1. NERVOUS SYSTEM
2. NERVOUS FUNCTIONS Body’s master controlling and communicating system
Three functions
Sensory input
Gathers information �from sensory receptors
Integration
Processes and interprets �sensory input
Motor output
Activates effector organs to cause a response
3. ORGANIZATION Two Principal Parts of the System
Central nervous system (CNS)
Brain and spinal cord
Integrating and command center
Interprets sensory input
Dictates motor responses
Peripheral nervous system (PNS)
Nerves extending from brain and spinal cord
Carry impulses to and from the CNS
4. PERIPHERAL DIVISIONS Two Functional Subdivisions of the PNS
Sensory division
a.k.a. “afferent division”
Nerve fibers conveying impulses to the CNS
Somatic afferent fibers convey impulses from the skin, muscles, and joints
Visceral afferent fibers convey impulses from visceral organs
Motor division
a.k.a., “efferent division”
Nerve fibers conveying impulses from the CNS
5. MOTOR DIVISIONS Two Parts of the Motor Division
Somatic nervous system
a.k.a., “voluntary nervous system”
Nerve fibers conducting impulses from CNS to skeletal muscles
Autonomic nervous system
a.k.a., “involuntary nervous system”
Nerve fibers regulating the activity of smooth muscles, cardiac muscles, and glands
6. AUTONOMIC DIVISIONS Functional Subdivisions of the Autonomic Nervous System
Sympathetic
Mobilizes body systems during emergency situations
Parasympathetic division
Conserves energy
Promotes non-emergency functions
7. ORGANIZATION Summary
Central nervous system
Brain
Spinal cord
Peripheral nervous system
Sensory division
Motor division
Somatic nervous system
Autonomic nervous system
Sympathetic division
Parasympathetic division
8. HISTOLOGY Nervous system consists mainly of nervous tissue
Highly cellular
e.g., <20% extracellular space in CNS
Two principal cell types
Neurons
Excitable nerve cells that transmit electrical signals
Supporting cells
Smaller cells surrounding and wrapping neurons
“Neuroglia”
9. NEUROGLIA “Nerve glue”
Six types of small cells associated with neurons
4 in CNS
2 in PNS
Most have central cell body and branching processes
Several functions
e.g., Supportive scaffolding for neurons
e.g., Electrical isolation of neurons
e.g., Neuron health and growth
10. CNS NEUROGLIA Astrocytes
Microglia
Ependymal cells
Oligodendrocytes
11. CNS NEUROGLIA Astrocytes
Most abundant and versatile glial cells
Numerous processes support branching neurons
Anchor neurons to capillary blood supply
Guide migration of young neurons
Facilitate nutrient delivery to neurons
(blood ? glial cell ? neuron)
Control chemical environment �around neurons
Uptake of K+, neurotransmitters
Communicate with astrocytes �& neurons
Gap junctions, Ca2+ surges
12. CNS NEUROGLIA Microglia
Small ovoid cells
Relatively long “thorny” �processes
Processes touch nearby neurons
“Checking vitals”
Migrate toward injured neurons
Transform into macrophage
Phagocytize microorganisms, debris
(Cells of immune system cannot enter the CNS)
13. CNS NEUROGLIA Ependymal Cells
Line central cavities of brain and spinal cord
Form permeable barrier between cerebrospinal fluid inside these cavities and tissue fluid of CNS tissue
Shapes range from squamous to columnar
Many are ciliated
Beating helps circulate cerebrospinal fluid cushioning brain and spinal cord
14. CNS NEUROGLIA Oligodendrocytes
Fewer processes than astrocytes
Wrap processes tightly around thicker neuron fibers in CNS
“Myelin sheath”
Insulating covering
15. PNS NEUROGLIA Satellite cells
Schwann cells
16. PNS NEUROGLIA Satellite cells
Surround neuron cell bodies within ganglia
(A ganglion is a collection of nerve cell bodies outside of the CNS)
Function poorly understood
17. PNS NEUROGLIA Schwann cells
a.k.a., “Neurolemmocytes”
Surround and form myelin sheaths around larger nerve fibers of PNS
Functionally similar to oligodendrocytes
Vital to regeneration of peripheral nerve fibers
18. NEURONS a.k.a., Nerve cells
Structural units of nervous system
Billions are present in nervous system
Conduct messages throughout body
Nerve impulses
Extreme longevity
Can function optimally for entire lifetime
Amitotic
Ability to divide is lost in mature cells
Cannot be replaced if destroyed
Some (very few) exceptions
e.g., stem cells present in olfactory epithelium can produce new neurons
Stem cell research shows great promise in repairing damaged neurons
High metabolic rate
Require large amounts of oxygen and glucose
19. NEURONS Generally large, complex cells
Structures vary, but all neurons have the same basic structure
Cell body
Slender processes �extending from cell �body
Plasma membrane �is site of signaling
20. NEURON CELL BODY Most neuron cell bodies are located in the CNS
Protected by bones of skull or vertebral column
Clusters of cell bodies in the CNS are termed “nuclei”
Clusters of cell �bodies in the �PNS are �termed �“ganglia”
21. NEURON CELL BODY a.k.a., “perikaryon” or “soma”
5 – 140 mm in diameter
Transparent spherical nucleus
Contains �conspicuous �nucleolus
22. NEURON CELL BODY Major biosynthetic center of neuron
Other usual organelles present
ER & ribosomes most active and best developed in body
What do they do?
