1. Fundamentals of the Nervous System and Nervous Tissue: Part E11
Fundamentals of the Nervous System and Nervous Tissue: Part E

2. The Synapse
Nervous system works because information flows from neuron to neuron
Neurons functionally connected by synapses
Junctions that mediate information transfer
From one neuron to another neuron
Or from one neuron to an effector cell

3. Synapse Classification
Axodendritic—between axon terminals of one neuron and dendrites of others
Axosomatic—between axon terminals of one neuron and soma of others
Less common types:
Axoaxonal (axon to axon)
Dendrodendritic (dendrite to dendrite)
Somatodendritic (dendrite to soma)

4. Important Terminology
Presynaptic neuron
Neuron conducting impulses toward synapse
Sends the information
Postsynaptic neuron (in Pns may be a neuron, muscle cell, or gland cell)
Neuron transmitting electrical signal away from synapse
Receives the information
Most function as both

5. Important Terminology
Animation: Synapses
Right-click slide / select “play”

6. Figure 11.16 Synapses. Axodendritic synapses Dendrites Axosomatic
Cell body
Axoaxonal
synapses
Axon
Axon
Axosomatic
synapses
Cell body (soma)
of postsynaptic
neuron

7. Varieties of Synapses: Electrical Synapses
Less common than chemical synapses
Neurons electrically coupled (joined by gap junctions that connect cytoplasm of adjacent neurons)
Communication very rapid
May be unidirectional or bidirectional
Synchronize activity
More abundant in:
Embryonic nervous tissue
Nerve impulse remains electrical

8. Varieties of Synapses: Chemical Synapses
Specialized for release and reception of chemical neurotransmitters
Typically composed of two parts
Axon terminal of presynaptic neuron
Contains synaptic vesicles filled with neurotransmitter
Neurotransmitter receptor region on postsynaptic neuron's membrane
Usually on dendrite or cell body
Two parts separated by synaptic cleft
Fluid-filled space
Electrical impulse changed to chemical across synapse, then back into electrical

9. Synaptic Cleft 30–50 nm wide (~1/1,000,000th of an inch)
Prevents nerve impulses from directly passing from one neuron to next

10. Synaptic Cleft Transmission across synaptic cleft
Chemical event (as opposed to an electrical one)
Depends on release, diffusion, and receptor binding of neurotransmitters
Ensures unidirectional communication between neurons

11. Synaptic Cleft Animation: Neurotransmitters
Right-click slide / select “play”

12. Information Transfer Across Chemical Synapses
AP arrives at axon terminal of presynaptic neuron
Causes voltage-gated Ca2+ channels to open
Ca2+ floods into cell
Synaptotagmin protein binds Ca2+ and promotes fusion of synaptic vesicles with axon membrane
Exocytosis of neurotransmitter into synaptic cleft occurs
Higher impulse frequency  more released

13. Information Transfer Across Chemical Synapses
Neurotransmitter diffuses across synapse
Binds to receptors on postsynaptic neuron
Often chemically gated ion channels
Ion channels are opened
Causes an excitatory or inhibitory event (graded potential)
Neurotransmitter effects terminated

14. Termination of Neurotransmitter Effects
Within a few milliseconds neurotransmitter effect terminated in one of three ways
Reuptake
By astrocytes or axon terminal
Degradation
By enzymes
Diffusion
Away from synaptic cleft

15. Figure 11.17 Chemical synapses transmit signals from one neuron to another using neurotransmitters.
Slide 1
Presynaptic
neuron
Presynaptic
neuron
Postsynaptic
neuron
Action potential
arrives at axon
terminal. 1
Voltage-gated Ca2+
channels open and Ca2+
enters the axon terminal. 2
Mitochondrion
Ca2+ entry
causes synaptic
vesicles to release
neurotransmitter
by exocytosis 3
Synaptic
cleft
Axon
terminal
Synaptic
vesicles
Neurotransmitter diffuses
across the synaptic cleft and
binds to specific receptors on
the postsynaptic membrane. 4
Postsynaptic
neuron
Ion movement
Enzymatic
degradation
Graded potential
Reuptake
Diffusion away
from synapse
Binding of neurotransmitter opens
ion channels, resulting in graded
potentials. 5
Neurotransmitter effects are
terminated by reuptake through
transport proteins, enzymatic
degradation, or diffusion away
from the synapse. 6

