figure 14.17b
DESCRIPTION
Figure 14.17b. Table 14.5. Figure 14.18. Concept 14.4 Reflexes and SNS Reflex Arcs. Reflexes. somatic reflexes involve contraction of skeletal muscles autonomic reflexes not consciously perceived responses of smooth muscle, cardiac muscle, and glands reflex arc - PowerPoint PPT PresentationTRANSCRIPT
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Figure 14.17b
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Table 14.5
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Figure 14.18
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Concept 14.4 Reflexesand SNS Reflex Arcs
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Reflexes
somatic reflexes involve contraction of skeletal muscles
autonomic reflexes not consciously perceived responses of smooth muscle, cardiac muscle, and
glands reflex arc
pathway followed by nerve impulses that produce reflex
may be monosynaptic or polysynaptic
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Reflexes fast involuntary, unplanned sequence of
actions that occurs in response to a particular stimulus
some present from birth some are learned or acquired cranial reflex
integration occurs in brain spinal reflex
integration occurs in spinal cord SNS reflexes are always excitatory
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SNS Reflex Arc Components
1. sensory receptor• dendrite or associated sensory structure
2. sensory neuron• axon and axon terminals
3. integrating center• interneuron(s) that relay impulses
4. motor neuron• impulse triggered by integrating center
5. effector• body part that responds to impulse
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Stretch Reflexes Triggered by tapping on tendons attached to muscles
at elbow, wrist, knee, and ankle joints Monosynaptic
1. muscle spindles detect slight stretch
2. muscle spindle generates impulse(s) to sensory neuron to posterior root of spinal nerve
3. sensory neuron synapses with motor neuron in gray matter of spinal cord
4. strong enough impulse triggers AP of motor neuron
5. ACh at NMJ triggers contraction of skeletal muscle
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Figure 14.20
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Stretch Reflexes
Monosynaptic reflexes are called ipsilateral reflexes propagate into and out of the same side of
spinal cord reflex helps prevent injury by preventing
overstretching of muscles reciprocal innervation
polysynaptic reflex arc to antagonistic muscles operates at the same time
three neurons and two synapses
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Flexor Reflexes
Triggered by painful AKA withdrawal reflex Polysynaptic or intersegmental reflex arc
1. pain-sensitive sensory neuron stimulated2. impulse propagates into spinal cord3. sensory neuron activated interneuron and signal
sent to several segments4. several motor neurons activated and motor
impulse propagates toward several NMJs5. ACh released into synaptic cleft causes flexor
muscles to contract withdrawing body part from painful stimulus
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Figure 14.21
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Flexor Reflexes
reciprocal innervation occurs as in stretch reflex
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Concept 14.5 ANS Reflexes
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ANS versus SNSSNS produces voluntary movements in response to consciously perceived sensory input
ANS produces involuntary movements in
cardiac muscle smooth muscle glands
in response to unconscious sensory input
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ANS Reflex Arcs
regulates activity of smooth, cardiac muscle, and many glands
continual flow of nerve impulses from autonomic sensory neurons in visceral organs and blood vessels propagates into integrating centers of CNS
impulses in autonomic motor neurons propagate to various effector tissues
can excite or inhibit activities of effector tissues ANS activity is regulated by hypothalamus and brain stem of
CNS
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ANS Divisionssympathetic divisionparasympathetic division most organs have dual innervation by both
sympathetic and parasympathetic divisions transmit opposing nerve impulsesenteric division enteric plexuses
network of neurons that extend throughout GI tract walls
contain sensory neurons interneurons motor neurons
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Figure 14.22a
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Figure 14.22b
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Table 14.6
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Concept 14.6 Anatomy of the ANS
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Components of ANS
Preganglionic Neurons Autonomic Ganglia Postganglionic Neurons Effectors
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Preganglionic Neurons
cell body in CNS sympathetic division
in gray matter segments T1-T12, L1 and L2 parasympathetic division
in nuclei of four cranial nerves in brain stem in gray matter segments S2-S4
small-diameter myelinated fiber extends to an autonomic ganglion synapses with postganglionic neuron
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Figure 14.23
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Figure 14.24
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Ganglia Sympathetic ganglia
sympathetic trunk ganglia vertical row on either side of vertebral column
prevertebral ganglia celiac ganglion superior mesenteric ganglion inferior mesenteric ganglion
Parasympathetic ganglia terminal ganglia located close to or actually within wall of visceral organ longer than most axons of sympathetic preganglionic
neurons
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Figure 14.25
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Autonomic Plexuses
many lie along major arteries may contain sympathetic ganglia and axons of
autonomic sensory neurons often named after associated artery thoracic plexuses
cardiac plexus pulmonary plexus
abdominal and pelvic plexuses celiac plexus superior and inferior mesenteric plexus hypogastric plexus renal plexus
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Figure 14.25
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Postganglionic Neurons
Sympathetic neurons connect with postganglionic neurons by
synapse with first ganglion it reaches may ascent or descent to higher or lower
ganglion before synapsing with postganglionic neurons
without synapsing it may continue through sympathetic trunk ganglion
end at prevertebral ganglion synapse with postganglionic neurons there
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Figure 14.26
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Postganglionic NeuronsSympathetic effectors some preganglionic sympathetic axons directly innervate adrenal
medullae each has many axon collaterals single sympathetic preganglionic fiber may synapse with 20 or
more postganglionic neurons example of divergence explains why responses affect almost entire body
simultaneouslyParasympathetic effectors preganglionic neurons pass to terminal ganglia near or within a
visceral effector can be localized to single effector
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Concept 14.7 ANS Signal Transmission
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ANS Signal Transmission
Classification based on neurotransmitter released Cholinergenic neurons
release acetylcholine Adrenergenic neurons
release norepinephrine
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Cholinergenic neurons
release acetylcholine preganglionic
both sympathetic and parasympathetic sympathetic postganglionic that innervate most sweat glands all parasympathetic postganglionic neurons
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Adrenergenic neurons
release norepinephrine most sympathetic postganglionic neurons
receptors bind both neurotransmitter norepinephrine and hormone epinephrine four classifications
alpha 1, alpha 2, beta 1, and beta 2 alpha 1 and beta 1 are generally excitatory receptors alpha 2 and beta 2 are generally inhibitory receptors
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Figure 14.27a
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Figure 14.27b
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Figure 14.27c
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Table 14.7
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Concept 14.8 Sympathetic and Parasympathetic Responses
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Sympathetic dominates during extreme physical or emotional stress favors activities that can support high production of ATP and high
physical activity fight or flight response
1. pupil dilation
2. increased heart function
3. dilation of airways
4. reduced blood flow to viscera
5. increased blood flow to heart, skeletal muscles, liver and adipose tissue
6. increased glycogen and fatty acid breakdown
7. release of glucose from liver
8. inhibition of processes not essential for emergency response
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Parasympathetic
enhances rest and digest activities favors activities that can support body functions that conserve and
restore energy during times of rest and recovery SLUDD
salivation lacrimation urination digestion defecation
three decreases heart rate diameter of airways diameter of pupils
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Table 14.9 pt 1
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Table 14.9 pt 2
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Table 14.8
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Concept 14.9 ANS Reflex Arcs
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Autonomic Reflexes
Components:1. Receptor2. Sensory neuron3. Integrating center4. Motor Neuron5. Effector
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Hypothalamus control and integration center of ANS receives sensory input regarding
visceral function olfaction gustation blood, temperature, osmolarity, and substance
concentration emotions from limbic system
output via reticular formation to brain stem spinal cord
posterior and lateral control sympathetic activities anterior and medial control parasympathetic activities
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End Chapter 14