Centrioles absent
What do centrioles �do?
Sometimes contains �pigment inclusions
23. NEURON CELL BODY Focal point for the outgrowth of neuron processes during embryonic development
Some processes receive signals
Plasma membrane �generally also acts �as part of the �receptive surface
24. NEURON PROCESSES Extend from the neuron’s cell body
CNS contains both neuron cell bodies and their processes
Bundles of CNS processes are termed “tracts”
PNS consists mainly of neuronal processes
Bundles of PNS processes are termed “nerves”
Two types of neuron processes
Dendrites
Axons
25. NEURON PROCESSES Typical Dendrite
Short, tapering, diffusely branching extensions
Generally hundreds clustering close to cell body
Most cell body organelles also present in dendrites
Main receptive / input regions
Large surface area for �receiving signals from �other neurons
Convey incoming messages �toward cell body
Short-distance signals are �“graded potentials”
Not action potentials
26. NEURON PROCESSES Typical Axon
Single axon per neuron
“Axon hillock” of cell body narrows to form a slender process of uniform diameter
Sometimes very short
Sometimes very long
e.g., axons controlling �big toe are 3 – 4 feet �long
27. NEURON PROCESSES Typical Axon
Single axon may branch along length
“Axon collaterals” extend from neurons at ~ 90o angles
Usually branches �profusely at end
10,000 or more �terminal branches �is common
Distal endings �termed “axonal �terminals”
28. NEURON PROCESSES Typical Axon
Conducting component of neuron
Generates nerve impulses
Generated at axon hillock / axon junction in motor neurons
“Trigger zone”
Transmits nerve �impulses away from �cell body
To axonal terminals
29. NEURON PROCESSES Typical Axon
Axonal terminals are secretory component of neuron
Sequence of events
Signal reaches terminals
Membranes of vesicles fuse with �plasma membrane
“Axolemma”
Neurotransmitters released
Neurotransmitters interact �with either other neurons �or effector cells
Excite or inhibit
30. NEURON PROCESSES Typical Axon
Contains most of the same organelles found in dendrites and cell body
Lacks ER and Golgi apparatus
What do these �organelles do?
Must rely on cell �body to renew what?
31. NEURON PROCESSES Typical Axon
Rely on cell body for some molecules
Rely on efficient transport mechanisms for delivery
Anterograde movement toward axonal terminals
e.g., Mitochondria, �membrane components, �neurotransmitters or �enzymes required for �neurotransmitter �synthesis, etc.
Retrograde movement �toward cell body
e.g., Organelles being �returned for recycling
32. NEURON PROCESSES Typical Axon
Some viruses and bacterial toxins use retrograde transport to reach the cell body
e.g., poliovirus, rabies virus, herpes simplex viruses, tetanus toxin, etc.