16. Figure 11.17 Chemical synapses transmit signals from one neuron to another using neurotransmitters.
Slide 2
Presynaptic
neuron
Presynaptic
neuron
Postsynaptic
neuron
Action potential
arrives at axon
terminal. 1
Mitochondrion
Synaptic
cleft
Axon
terminal
Synaptic
vesicles
Postsynaptic
neuron

17. Figure 11.17 Chemical synapses transmit signals from one neuron to another using neurotransmitters.
Slide 3
Presynaptic
neuron
Presynaptic
neuron
Postsynaptic
neuron
Action potential
arrives at axon
terminal. 1
Voltage-gated Ca2+
channels open and Ca2+
enters the axon terminal. 2
Mitochondrion
Synaptic
cleft
Axon
terminal
Synaptic
vesicles
Postsynaptic
neuron

18. Figure 11.17 Chemical synapses transmit signals from one neuron to another using neurotransmitters.
Slide 4
Presynaptic
neuron
Presynaptic
neuron
Postsynaptic
neuron
Action potential
arrives at axon
terminal. 1
Voltage-gated Ca2+
channels open and Ca2+
enters the axon terminal. 2
Mitochondrion
Ca2+ entry
causes synaptic
vesicles to release
neurotransmitter
by exocytosis 3
Synaptic
cleft
Axon
terminal
Synaptic
vesicles
Postsynaptic
neuron

19. Figure 11.17 Chemical synapses transmit signals from one neuron to another using neurotransmitters.
Slide 5
Presynaptic
neuron
Presynaptic
neuron
Postsynaptic
neuron
Action potential
arrives at axon
terminal. 1
Voltage-gated Ca2+
channels open and Ca2+
enters the axon terminal. 2
Mitochondrion
Ca2+ entry
causes synaptic
vesicles to release
neurotransmitter
by exocytosis 3
Synaptic
cleft
Axon
terminal
Synaptic
vesicles
Neurotransmitter diffuses
across the synaptic cleft and
binds to specific receptors on
the postsynaptic membrane. 4
Postsynaptic
neuron

20. ion channels, resulting in graded potentials.
Figure Chemical synapses transmit signals from one neuron to another using neurotransmitters.
Slide 6
Ion movement
Graded potential 5
Binding of neurotransmitter opens
ion channels, resulting in graded
potentials.

21. terminated by reuptake through transport proteins, enzymatic
Figure Chemical synapses transmit signals from one neuron to another using neurotransmitters.
Slide 7
Enzymatic
degradation
Reuptake
Diffusion away
from synapse 6
Neurotransmitter effects are
terminated by reuptake through
transport proteins, enzymatic
degradation, or diffusion away
from the synapse.

22. Figure 11.17 Chemical synapses transmit signals from one neuron to another using neurotransmitters.
Slide 8
Presynaptic
neuron
Presynaptic
neuron
Postsynaptic
neuron
Action potential
arrives at axon
terminal. 1
Voltage-gated Ca2+
channels open and Ca2+
enters the axon terminal. 2
Mitochondrion
Ca2+ entry
causes synaptic
vesicles to release
neurotransmitter
by exocytosis 3
Synaptic
cleft
Axon
terminal
Synaptic
vesicles
Neurotransmitter diffuses
across the synaptic cleft and
binds to specific receptors on
the postsynaptic membrane. 4
Postsynaptic
neuron
Ion movement
Enzymatic
degradation
Graded potential
Reuptake
Diffusion away
from synapse
Binding of neurotransmitter opens
ion channels, resulting in graded
potentials. 5
Neurotransmitter effects are
terminated by reuptake through
transport proteins, enzymatic
degradation, or diffusion away
from the synapse. 6

