Nervous_System_1.pptx

Full Transcript

Nervous System

Structure and Function
 Functions

Sensory input

Integration

Motor output
 Classification

Central Nervous System
◻ CNS

Peripheral Nervous System
◻ PNS
 Divisions of Peripheral Nervous System
Sensory Division

Motor Division
◻ muscles and glands

Divisions of the
Motor
◻ Somatic
◻ Autonomic
 Central nervous system (CNS) Peripheral nervous system (PNS)
Brain and spinal cord Cranial nerves and spinal nerves
Integrative and control centers Communication lines between the
CNS and the rest of the body

Sensory (afferent) division Motor (efferent) division
Somatic and visceral sensory Motor nerve fibers
nerve fibers Conducts impulses from the CNS
Conducts impulses from to effectors (muscles and glands)
receptors to the CNS

Somatic sensory Somatic nervous Autonomic nervous
fiber system system (ANS)
Skin
Somatic motor Visceral motor
(voluntary) (involuntary)
Conducts impulses Conducts impulses
from the CNS to from the CNS to
skeletal muscles cardiac muscles,
Visceral sensory fiber smooth muscles,
Stomach and glands
Skeletal
muscle
Motor fiber of somatic nervous system

Sympathetic division Parasympathetic
Mobilizes body division
systems during activity Conserves energy
Promotes house-
keeping functions
during rest

Sympathetic motor fiber of ANS
Heart
Structure
Function
Sensory (afferent)
division of PNS Parasympathetic motor fiber of ANS Bladder
Motor (efferent)
division of PNS

Figure 11.2
How it works
 Neurons = nerve cells

Long lived, no mitosis,
Cell body- developed Golgi
Extensions outside the cell body
◻ Dendrites
◻ Axons
◻ Axonal terminals contain vesicles with
neurotransmitters
Axonal terminals are separated from by a gap
◻ Synapse
Nerve Coverings
Myelin- Lipid/Protein

Schwann cells

Nodes of Ranvier
Schwann cell
plasma membrane
Schwann cell 1A Schwann cell
cytoplasm envelopes an axon.
Axon Schwann cell
nucleus

2 The Schwann cell then
rotates around the axon,
wrapping its plasma
membrane loosely around
it in successive layers.

Neurilemma 3 The Schwann cell
Myelin sheath cytoplasm is forced from
between the membranes.
The tight membrane
wrappings surrounding
(a) Myelination of a nerve the axon form the myelin
fiber (axon) sheath.

Figure 11.5a
 Classification of Neurons
Multipolar neurons

Bipolar

Unipolar
 Classification Cont..
Sensory Neurons
◻ afferent
◻ most are unipolar
◻ some are bipolar
Interneurons
◻ multipolar
◻ in CNS
Motor Neurons
◻ multipolar
◻ carry impulses to effectors, muscle
Table 11.1 (2 of 3)
 Neuroglial Cells: Support Cells
Schwann Cells-PNS

Oligodendrocytes-CNS

Microglia-CNS

Astrocytes- CNS

Ependyma-CNS
Regeneration of Injury (if possible)
Principles of Electricity
Opposite charges attract each other
Energy is required to separate opposite
charges across a membrane
Energy is liberated when the charges move
toward one another
If opposite charges are separated, the
system has potential energy
Definitions
Voltage (V): measure of potential energy
generated by separated charge
Potential difference: voltage measured
between two points
Current (I): the flow of electrical charge
(ions) between two points
Definitions
Resistance (R): hindrance to charge flow
(provided by the plasma membrane)
Insulator: substance with high electrical
resistance
Conductor: substance with low electrical
resistance
Role of Membrane Ion Channels

1. Leakage (nongated) channels—always
open
2. Gated channels (three types):
◻ Chemically gated (ligand-gated)
◻ Voltage-gated channels
◻ Mechanically gated channels
 Generating a Nerve Impulse
polarized
membrane:
inside is
negative
relative to
the outside
under resting
conditions
-70 mV
 Voltmeter

Plasma Ground electrode
membrane outside cell

Microelectrode
inside cell

Axon

Neuron

Figure 11.7
Action Potential (AP)
Brief reversal of membrane potential with a
total amplitude of ~100 mV
Occurs in muscle cells and axons of neurons
Does not decrease in magnitude over
distance
Principal means of long-distance neural
communication
The big picture
1 Resting state
Membrane potential (mV) 2 Depolarization 3 Repolarization

3
4 Hyperpolarization

2 Action
potential

Threshold

1 1
4

Time (ms)

Figure 11.11 (1 of 5)
Generation of an Action
Potential
Resting state
◻ Only leakage channels for Na+ and K+ are
open
◻ All gated Na+ and K+ channels are closed
Depolarizing Phase
Na+ influx causes more depolarization
At threshold (–55 to –50 mV) positive
feedback leads to opening of all Na+
channels, and a reversal of membrane
polarity to +30mV (spike of action potential)
Repolarizing Phase
Repolarizing phase
◻ Na+ channel slow inactivation gates close
◻ Membrane permeability to Na+ declines to
resting levels
◻ Slow voltage-sensitive K+ gates open
◻ K+ exits the cell and internal negativity is
restored
Hyperpolarization
Hyperpolarization
◻ Some K+ channels remain open, allowing
excessive K+ efflux
◻ This causes after-hyperpolarization of the
membrane (undershoot)
 The AP is caused by permeability changes in
the plasma membrane

Relative membrane permeability
Membrane potential (mV)

3
Action
potential

2 Na+ permeability

K+ permeability

1 1
4

Time (ms)
Figure 11.11 (2 of 5)
 Voltage
at 0 ms

Recording
electrode

(a) Time = 0 ms. Action
potential has not yet
reached the recording
electrode.