Such viruses can be �used as vehicles for the �therapeutic delivery of �engineered DNA
“Gene therapy”
33. MYELIN SHEATH Whitish, fatty covering of many nerve fibers
Particularly those long are large in diameter
Protects and electrically insulates fibers
Increases speed of nerve impulse transmission
Some axons and all dendrites are unmyelinated
34. MYELIN SHEATH In PNS, myelin sheaths formed by Schwann cells
Continually wrap around nerve
Cytoplasm gradually squeezed from intracellular space
Result is many concentric layers of plasma membrane surrounding the axon
These plasma membranes contain little protein
Some proteins present interlock adjacent membranes
Thickness depends on number of wrappings
Nucleus and most of �cytoplasm exist as a bulge �external to the myelin sheath
“Neurilemma”
35. MYELIN SHEATH Adjacent Schwann cells on axon do not touch each other
Gaps in sheath occur at regular intervals
“Nodes of Ranvier”
a.k.a., “Neurofibril �nodes”
Axon collaterals �can emerge at �these nodes
36. MYELIN SHEATH CNS contains both myelinated and unmyelinated axons
Those long are large in diameter are typically myelinated
Oligodendrocytes, not Schwann cells, form CNS myelin sheaths
Oligodendrocytes possess numerous processes that can coil around numerous (up to 60) axons at once
CNS myelin sheaths lack a neurilemma
37. MYELIN SHEATH White matter
Regions of the brain and spinal cord containing dense collections of myelinated fibers
Gray matter
Regions of the brain and spinal cord containing mostly nerve cell bodies and unmyelinated fibers
38. NEURON CLASSIFICATION Structural classification based upon number of processes
Multipolar neurons
Bipolar neurons
Unipolar neurons
Functional classification based upon direction nerve impulse travels
Sensory (afferent) neurons
Motor (efferent) neurons
Interneurons (association neurons)
39. NEURON CLASSIFICATION Structural Classification
Multipolar neurons
Three or more processes
Most common neuron type in humans
(> 99% of neurons)
Bipolar neurons
Two processes – axon and dendrite
Found only in some special sense organs
e.g., retina of eye
Act as receptor cells
Unipolar neurons
Single short process
“Pseudounipolar neurons”
Originate as bipolar neurons
Two processes converge and fuse
Process divides into proximal and distal branches
Distal process often associated with a sensory receptor
“Peripheral process”
Central process enters CNS
Most are sensory neurons in PNS
40. NEURON CLASSIFICATION Functional Classification
Sensory (afferent) neurons
Transmit impulses toward CNS
From sensory receptors or internal organs
Most are unipolar
Cell bodies are located outside CNS
Motor (efferent) neurons
Carry impulses away from CNS
Toward effector organs
Multipolar
Cell bodies generally located in the CNS Interneurons
a.k.a., association neurons
Lie between motor and sensory neurons in neural pathways
Shuttle signals through CNS pathways where integration occurs
> 99% of neurons in body
Most are multipolar
Most are confined within the CNS
41. NEUROPHYSIOLOGY Neurons are highly irritable
Responsive to stimuli
Response to stimulus is action potential
Electrical impulse carried along length of axon
Always the same regardless of stimulus
The underlying functional feature of the nervous system
42. ELECTRICITY Voltage (V)
Measure of potential energy
Measured between two points
“Potential difference” or simply “potential”
Measured in volts or millivolts
Current (I)
Flow of electrical charge from one point to another
Can be used to do work
Amount of charge moved depends on voltage & resistance
Resistance (R)
Hindrance to charge flow
Provided by substances through which the current must pass
43. ELECTRICITY Ohm’s Law
Current = Voltage / Resistance
I = V / R
voltage = current * resistance
V = I * R
44. ELECTRICITY Electrical currents involve the flow of ions across membranes
Resistance to current flow is provided by the plasma membrane
Movement of ions across the plasma membrane is regulated by membrane ion channels
45. ION CHANNELS Plasma membranes contain various ion channels
Passive channels (leakage channels)
Always open
Active channels (gated channels)
Ligand-gated channels
Open when specific chemical binds
Voltage-gated channels
Open and close in response to membrane potential
Mechanically-gated channels
Open in response to physical deformation of receptor
e.g., touch and pressure receptors
46. ION CHANNELS Channels are specific as to what type of ions are allowed to pass
e.g., K+ channels allow only K+ to pass
Ions moving through open channels follow their electrochemical gradients
Electrical current is generated
Voltage changes across the membrane
47. MEMBRANE POTENTIALS A voltage exists across the plasma membrane
Due to separation of oppositely charged ions
Potential difference in a resting membrane is termed its “resting membrane potential”
~ -70 mV in a resting �neuron
Membrane is �“polarized”
48. MEMBRANE POTENTIALS Resting potential exists across the membrane
Majority of Na+ outside of cell Why?
