1. Unit IV: Coordination Impulse Transmission
Ch. 11 – pgs
Ch. 14 – pgs

2. Review What is the CSF and what are the three functions it provides?
Which way is caudal?
Which is not a region the spinal nerves are named for? a.) cervical, b.) thoracic, c.) pelvic, d.) lumbar, e.) sacral
How does the location of white and gray matter differ in the spinal cord compared to the cerebrum?
The formation of the blood-brain barrier is stimulated by which glial cells?
_____ are folds that increase surface.
By increasing surface area, they allow for more ___________.

3. Initiation of Nerve Impulses
Resting Membrane Potential
ICF relative to ECF – electrical potential
Polarized
Requires use of ATP
Created by Na+-K+ pumps
ECF
ICF
Na+
channel K+
Na+ 145 mEq/L
K mEq/L
Na mEq/L
K mEq/L
Large anions
that cannot
escape cell

4. Initiation of Nerve Impulses
Action Potentials
Na+ gate opens; K+ gate begins to open; depolarization begins
Na+ gate closes; K+ gate opens fully; repolarization begins
Both Na+ gate and K+ gate closed; repolarization complete.

5. Initiation of Nerve Impulses
Types of gated channels:
Chemical gated channel
Voltage gated channel
Extracellular fluid
Plasma
membrane
Cytosol
Gated
channel
(closed)
Resting state
Arrival of ACh
Binding
site
Gated channel opens
ACh
Channel inactivated
Channel closed
Channel open
Inactivation
gate
Activation

6. Initiation of Nerve Impulses
Notes
Threshold –
Depolarization –
Refractory period –
Action Potentials –
follow an All or Nothing Law
are nondecremantal
are irreversible
Resting
potential
Graded
Presynaptic neuron
stimulus
produces
may
produce
Action potential
Postsynaptic cell
triggers
Information
processing
Synaptic activity

7. Conduction of Nerve Impulses
Notes
Unmyelinated fibers – continuous propagation
Myelinated fibers – ions exchanged only at nodes of Ranvier
Saltatory propagation
+ +
– –
(a)
(b)
Na+inflow at node
generates action potential
(slow but nondecremental)
Na+ diffuses along inside
of axolemma to next node
(fast but decremental)
Excitation of voltage-
regulated gates will
generate next action
potential here
Action potential
in progress
Refractory
membrane
Excitable

8. Synaptic Transmission Chemical Synapse Structure
Synaptic knob
Synaptic vesicles
Synaptic cleft
20-40nm gap
Neurotransmitter receptors

9. Synaptic Transmission
Synaptic delay (0.5 msec)
Classes of Neurotransmitters
Excitatory, inhibitory, neuromuscular junction
3 kinds of synapses:
Excitatory cholinergic synapse = ACh
Inhibitory GABA-ergic synapse = GABA
Excitatory adrenergic synapse = NE

10. Excitatory Cholinergic Synapse
Mitochondrion
Acetylcholine
Synaptic
vesicle
SYNAPTIC
KNOB
CLEFT
POSTSYNAPTIC
MEMBRANE
Choline
Acetate
Acetylcholinesterase
(AChE)
ACh
receptor
CoA
Acetyl-CoA
Nerve signal opens
voltage-gated calcium
channels in synaptic knob
Ca+ triggers release of
neurotransmitter.
ACh binds to sodium
channel receptors
producing a graded
depolarization.
ACh is broken down
into acetate and choline
by AChE.
Choline is reabsorbed
and used to synthesize
new molecules of ACh. 1 2 3 4 5

11. Inhibitory GABA-ergic Synapse
Nerve signal triggers release of neurotransmitters
Receptors trigger opening of Cl- channels
Postsynaptic neuron now less likely to reach threshold

12. Excitatory Adrenergic Synapse
Acts through 2nd messenger systems (cAMP)
cAMP has multiple effects
binds to ion gate inside of membrane
turn metabolic pathways on/off
induces genetic transcription
Its advantage is enzymatic amplification
Presynaptic neuron
Postsynaptic neuron
Neurotransmitter
receptor
Norepinephrine
Adenylate cyclase
G protein – – – + + + 1 2 3
Ligand-
regulated
gates
opened 5
ATP
Na+
cAMP 4
Postsynaptic
potential
Multiple
possible
effects
Enzyme activation 6 7
Metabolic
changes
Genetic transcription
Enzyme synthesis

13. Cessation of the Signal
Stop signal in presynaptic neuron
Mechanisms to “turn off” the signal
diffusion of neurotransmitter into ECF
synaptic knob reabsorbs neurotransmitters
degradation of neurotransmitters in synaptic cleft
Acetylcholinesterase
Adrenalate cyclase

