/closing ion channels
Triggering a depolarizing graded potential
Na+
cell membrane
+ + +
- - -
Resting
Depolarized
- - -
-70 mV
e.g., +30 mV
Na+
Open chemically-gated or voltage gated channels for cation (Na+) flow INTO cell  depolarization

56. Cl– How are graded potentials produced?  hyperpolarization
Changing the membrane’s permeability to different ions by opening/closing ion channels
Triggering a hyperpolarizing graded potential
Open channels for cation (K+) flow OUT of cell
Open channels for anion (Cl-) flow INTO cell K+
Cl–
e.g., -90 mV
-70 mV
+ + +
- - -
Resting
Hyperpolarized
 hyperpolarization

57. Signals produced by a change in membrane potential
Graded potentials
Action potentials
All or None
Self Propagating
Long distance communication

58. Action Potential Key Players:
Voltage gated ion channels
Channel is blocked by one or more ‘gates’
Membrane Potential hits a threshold voltage and ‘gate’ opens

59. Concept of Threshold
Graded potentials that are not large enough to depolarize a large area of the axon hillock, fade away and never reach threshold
A stimulus that is large enough to depolarize a large enough section of the axon hillock hit threshold
( -55mV), causes an ACTION POTENTIAL
Threshold
Stimulus
Stimulus Strength
Sub-threshold
Stimuli
Supra-Threshold
-70
Membrane Potential (mV)
-55 30
threshold

60. Why? Many Voltage gated Na+ channels located at trigger zone
If graded potential is strong enough to hit threshold when it reaches the axon hillock, it will trigger an Action Potential
Why?
Many Voltage gated Na+ channels located at trigger zone
On soma & dendrite : / um2 membrane
At trigger zone : / um2 membrane

61. Action Potential Key Players:
Voltage gated ion channels
Voltage gated Na+
activation gate closed at resting
inactivation gate open at resting
Voltage gated K+
Single gate closed at resting

62. Action Potentials + + + + + + + + + + + + + + + + + + + + + + + + + +
Remember that due to Resting Membrane Potential:
there is a large diffusional gradient inward for Na+
as well as a large electrical gradient inward for Na+
There is a large diffusional gradient outward for K+

63. Action Potentials + + + + + + + + + + + + + + + + + + + + + + + + + +
Depolarization that reaches threshold opens the Na+ activation gates and Na+ RUSHES into the cell

64. Action Potentials and the membrane potential Depolarizes ... Amplifier
Electrode
-70 mV
Oscilloscope
and the membrane
potential Depolarizes ...

65. Action Potentials + + + + + + + + + + + + + + + + + + + + + + + + + +
As membrane potential peaks at about 30 mV,
the Na+ inactivation gates close and Na+ can no longer enter the cell
K+ channels open and K+ RUSHES out of the cell

66. Action Potentials Return to resting membrane potential Amplifier
Electrode
+30 mV
-70 mV
Oscilloscope
Return to
resting
membrane
potential

67. + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
Action Potentials + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + + +
As membrane potential approaches resting potential
the Na+ activation gate closes and the inactivation gate opens
K+ gate closes

68. Stages of the action potential
1) Depolarization
+30
2) Repolarization
Membrane Potential (mV)
3) Hyperpolarization
-70 1 2 3
Time (msec)
Notice the Time scale……

69. Stages of the action potential
1) Depolarization
Initially, depolarization is a local current until it reaches threshold (-55 to -50 mV)
Na+ activation & inactivation gates are opened; K+ gates are closed
Na+ rushes into cell
Membrane Potential (mV)
-70 1 2 3
Time (msec)

70. Stages of the action potential
2) Repolarization
Sodium inactivation gates close
Membrane permeability to Na+ declines to resting levels
Voltage-gated K+ channels open
K+ exits the cell and internal negativity of the resting neuron is restored
Membrane Potential (mV)
-70 1 2 3
Time (msec)

71. Stages of the action potential
3) Hyperpolarization
Potassium gates are slow to close, causing an excessive outflow of K+
This outflow causes hyperpolarization of the membrane (undershoot)
Na+ Activation gates close
Na+ inactivation gates open
Membrane Potential (mV)
-70 1 2 3
Time (msec)

72. Refractory Periods Absolute RP Relative RP Na+ channels open
Na+ channels inactivated
No new action potential possible
Relative RP
Some Na+ channels still inactivated
New action potential possible, but it requires a stronger than normal stimulus
Membrane Potential (mV)
-70
Time (msec)

73. Action Potentials are ALL-or None
Once we hit threshold the voltage gated channels are ‘popped’ and the Na+ rushes in
We have an Action Potential
Threshold
Stimulus
Stimulus Strength
Sub-threshold
Stimuli
Supra-Threshold
-70
Membrane Potential (mV)
-55 30
threshold
(Its like firing a gun)

74. Action Potentials are Self-Propagating+ + + + + + + + + + + + + + + + + + + + + +

75. Action Potentials are Self-Propagating+ + + + + + + + + + + + + + + + + + + + + + +

76. Action Potentials are Self-Propagating+ + + + + + + + + + + + + + + + + + + + + + +

77. Action Potentials are Self-Propagating+ + + + + + + + + + + + + + + + + + + + + +

78. Action Potentials are Self-Propagating+ + + + + + + + + + + + + + + + + + + + + +

79. Action Potentials are Self-Propagating
Continuous Conduction:
the action potential moves down the entire length of the axon
Trigger Zone
Graded Potentials
Action Potentials