Majority of K+ inside of cell Why?
Resting membrane
Only slightly permeable to Na+
75 times more permeable to K+
How do these ions cross the membrane?
49. MEMBRANE POTENTIALS Neurons use changes in membrane potentials as signals
Used to receive, integrate, and send signals
Changes in membrane potentials produced by
Anything changing membrane permeability to ions
Anything altering ion concentrations
Two types of signals
Graded potentials
Short-distance signals
Action potentials
Long-distance signals
50. MEMBRANE POTENTIALS Changes in membrane potentials are caused by three events
Depolarization
Inside of membrane becomes less negative
Nerve impulses more likely to be produced
Repolarization
Membrane returns to resting membrane potential
Hyperpolarization
Inside of membrane becomes more negative than the resting potential
Nerve impulses less likely to be produced
51. MEMBRANE POTENTIALS Graded Potentials
Short-lived local changes in membrane potential
Either depolarizations or hyperpolarizations
Cause current flows that decrease in magnitude with distance
Magnitude of potential dependent upon stimulus strength
Stronger stimulus ? larger voltage change
Larger voltage change ? farther current flows
52. MEMBRANE POTENTIALS Graded Potentials
Triggered by change in neuron’s environment
Change causes gated ion channels to open
Small area of neuron’s plasma membrane becomes depolarized (by this stimulus)
Current flows on both sides of the membrane
+ moves toward – and vise versa
53. MEMBRANE POTENTIALS Graded Potentials
Inside cell: + ions move away from depolarized area
Outside cell: + ions move toward depolarized area
(+ and – ions switch places)
Membrane is leaky
Most of the charge is quickly lost through membrane
Current dies out after traveling a short distance
54. MEMBRANE POTENTIALS Graded Potentials
Act as signals over very short distances
Important in initiating action potentials
55. MEMBRANE POTENTIALS Action Potentials
Principal means by which neurons communicate
Brief reversal of membrane potential
Total amplitude of ~ 100 mV (-70 ? +30)
Depolarization followed by repolarization, then brief period of hyperpolarization
Time for entire event is only a few milliseconds
Events in generation and transmission of an action potential identical between neurons and skeletal muscle cells
56. ACTION POTENTIALS
57. ACTION POTENTIALS Not all local depolarizations produce action potentials
Depolarization must reach threshold values
Brief, weak stimuli produce subthreshold depolarizations that are not translated into nerve impulses
Stronger threshold stimuli produce depolarizing events
58. ACTION POTENTIALS Action potential is all-or-nothing phenomenon
Happens completely or doesn’t happen
Independent of stimulus strength once generated
Strong stimuli generate more impulses of the same strength per unit time
Intensity is determined by number of impulses per unit time
59. ACTION POTENTIALS Refractory Periods
Neuron cannot respond to a second stimulus while the Na+ channels are still open from previous stimulus
This period of time is termed the “absolute refractory period”
“Relative refractory period” follows the absolute refractory period
Repolarization is occurring
Threshold for impulse generation is elevated
Only strong stimuli can generate impulses
60. ACTION POTENTIALS Conduction Velocities
Conduction velocities of neurons vary widely
Rate of impulse propagation dependent upon
Axon diameter
Larger axons conduct impulses faster
Degree of myelination
Myelin sheath dramatically increases rate of propagation
Myelin acts as an insulator to prevent almost all leakage from axon
61. ACTION POTENTIALS Multiple Sclerosis (MS)
Autoimmune disease mainly affecting young adults
Myelin sheaths in CNS are gradually destroyed
Interferes with impulse conduction
Visual disturbances, muscle control problems, speech disturbances, etc.