23. Synaptic Delay
Time needed for neurotransmitter to be released, diffuse across synapse, and bind to receptors
0.3–5.0 ms
Synaptic delay is rate-limiting step of neural transmission

24. Postsynaptic Potentials
Neurotransmitter receptors cause graded potentials that vary in strength with
Amount of neurotransmitter released and
Time neurotransmitter stays in area

25. Table 11.2 Comparison of Graded Potentials and Action Potentials (1 of 4)

26. Table 11.2 Comparison of Graded Potentials and Action Potentials (2 of 4)

27. Table 11.2 Comparison of Graded Potentials and Action Potentials (3 of 4)

28. Table 11.2 Comparison of Graded Potentials and Action Potentials (4 of 4)

29. Postsynaptic Potentials
Types of postsynaptic potentials
EPSP—excitatory postsynaptic potentials
IPSP—inhibitory postsynaptic potentials

30. Excitatory Synapses and EPSPs
Neurotransmitter binding opens chemically gated channels
Allows simultaneous flow of Na+ and K+ in opposite directions
Na+ influx greater than K+ efflux  net depolarization called EPSP (not AP)
EPSP help trigger AP if EPSP is of threshold strength
Can spread to axon hillock, trigger opening of voltage-gated channels, and cause AP to be generated

31. Figure 11.18a Postsynaptic potentials can be excitatory or inhibitory.
+30
An EPSP is a local
depolarization of the
postsynaptic membrane
that brings the neuron
closer to AP threshold.
Neurotransmitter binding
opens chemically gated
ion channels, allowing
Na+ and K+ to pass
through simultaneously.
Membrane potential (mV)
Threshold
–55
–70
Stimulus 10 20 30
Time (ms)
Excitatory postsynaptic potential (EPSP)

32. Inhibitory Synapses and IPSPs
Reduces postsynaptic neuron's ability to produce an action potential
Makes membrane more permeable to K+ or Cl–
If K+ channels open, it moves out of cell
If Cl– channels open, it moves into cell
Therefore neurotransmitter hyperpolarizes cell
Inner surface of membrane becomes more negative
AP less likely to be generated

33. Figure 11.18b Postsynaptic potentials can be excitatory or inhibitory.
+30
An IPSP is a local
hyperpolarization of the
postsynaptic membrane
that drives the neuron
away from AP threshold.
Neurotransmitter binding
opens K+ or Cl– channels.
Membrane potential (mV)
Threshold
–55
–70
Stimulus 10 20 30
Time (ms)
Inhibitory postsynaptic potential (IPSP)

34. Synaptic Integration: Summation
A single EPSP cannot induce an AP
EPSPs can summate to influence postsynaptic neuron
IPSPs can also summate
Most neurons receive both excitatory and inhibitory inputs from thousands of other neurons
Only if EPSP's predominate and bring to threshold  AP

35. Two Types of Summation Temporal summation Spatial summation
One or more presynaptic neurons transmit impulses in rapid-fire order
Spatial summation
Postsynaptic neuron stimulated simultaneously by large number of terminals at same time

36. Figure 11.19a Neural integration of EPSPs and IPSPs.
Threshold of axon of
postsynaptic neuron
Membrane potential (mV)
Resting potential
–55
–70 E1 E1
Time
No summation:
2 stimuli separated in time
cause EPSPs that do not
add together.
Excitatory synapse 1 (E1)
Excitatory synapse 2 (E2)
Inhibitory synapse (I1)

37. Figure 11.19b Neural integration of EPSPs and IPSPs.
Threshold of
axon of
postsynaptic
neuron
Resting
potential
Membrane potential (mV)
–55
–70 E1 E1
Time
Temporal summation:
2 excitatory stimuli close
in time cause EPSPs
that add together.
Excitatory synapse 1 (E1)
Excitatory synapse 2 (E2)
Inhibitory synapse (I1)