Resting potential
Peak of action potential
Hyperpolarization
Figure 11.12a
 Voltage
at 2 ms

(b) Time = 2 ms. Action
potential peak is at the
recording electrode.

Figure 11.12b
 Voltage
at 4 ms

(c) Time = 4 ms. Action
potential peak is past
the recording electrode.
Membrane at the
recording electrode is
still hyperpolarized.

PLAY A&P Flix™: Propagation of an Action Potential

Figure 11.12c
Impulse Conduction
Coding for Stimulus Intensity
All action potentials are alike and are
independent of stimulus intensity
◻ How does the CNS tell the difference between a
weak stimulus and a strong one?
Strong stimuli can generate action potentials
more often than weaker stimuli
The CNS determines stimulus intensity by the
frequency of impulses
 Saltatory Conduction

Appear the
jump from
node to node.
Speed of
impulses is
much faster on
myelinated
nerves then
unmyelinated
ones. Speed
also increases
with increase in
diameter. Ex.)
120m/s skeletal
muscle.5m/s
skin.
 Conduction Velocity
Conduction velocities of neurons vary widely
Effect of axon diameter
Effect of myelination
◻ Myelin sheaths insulate and prevent leakage of
charge
◻ Saltatory conduction in myelinated axons is about
30 times faster
Nerve Fiber Classification
Group A fibers
◻ Largediameter, myelinated somatic sensory
and motor fibers
Group B fibers
◻ Intermediate diameter, lightly myelinated ANS
fibers
Group C fibers
◻ Smallest diameter, unmyelinated ANS fibers
 The Synapse
Presynaptic neuron—conducts impulses
toward the synapse
Postsynaptic neuron—transmits impulses
away from the synapse
Axodendritic
Axosomatic
Some electrical, most chemical
Cleft = gap
 Axodendritic
synapses
Dendrites
Axosomatic
synapses Cell body
Axoaxonic synapses

(a)
Axon
Axon

Axosomatic
synapses

Cell body (soma) of
(b) postsynaptic neuron
Figure 11.16
 Chemical synapses
transmit signals from
one neuron to another
using neurotransmitters.
Presynaptic
neuron

Presynaptic
Postsynaptic neuron
neuron

1 Action potential
arrives at axon terminal.
2 Voltage-gated Ca2+
channels open and Ca2+
Mitochondrion
enters the axon terminal. Ca2+
Ca2+
Ca2+
Ca2+
3 Ca2+ entry causes Synaptic
neurotransmitter- cleft
containing synaptic Axon
terminal Synaptic
vesicles to release their vesicles
contents by exocytosis.
4 Neurotransmitter
diffuses across the synaptic
cleft and binds to specific Postsynaptic
receptors on the neuron
postsynaptic membrane.

Ion movement Enzymatic
Graded potential degradation
Reuptake

Diffusion away
from synapse

5 Binding of neurotransmitter
opens ion channels, resulting in
graded potentials.
6 Neurotransmitter effects are
terminated by reuptake through
transport proteins, enzymatic
degradation, or diffusion away
from the synapse.

Figure 11.17
Membrane potential (mV)

An EPSP is a local
depolarization of the
postsynaptic membrane
that brings the neuron
closer to AP threshold.
Neurotransmitter binding
opens chemically gated
Threshold ion channels, allowing
the simultaneous pas-
sage of Na+ and K+.

Stimulus

Time (ms)
(a) Excitatory postsynaptic potential (EPSP)

Figure 11.18a
Membrane potential (mV)

An IPSP is a local
hyperpolarization of the
postsynaptic membrane
and drives the neuron
away from AP threshold.
Neurotransmitter binding
opens K+ or Cl– channels.
Threshold

Stimulus

Time (ms)
(b) Inhibitory postsynaptic potential (IPSP)

Figure 11.18b
Integration: Summation
A single EPSP cannot induce an action
potential
EPSPs can summate to reach threshold
IPSPs can also summate with EPSPs,
canceling each other out
 Neurotransmitters
Most neurons make two or more
neurotransmitters, which are released at
different stimulation frequencies
50 or more neurotransmitters have been
identified
Classified by chemical structure and by
function
Some excite and some inhibit
Can be nucleotides, gas, protein, amino acid,
lipoprotein
Neurotransmitters
 Ion flow blocked Ions flow
Ligand

Closed ion channel Open ion channel
(a) Channel-linked receptors open in response to binding
of ligand (ACh in this case).

Figure 11.20a
 1 Neurotransmitter Closed ion Open ion
(1st messenger) binds Adenylate cyclase channel channel
and activates receptor.

Receptor
G protein

5a cAMP changes
membrane permeability
by opening or closing ion
channels. 5c cAMP activates
specific genes.
GDP 5b cAMP activates
enzymes.
2 Receptor 3 G protein 4 Adenylate
activates G activates cyclase converts
protein. adenylate ATP to cAMP
cyclase. (2nd messenger). Nucleus
Active enzyme
(b) G-protein linked receptors cause formation of an intracellular second messenger (cyclic
AMP in this case) that brings about the cell’s response.

Figure 11.17b
Figure 11.22a
Figure 11.22b
Figure 11.22c, d
Clinical Application.
Multiple Sclerosis
Symptoms Causes
blurred vision myelin destroyed in
numb legs or arms various parts of CNS
can lead to paralysis hard scars
(scleroses) form
nerve impulses
Treatments blocked
no cure muscles do not
bone marrow transplant
receive innervation
interferon (anti-viral drug) may be related to a
hormones
virus 10-29