Some modern treatments showing some promise in delaying problems
62. NERVE FIBERS Classified based on
Diameter
Degree of myelination
Conduction speed
63. NERVE FIBER CLASSIFICATION Group A fibers
Largest diameter
Thick myelin sheaths
Conduct impulses at high speeds (> 300 mph)
Mostly somatic sensory ad motor fibers serving skin, skeletal muscles, and joints
Group B fibers
Intermediate diameter
Lightly myelinated
Transmit impulses at moderate speeds (40 mph)
Group C fibers
Smallest diameter
Unmyelinated
Transmit impulses comparatively slowly (2 mph or less)
64. ION CHANNELS Various chemicals block nerve impulses
e.g., alcohol, sedatives, anesthetics, etc.
Mechanisms differ, but all reduce membrane permeability to Na+
No Na+ entry ? no action potential
Neurons also impaired by cold or continuous pressure
Blood supply interrupted
O2 delivery compromised
65. SYNAPSE Junction mediating information transfer from one neuron to another neuron or an effector cell
Axodendritic synapses
Axonal endings ? dendrites of second neuron
Axosomatic synapses
Axonal endings ? cell body of neuron
Presynaptic neuron
Conducts impulses toward the synapse
Postsynaptic neuron
Transmits impulse away from the synapse
66. SYNAPSE TYPES Electrical Synapses
Less common than chemical synapses
Correspond to gap junctions found elsewhere
Cytoplasm of adjacent neurons connected through protein channels
Ions flow directly between neurons
Neurons are “electrically coupled”
Transmission across synapse is very rapid
67. SYNAPSE TYPES Chemical Synapses
Specialized for release & reception of neurotransmitters
Two parts
Axonal terminal of presynaptic neuron
Contains numerous synaptic vesicles filled with neurotransmitter molecules
Neurotransmitter receptor region
Present on dendrite or cell body of postsynaptic neuron
Separated by synaptic cleft
Remember this stuff in muscles?
68. SYNAPSE Nerve impulse reaches axonal terminal
Voltage-gated Ca2+ channels open in axon
Ca2+ enters presynaptic neuron
Neurotransmitter is released via exocytosis
Vesicles fuse with axonal membrane
Neurotransmitter binds to postsynaptic receptors
Ion channels open in �postsynaptic membrane
Result is excitation or �inhibition
69. SYNAPSE Binding of neurotransmitter to its receptor is reversible
Permeability affected as long as neurotransmitter is bound to its receptor
Neurotransmitters do not persist in the synaptic cleft
Degraded by enzymes associated with postsynaptic membrane
Reuptake by astrocytes or presynaptic terminal
Diffusion of neurotransmitters away from synapse
70. SYNAPSE Transmission of impulses along axon can be very fast
Up to 300 mph (150 m/s)
Transmission of a signal across a synapse is slow in comparison
Leads to “synaptic delay”
~0.3 0 5.0 milliseconds
Rate-limiting step of neural transmission
Transmission along multisynaptic pathways is slower than along pathways with fewer synapses
71. SYNAPSE Postsynaptic Potentials
Many receptors present on postsynaptic membranes open ion channels
Ligand-gated channels
Electrical signal converted to chemical signal converted to electrical signal
Graded potential is produced
Magnitude is dependent upon amount of neurotransmitter released
Action potential may be produced
Either excitatory or inhibitory
72. SYNAPSE Excitatory Synapses
Neurotransmitter binding causes depolarization
Single type of channel opens in membrane
Na+ and K+ simultaneously diffuse through the membrane in opposite directions
Na+ influx exceeds K+ efflux
Net depolarization occurs
Local graded depolarization events formed
“Excitatory postsynaptic potential (EPSP)”
May trigger an action potential at axon hillock
Voltage-gated channels at hillock open, etc.