38. Figure 11.19c Neural integration of EPSPs and IPSPs.
Threshold
of axon of
postsynaptic
neuron
Resting
potential
Membrane potential (mV)
–55
–70
E1 + E2
Time
Spatial summation:
2 simultaneous stimuli at
different locations cause
EPSPs that add together.
Excitatory synapse 1 (E1)
Excitatory synapse 2 (E2)
Inhibitory synapse (I1)

39. Figure 11.19d Neural integration of EPSPs and IPSPs.
Threshold of axon of
postsynaptic neuron
Membrane potential (mV)
Resting potential
–55
–70 l1
E1 + l1
Time
Spatial summation of
EPSPs and IPSPs:
Changes in membane potential
can cancel each other out.
Excitatory synapse 1 (E1)
Excitatory synapse 2 (E2)
Inhibitory synapse (I1)

40. Integration: Synaptic Potentiation
Repeated use of synapse increases ability of presynaptic cell to excite postsynaptic neuron
Ca2+ concentration increases in presynaptic terminal and postsynaptic neuron
Brief high-frequency stimulation partially depolarizes postsynaptic neuron
Chemically gated channels (NMDA receptors) allow Ca2+ entry
Ca2+ activates kinase enzymes that promote more effective responses to subsequent stimuli

41. Integration: Presynaptic Inhibition
Excitatory neurotransmitter release by one neuron inhibited by another neuron via an axoaxonal synapse
Less neurotransmitter released
Smaller EPSPs formed

42. Neurotransmitters Language of nervous system
50 or more neurotransmitters have been identified
Most neurons make two or more neurotransmitters
Neurons can exert several influences
Usually released at different stimulation frequencies
Classified by chemical structure and by function

43. Classification of Neurotransmitters: Chemical Structure
Acetylcholine (ACh)
First identified; best understood
Released at neuromuscular junctions ,by some ANS neurons, by some CNS neurons
Synthesized from acetic acid and choline by enzyme choline acetyltransferase
Degraded by enzyme acetylcholinesterase (AChE)

44. Classification of Neurotransmitters: Chemical Structure
Biogenic amines
Catecholamines
Dopamine, norepinephrine (NE), and epinephrine
Synthesized from amino acid tyrosine
Indolamines
Serotonin and histamine
Serotonin synthesized from amino acid tryptophan; histamine synthesized from amino acid histidine
Broadly distributed in brain
Play roles in emotional behaviors and biological clock
Some ANS motor neurons (especially NE)
Imbalances associated with mental illness

45. Classification of Neurotransmitters: Chemical Structure
Amino acids
Glutamate
Aspartate
Glycine
GABA—gamma ()-aminobutyric acid

46. Classification of Neurotransmitters: Chemical Structure
Peptides (neuropeptides)
Substance P
Mediator of pain signals
Endorphins
Beta endorphin, dynorphin and enkephalins
Act as natural opiates; reduce pain perception
Gut-brain peptides
Somatostatin and cholecystokinin

47. Classification of Neurotransmitters: Chemical Structure
Purines
ATP!
Adenosine
Potent inhibitor in brain
Caffeine blocks adenosine receptors
Act in both CNS and PNS
Produce fast or slow responses
Induce Ca2+ influx in astrocytes

48. Classification of Neurotransmitters: Chemical Structure
Gases and lipids - gasotransmitters
Nitric oxide (NO), carbon monoxide (CO), hydrogen sulfide gases (H2S)
Bind with G protein–coupled receptors in the brain
Lipid soluble
Synthesized on demand
NO involved in learning and formation of new memories; brain damage in stroke patients, smooth muscle relaxation in intestine
H2S acts directly on ion channels to alter function

49. Classification of Neurotransmitters: Chemical Structure
Endocannabinoids
Act at same receptors as THC (active ingredient in marijuana)
Most common G protein-linked receptors in brain
Lipid soluble
Synthesized on demand
Believed involved in learning and memory
May be involved in neuronal development, controlling appetite, and suppressing nausea