80. Action Potentials are Self-Propagating
What about myelinated axons?

81. Action Potentials are Self-Propagating
Myelinated Axons
Myelin Sheath
(each made by a Schwann cell)
Nodes of Ranvier

82. Action Potentials are Self-Propagating
Myelinated Axons

83. Action Potentials are Self-Propagating
Myelinated Axons

84. Action Potentials are Self-Propagating
Myelinated Axons
Action Potentials are Self-Propagating
Myelinated Axons

85. Action Potentials are Self-Propagating
Myelinated Axons
Action Potentials are Self-Propagating
Myelinated Axons

86. Action Potentials are Self-Propagating
Myelinated Axons

87. Action Potentials are Self-Propagating
Myelinated Axons
Saltatory conduction: action potential jumps from one node of Ranvier to another -- speeds up conduction in Vertebrates
WOW! APs in unmyelinated = 1m/sec in myelinated = 150m/sec

88. An Action Potential is an Action Potential……
If there are no BIG Action Potentials for BIG stimuli……
how do we tell the difference?

89. Frequency Coding for Stimulus Intensity

90. Graded Potentials vs Action Potentials
“the magnitude of the potential varies directly with the intensity of the stimulus”
magnitude decreases with distance from the source
Action Potentials
All-or None
do not decrease in magnitude with distance

91. Graded Potentials vs Action Potentials
Are generated in Dendrites and cell body in response to stimuli
Travel toward the axon hillock
Action Potentials
Are generated at Axon hillock when depolarization reaches threshold
Are Propagated down the axon
Continuous conduction
Saltatory conduction
Refractory Period
Absolute
Relative

92. Chemical Synaptic Transmission

93. Chemical Synaptic Transmission

94. Chemical Synaptic Transmission

95. Chemical Synaptic Transmission
[239]

96. Chemical Synaptic Transmission
[239]

97. Chemical Synaptic Transmission
Synaptic Cleft
[239]

98. Chemical Synaptic Transmission
Synaptic Cleft
[239]

99. Synaptic Cleft [239] Ca++ Chemical Synaptic Transmission
calcium channels open
Ca++
Synaptic Cleft
[239]

100. Synaptic Cleft [239] Ca++ Chemical Synaptic Transmission
calcium channels open
calcium moves into presynaptic cell
Ca++
Synaptic Cleft
[239]

101. Synaptic Cleft [239] Ca++ Chemical Synaptic Transmission
calcium channels open
calcium moves into presynaptic cell
Ca++
Synaptic Cleft
[239]

102. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
Ca++
[239]

103. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
Ca++
[239]

104. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
Ca++
[239]

105. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
Ca++
[239]

106. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
Ca++
[239]

107. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
neurotransmitter diffuses across cleft
Ca++
[239]

108. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
neurotransmitter diffuses across cleft
Ca++
[239]

109. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
neurotransmitter diffuses across cleft
Ca++
[239]

110. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
neurotransmitter diffuses across cleft
Ca++
[239]

111. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
neurotransmitter diffuses across cleft
Ca++
[239]

112. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
neurotransmitter diffuses across cleft
Ca++
neurotransmitter - receptor interaction
[239]

113. [240] Ca++ Excitatory Postsynaptic Potential =EPSP EPSP Na+ Na+
neurotransmitter - receptor interaction
opening of post-synaptic ion channels
[240]

114. K+ K+ [240] Ca++ Inhibitory Postsynaptic Potential =IPSP IPSP
neurotransmitter - receptor interaction
opening of post-synaptic ion channels
[240]

115. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
neurotransmitter diffuses across cleft
Ca++
neurotransmitter - receptor interaction
opening of post-synaptic ion channels
[239]
degradation of neurotransmitter

116. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
neurotransmitter diffuses across cleft
Ca++
neurotransmitter - receptor interaction
opening of post-synaptic ion channels
[239]
degradation of neurotransmitter

117. [239] Ca++ Chemical Synaptic Transmission calcium channels open
calcium moves into presynaptic cell
synaptic vesicles fuse with membrane
exocytosis of neurotransmitter
neurotransmitter diffuses across cleft
Ca++
neurotransmitter - receptor interaction
opening of post-synaptic ion channels
[239]
degradation of neurotransmitter

119. Temporal Summation
threshold
[241]

120. Temporal Summation
threshold
[241]

121. Temporal Summation
threshold
[241]

122. Temporal Summation
threshold
[241]

123. Temporal Summation
threshold
[241]

124. Temporal Summation
threshold
[241]

125. Temporal Summation
threshold
[241]

126. Temporal Summation
threshold
[241]

127. Temporal Summation
threshold
[241]

128. Temporal Summation
threshold
[241]

129. Temporal Summation
threshold
[241]

130. Temporal Summation
threshold
[241]

131. Temporal Summation
threshold
[241]

132. Temporal Summation
threshold
[241]

133. Temporal Summation
threshold
[241]

134. Temporal Summation
threshold
[241]

135. Spatial Summation
threshold
[242]

136. Spatial Summation
threshold
[242]

137. Spatial Summation
threshold
[242]

138. Spatial Summation
threshold
[242]

139. Spatial Summation
threshold
[242]

140. Spatial Summation
threshold
[242]

141. Spatial Summation
threshold
[242]

142. Spatial Summation
threshold
[243]

143. Spatial Summation
(+)
threshold
(+)
(-)
[243]