73. SYNAPSE Inhibitory Synapses
Neurotransmitter binding reduces a postsynaptic neuron’s ability to generate an action potential
Increased permeability to K+ and Cl-, not Na+
Postsynaptic neuron becomes less likely to fire
“Inhibitory postsynaptic potential (IPSP)”
74. SYNAPSE Summation
A single ESPS cannot induce an action potential
Requires multiple axonal termini firing in concert
Hundreds or thousands of EPSPs act together
“Summation”
Two types of summation
Temporal summation
One or more neurons transmit in rapid succession
Spatial summation
Simultaneous stimulation by numerous termini from one or more neurons
(Both EPSPs and IPSPs summate)
75. SYNAPSE Synaptic Potentiation
Repeated or continuous use of a synapse enhances presynaptic neuron’s ability to excite
Larger postsynaptic potentials produced
“Synaptic potentiation”
Greater [Ca++] inside presynaptic terminals
More neurotransmitter released
Larger EPSPs produced
76. SYNAPSE Presynaptic Inhibition
Release of excitatory neurotransmitter can be inhibited by activity of another neuron
Less neurotransmitter released and bound
77. SYNAPSE Neuromodulation
Presynaptic event effecting postsynaptic activity
Can occur when neurotransmitter acts via slow changes in target cell metabolism
Can occur when chemicals other than neurotransmitters modify neuronal activity
Neuromodulators can influence
Synthesis, release, degradation, or reuptake of neurotransmitters
Sensitivity of postsynaptic membrane
78. NEUROTRANSMITTERS Facilitate communication by neurons
Neurotransmitter release or destruction can be enhanced or inhibited
How can synaptic transmission be affected?
Enhanced or inhibited neurotransmitter release
Enhanced or inhibited neurotransmitter degradation
Blocked receptors or postsynaptic membrane
79. NEUROTRANSMITTERS More than fifty neurotransmitters identified
Most neurons make two or more
Can be released singly or together
Classification by Structure
Acetylcholine (ACh)
Biogenic amines
Amino acids
Peptides
ATP
Dissolved gases
Classification by Function
Excitatory/Inhibitory
Direct/Indirect
80. NEUROTRANSMITTERS Two main types of neurotransmitter receptors
Channel-linked receptors
Mediate fast synaptic transmission
G protein-linked receptors
Mediate slow synaptic responses
81. RECEPTORS Channel-Linked Receptors
“Ligand-gated ion channels”
Composed of “rosettes” of several protein subunits surrounding central pore
Ligand binds to subunit(s) ? subunit shape changes ? central channel opened
82. RECEPTORS G Protein-Linked Receptors
Indirect, slow, and prolonged response
Neurotransmitter binding activates G protein
Intracellular enzymatic activity activated
Second messenger(s) formed inside the cell
Cellular response
83. NEURAL INTEGRATION Neurons function in groups, not singly
These various components must interact
Multiple levels of neural integration
84. NEURONAL POOLS Neurons in CNS are organized into pools
Functional groups
Integrate incoming information
Forward processed information
85. NEURONAL POOLS Simple Neuronal Pool
Incoming fiber branches profusely upon entering pool
EPSPs induced in multiple postsynaptic neurons
EPSPs exceed threshold in some neurons
Mainly those with multiple synaptic contacts
EPSPs do not exceed �threshold in some �neurons
Mainly those with �fewer synaptic contacts
Some close to threshold
“Facilitated zone”
86. TYPES OF CIRCUITS Patterns of synaptic connections in neuronal pools are called circuits
Determine neuronal pool’s functional capabilities
Four basic circuit patterns
Diverging circuits
Converging circuits
Reverberating (oscillating) circuits
Parallel after-discharge circuits
87. TYPES OF CIRCUITS Diverging (Amplifying) Circuit
One incoming fiber triggers responses in ever-increasing numbers of neurons
Common in both sensory and motor systems
88. TYPES OF CIRCUITS Converging Circuits
Pool receives inputs from several neurons
Circuit has “funneling” effect
Common in sensory �and motor systems
89. TYPES OF CIRCUITS Reverberating (Oscillating) Circuits
Incoming signal travels through chain of neurons
Each neuron makes synapses with neurons upstream in the pathway
Involved in rhythmic activities (e.g., breathing)
90. TYPES OF CIRCUITS Parallel After-Discharge Circuits
Incoming fiber stimulated parallel neuron arrays
Parallel arrays ultimately stimulate a common output cell
Create prolonged burst of impulses
Involved in complex �mental processing
91. PROCESSING PATTERNS Serial input processing
Input travels along one pathway to a specific destination
All-or-nothing function of system
e.g., reflexes
Parallel input processing
Inputs are segregated into multiple pathways
Integrated in different CNS regions
Different circuits do different things with input
Not repetitious