50. Classification of Neurotransmitters: Function
Great diversity of functions
Can classify by
Effects – excitatory versus inhibitory
Actions – direct versus indirect

51. Classification of Neurotransmitters: Function
Effects - excitatory versus inhibitory
Neurotransmitter effects can be excitatory (depolarizing) and/or inhibitory (hyperpolarizing)
Effect determined by receptor to which it binds
GABA and glycine usually inhibitory
Glutamate usually excitatory
Acetylcholine and NE bind to at least two receptor types with opposite effects
ACh excitatory at neuromuscular junctions in skeletal muscle
ACh inhibitory in cardiac muscle

52. Classification of Neurotransmitters: Direct versus Indirect Actions
Neurotransmitter binds to and opens ion channels
Promotes rapid responses by altering membrane potential
Examples: ACh and amino acids

53. Ion flow blocked Ions flow Ligand Closed ion channel Open ion channel
Figure Direct neurotransmitter receptor mechanism: Channel-linked receptors.
Ion flow blocked
Ions flow
Ligand
Closed ion
channel
Open ion
channel

54. Classification of Neurotransmitters: Direct versus Indirect Actions
Neurotransmitter acts through intracellular second messengers, usually G protein pathways
Broader, longer-lasting effects similar to hormones
Biogenic amines, neuropeptides, and dissolved gases

55. Figure 11.21 Indirect neurotransmitter receptor mechanism: G protein-inked receptors.
Recall from Chapter 3 that G protein
signaling mechanisms are like a
molecular relay race.
Ligand (1st
messenger)
Receptor
G protein
Enzyme
2nd
messenger
Neurotransmitter
(1st messenger) binds
and activates receptor. 1
Adenylate cyclase
Closed ion channel
Open ion channel
Receptor
G protein
cAMP changes membrane
permeability by opening or
closing ion channels. 5a
cAMP activates
specific genes. 5c
GDP
cAMP activates
enzymes. 5b
Receptor
activates G
protein. 2
G protein
activates
adenylate
cyclase. 3
Adenylate
cyclase converts
ATP to cAMP
(2nd messenger). 4
Nucleus
Active enzyme

56. Neurotransmitter Receptors
Types
Channel-linked receptors
Mediate fast synaptic transmission
G protein-linked receptor
Oversee slow synaptic responses

57. Channel-Linked (Ionotropic) Receptors: Mechanism of Action
Ligand-gated ion channels
Action is immediate and brief
Excitatory receptors are channels for small actions
Na+ influx contributes most to depolarization
Inhibitory receptors allow Cl– influx that causes hyperpolarization

58. Ion flow blocked Ions flow Ligand Closed ion channel Open ion channel
Figure Direct neurotransmitter receptor mechanism: Channel-linked receptors.
Ion flow blocked
Ions flow
Ligand
Closed ion
channel
Open ion
channel

59. G Protein-Linked (Metabotropic) Receptors: Mechanism of Action
Responses are indirect, complex, slow, and often prolonged
Transmembrane protein complexes
Cause widespread metabolic changes
Examples: muscarinic ACh receptors, receptors that bind biogenic amines and neuropeptides

60. G Protein-Linked Receptors: Mechanism
Neurotransmitter binds to G protein–linked receptor
G protein is activated
Activated G protein controls production of second messengers, e.g., Cyclic AMP, cyclic GMP, diacylglycerol, or Ca2+

61. G Protein-Linked Receptors: Mechanism
Second messengers
Open or close ion channels
Activate kinase enzymes
Phosphorylate channel proteins
Activate genes and induce protein synthesis