14. Postsynaptic Potentials
Excitatory postsynaptic potentials (EPSP)
a positive voltage change = more likely to fire
Inhibitory postsynaptic potentials (IPSP)
a negative voltage change = less likely to fire
Summation – net postsynaptic potentials
Temporal Summation
Initial
segment
Threshold
reached
ACTION
POTENTIAL
PROPAGATION
FIRST
STIMULUS
SECOND
Spatial Summation
TWO
SIMULTANEOUS
STIMULI
ACTION
POTENTIAL
PROPAGATION
Threshold
reached

15. Peripheral Nervous System
Consists of spinal and cranial nerves
Sensory (afferent) Division
Somatic Sensory Division
Visceral Sensory Division
Motor (efferent) Division
Somatic Motor Division
Visceral Motor Division (Autonomic Nervous System)
Sympathetic Division
Parasympathetic Division
Enteric Division

16. Motor Division Autonomic vs. Somatic Reflex Arcs
1. ANS = 2 neurons from CNS to effectors
preganglionic neuron - cell body in CNS
postganglionic neuron - cell body in peripheral ganglion

17. Motor Division Autonomic vs. Somatic Reflex Arcs
2. Autonomic effectors function in absence of stimulation
3. Autonomic stimulation can be excitatory or inhibitory
4. Autonomic control is usually involuntary
5. Autonomic effectors are smooth and cardiac muscle, glands
6. Autonomic integrative center in hypothalamus

18. Autonomic Nervous System Sympathetic Division
Origin in thoracolumbar region
Short preganglionic fibers, long postganglionic fibers
Synapses at paravertebral ganglia
17 postganglionic neurons for every preganglionic neuron
Mass activation
“Fight or Flight”
Associated with adrenal glands
Stimulate the release of neurotransmitters

19. Sympathetic Efferent Pathways
PONS
Eye
Salivary
glands
Heart
Lung
Liver and
gallbladder
Stomach
Spleen
Pancreas
Large
intestine
Small
Adrenal
medulla
Kidney
Urinary bladder
Scrotum
Penis
Uterus
Ovary
Inferior
mesenteric
ganglion
Superior mesenteric
Celiac ganglion
Cardiac and
pulmonary plexuses T1 L2
Spinal
cord
Postganglionic fibers to
spinal nerves (innervating
skin, blood vessels, sweat
glands, arrector pili
muscles, adipose tissue)
Sympathetic
chain ganglia
Preganglionic neurons
KEY
Post-Ganglionic neurons
Sympathetic Efferent Pathways

20. Autonomic Nervous System Parasympathetic Division
Origin in craniosacral region
Long preganglionic fibers, short postganglionic fibers
Synapses at terminal ganglion
2 postganglionic neurons for every preganglionic neuron
Specific and local effects
“Rest and Digest”

21. Parasympathetic Efferent Pathways
Spinal
cord S2 S3 S4
Uterus
Ovary
Penis
Scrotum
Liver and
gallbladder
Stomach
Spleen
Pancreas
Large
intestine
Small
Kidney
Urinary bladder
Rectum
Eye
Salivary glands
Heart
Lungs
Hypogastric
plexus
Inferior mesenteric
Celiac plexus
Cardiac plexus
Vagus nerve (X),
which provides
about 75% of all
parasympathetic
outflow
PONS
Otic ganglion
Submandibular
ganglion
Ciliary ganglion
Pterygopalatine ganglion
III
VII IX
Lacrimal gland
Preganglionic neurons
KEY
Ganglionic neurons

22. Innervation Dual Innervation Antagonistic Effect Cooperative Effects
Brain
Dual Innervation
Antagonistic Effect
Cooperative Effects
Parasympathetic fibers
of oculomotor nerve (III)
Sympathetic
fibers
Superior
cervical
ganglion
Ciliary
ganglion
Spinal cord
Cholinergic stimulation
of pupillary constrictor
Iris
Adrenergic
stimulation of
pupillary dilator
Pupil
Sympathetic
(adrenergic) effect
Parasympathetic
(cholinergic) effect
Pupil dilated
Pupil constricted

23. Innervation Control without dual innervation
Some targets receive only sympathetic fibers
Sympathetic tone
Artery 1
Sympathetic
nerve fiber 1
Strong
sympathetic
tone 2 2
Smooth muscle
contraction 3
Vasomotor
tone 3
Vasoconstriction
(a) Vasoconstriction 1 1
Weaker
sympathetic
tone 2 2
Smooth muscle
relaxation 3 3
Vasodilation
(b) Vasodilation