62. Figure 11.21 Indirect neurotransmitter receptor mechanism: G protein–linked receptors.
Slide 1
Recall from Chapter 3 that G protein
signaling mechanisms are like a
molecular relay race.
Ligand (1st
messenger)
Receptor
G protein
Enzyme
2nd
messenger
Neurotransmitter
(1st messenger) binds
and activates receptor. 1
Adenylate cyclase
Closed ion channel
Open ion channel
Receptor
G protein 5a
cAMP changes membrane
permeability by opening or
closing ion channels.
cAMP activates
specific genes. 5c
GDP
cAMP activates
enzymes. 5b
Receptor
activates G
protein. 2
G protein
activates
adenylate
cyclase. 3
Adenylate
cyclase converts
ATP to cAMP
(2nd messenger). 4
Nucleus
Active enzyme

63. Figure 11.21 Indirect neurotransmitter receptor mechanism: G protein–linked receptors.
Slide 2
Recall from Chapter 3 that G protein
signaling mechanisms are like a
molecular relay race.
Ligand (1st
messenger)
Receptor
G protein
Enzyme
2nd
messenger
Neurotransmitter
(1st messenger) binds
and activates receptor. 1
Receptor
Nucleus

64. Figure 11.21 Indirect neurotransmitter receptor mechanism: G protein–linked receptors.
Slide 3
Recall from Chapter 3 that G protein
signaling mechanisms are like a
molecular relay race.
Ligand (1st
messenger)
Receptor
G protein
Enzyme
2nd
messenger
Neurotransmitter
(1st messenger) binds
and activates receptor. 1
Receptor
G protein
GDP
Receptor
activates G
protein. 2
Nucleus

65. Figure 11.21 Indirect neurotransmitter receptor mechanism: G protein–linked receptors.
Slide 4
Recall from Chapter 3 that G protein
signaling mechanisms are like a
molecular relay race.
Ligand (1st
messenger)
Receptor
G protein
Enzyme
2nd
messenger
Neurotransmitter
(1st messenger) binds
and activates receptor. 1
Adenylate cyclase
Receptor
G protein
GDP
Receptor
activates G
protein. 2
G protein
activates
adenylate
cyclase. 3
Nucleus

66. Figure 11.21 Indirect neurotransmitter receptor mechanism: G protein–linked receptors.
Slide 5
Recall from Chapter 3 that G protein
signaling mechanisms are like a
molecular relay race.
Ligand (1st
messenger)
Receptor
G protein
Enzyme
2nd
messenger
Neurotransmitter
(1st messenger) binds
and activates receptor. 1
Adenylate cyclase
Receptor
G protein
GDP
Receptor
activates G
protein. 2
G protein
activates
adenylate
cyclase. 3
Adenylate
cyclase converts
ATP to cAMP
(2nd messenger). 4
Nucleus

67. Figure 11.21 Indirect neurotransmitter receptor mechanism: G protein–linked receptors.
Slide 6
Recall from Chapter 3 that G protein
signaling mechanisms are like a
molecular relay race.
Ligand (1st
messenger)
Receptor
G protein
Enzyme
2nd
messenger
Neurotransmitter
(1st messenger) binds
and activates receptor. 1
Adenylate cyclase
Closed ion channel
Open ion channel
Receptor
G protein 5a
cAMP changes membrane
permeability by opening or
closing ion channels.
GDP
Receptor
activates G
protein. 2
G protein
activates
adenylate
cyclase. 3
Adenylate
cyclase converts
ATP to cAMP
(2nd messenger). 4
Nucleus

68. Figure 11.21 Indirect neurotransmitter receptor mechanism: G protein–linked receptors.
Slide 7
Recall from Chapter 3 that G protein
signaling mechanisms are like a
molecular relay race.
Ligand (1st
messenger)
Receptor
G protein
Enzyme
2nd
messenger
Neurotransmitter
(1st messenger) binds
and activates receptor. 1
Adenylate cyclase
Closed ion channel
Open ion channel
Receptor
G protein 5a
cAMP changes membrane
permeability by opening or
closing ion channels.
cAMP activates
enzymes. 5b
GDP
Receptor
activates G
protein. 2
G protein
activates
adenylate
cyclase. 3
Adenylate
cyclase converts
ATP to cAMP
(2nd messenger). 4
Nucleus
Active enzyme

69. Figure 11.21 Indirect neurotransmitter receptor mechanism: G protein–linked receptors.
Slide 8
Recall from Chapter 3 that G protein
signaling mechanisms are like a
molecular relay race.
Ligand (1st
messenger)
Receptor
G protein
Enzyme
2nd
messenger
Neurotransmitter
(1st messenger) binds
and activates receptor. 1
Adenylate cyclase
Closed ion channel
Open ion channel
Receptor
G protein 5a
cAMP changes membrane
permeability by opening or
closing ion channels.
cAMP activates
specific genes. 5c
GDP
cAMP activates
enzymes. 5b
Receptor
activates G
protein. 2
G protein
activates
adenylate
cyclase. 3
Adenylate
cyclase converts
ATP to cAMP
(2nd messenger). 4
Nucleus
Active enzyme

70. Basic Concepts of Neural Integration
Neurons function in groups
Groups contribute to broader neural functions
There are billions of neurons in CNS
Must be integration so the individual parts fuse to make a smoothly operating whole

71. Organization of Neurons: Neuronal Pools
Functional groups of neurons
Integrate incoming information received from receptors or other neuronal pools
Forward processed information to other destinations
Simple neuronal pool
Single presynaptic fiber branches and synapses with several neurons in pool
Discharge zone—neurons most closely associated with incoming fiber
Facilitated zone—neurons farther away from incoming fiber

72. Figure 11.22 Simple neuronal pool.
Presynaptic
(input) fiber
Facilitated zone
Discharge zone
Facilitated zone

73. Types of Circuits Circuits Four types of circuits
Patterns of synaptic connections in neuronal pools
Four types of circuits
Diverging
Converging
Reverberating
Parallel after-discharge

74. Figure 11.23a Types of circuits in neuronal pools.
Input
Diverging circuit
• One input, many outputs
• An amplifying circuit
• Example: A single neuron in the
brain can activate 100 or more motor
neurons in the spinal cord and
thousands of skeletal muscle fibers
Many outputs

75. Figure 11.23b Types of circuits in neuronal pools.
Input 1
Converging circuit
• Many inputs, one output
• A concentrating circuit
• Example: Different sensory stimuli
can all elicit the same memory
Input 2
Input 3
Output

76. Figure 11.23c Types of circuits in neuronal pools.
Input
Reverberating circuit
• Signal travels through a chain of
neurons, each feeding back to
previous neurons
• An oscillating circuit
• Controls rhythmic activity
• Example: Involved in
breathing, sleep-wake cycle,
and repetitive motor activities
such as walking
Output

77. Figure 11.23d Types of circuits in neuronal pools.
Input
Parallel after-discharge
circuit
• Signal stimulates neurons
arranged in parallel arrays that
eventually converge on a
single output cell
• Impulses reach output cell at
different times, causing a burst
of impulses called an after-discharge
• Example: May be involved in
exacting mental processes
such as mathematical calculations
Output

78. Patterns of Neural Processing: Serial Processing
Input travels along one pathway to a specific destination
System works in all-or-none manner to produce specific, anticipated response
Example – spinal reflexes
Rapid, automatic responses to stimuli
Particular stimulus always causes same response
Occur over pathways called reflex arcs
Five components: receptor, sensory neuron, CNS integration center, motor neuron, effector

79. Figure 11.24 A simple reflex arc.
Stimulus
Interneuron 1
Receptor 2
Sensory neuron 3
Integration center 4
Motor neuron 5
Effector
Spinal cord (CNS)
Response

80. Patterns of Neural Processing: Parallel Processing
Input travels along several pathways
Different parts of circuitry deal simultaneously with the information
One stimulus promotes numerous responses
Important for higher-level mental functioning
Example: a sensed smell may remind one of an odor and any associated experiences

81. Patterns of Neural Processing: Parallel Processing
Input travels along several pathways
Different parts of circuitry deal simultaneously with the information
One stimulus promotes numerous responses
Important for higher-level mental functioning
Example: a sensed smell may remind one of an odor and any associated experiences