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The Role of the Nervous System

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Title: The Role of the Nervous System


1
The Role of the Nervous System
  • Applied Kinesiology
  • 420151

2
Agenda
  • Introduction to the nervous system
  • Structural considerations
  • Motor efferents and gradations of force
  • Sensory afferents
  • Reflex movement

3
Introduction to the NS
  • Functions
  • Sensory input ? afferent neurons
  • Integration
  • Motor output ? efferent neurons
  • Properties
  • Irritability
  • Conductivity

4
Introduction to NS
  • Levels of Control
  • Cerebral cortex
  • Consciousness
  • Basal ganglia
  • Homeostasis ? posture and equilibrium
  • Cerebellum
  • Timing and intensity ? smooth and precise motion
  • Brain stem
  • Arousal and cardiorespiratory function
  • Spinal cord
  • Link b/w CNS and PNS ? interneurons and synapses

5
Cerebral cortex
Basal ganglia
Cerebellum
Brain stem
Spinal cord
Overide?
Figure 4.14, Hamilton
6
Introduction to the NS
  • Basic divisions of the nervous system

7
Figure 14.1, Marieb Mallett (2003)
8
Agenda
  • Introduction to the nervous system
  • Structural considerations
  • Motor efferents and gradations of force
  • Sensory afferents
  • Reflex movement

9
Structural Considerations
  • The neuron
  • The nerve
  • The synapse
  • The motor unit

10
The Neuron
  • Functional unit of nervous tissue
  • Three main types of neurons
  • Sensory/afferent neurons
  • Motor/efferent neurons
  • Interneurons
  • Common structures

11
Figure 12.11, Marieb Mallett (2003)
Dendrites
Cell Body
Axon
Differences Peripheral body, location of
dendrites/synaptic knobs, direction of
transmission
12
The Neuron
  • Other considerations
  • Cell body
  • Nucleus
  • Almost all cell bodies are in spinal cord
    (ganglia?)
  • Dendrites
  • Afferents ? cell body via peripheral body
  • Efferents ? cell body via axon
  • Axon
  • Myelin sheath
  • Axon collaterals
  • Extensive terminal branching (10,000)
  • Synaptic knobs

13
Figure 12.4, Marieb Mallett (2003)
14
(No Transcript)
15
Structural Considerations
  • The neuron
  • The nerve
  • The synapse
  • The motor unit

16
The Nerve
  • Nerve bundle of neurons
  • Not unlike skeletal muscle architecture

Figure 12.17, Marieb Mallett (2003)
17
The Nerve
  • Nerves can contain both afferent and efferent
    neurons.
  • Spinal/peripheral nerves connect to the spinal
    cord via
  • Anterior root (motor efferent neurons)
  • Posterior root (sensory afferent neurons)

18
Posterior root
Anterior root
19
The Nerve
  • Thirty one pairs of spinal/peripheral nerves
  • Cervical ? 8
  • Thoracic ? 12
  • Lumbar ? 5
  • Sacral ? 5
  • Coccygeal ?1

Figure 13.29, Marieb Mallett (2003)
20
Structural Considerations
  • The neuron
  • The nerve
  • The synapse
  • The motor unit

21
The Synapse
Figure 12.7, Marieb Mallett (2003)
  • Synapse Area between the synaptic knob of one
    neuron and the membrane of another neuron

22
Neurons have thousands of synaptic knobs
Some neurons are excitatory, some inhibitory
Competition between excitation and inhibition
occurs ? Threshold stimulus reached?
NMJ or motor end plate
Neurotransmitter
Figure 12.8, Marieb Mallett (2003)
23
Excitatory and Inhibitory Postsynaptic
Potentials EPSP, IPSP
EPSP - IPSP Stimulus
Stimulus gt Threshold Excitation of
impulse Stimulus lt Threshold Inhibition of
impulse
Impulse itself can be excitatory or inhibitory in
nature
24
Structural Considerations
  • The neuron
  • The nerve
  • The synapse
  • The motor unit

25
The Motor Unit
  • Functional unit of neuromuscular system
  • Consists of
  • Neuron all muscle fibers
  • Eye muscles vs. gastrocnemius (10-2000)
  • Fewer fibers/neuron precision
  • More fibers/neuron force

26
Figure 14.6, Marieb Mallett (2003)
27
Agenda
  • Introduction to the nervous system
  • Structural considerations
  • Motor efferents and gradations of force
  • Sensory afferents
  • Reflex movement

28
Efferents Gradations of Force
  • Motor efferent Sends signal away from the CNS
    (skeletal muscle)
  • Dendrites in spinal cord
  • Synaptic knobs ? muscle
  • Excitatory or inhibitory
  • Gradation of force
  • Concept Muscles are able to activate with
    varying degrees of force

29
Efferents Gradations of Force
  • Two factors influence the gradation of force
  • Number coding The number of motor units
    participating
  • Rate coding The frequency of stimulation

30
Number Coding
  • All-or-none principle of single motor units ?
    threshold
  • Gradation of force
  • Small force fewer motor units or motor units
    with less fibers
  • Large force more motor units or motor units
    with more fibers
  • Orderly sequence ? Size principle

31
Resting muscle tonus achieved via alternating
activation of some muscle fibers
Figure 19.13, Plowman Smith (2003)
32
Rate Coding
  • Effects of different stimulus frequencies on
    motor units
  • Single stimulus ? twitch
  • Second stimulus added prior to full relaxation ?
    temporal summation
  • Multiple stimuli added so that any relaxation is
    prohibited ? irregular and fused tetanus

33
Maximum number coding maximum rate coding
maximum force
As frequency increases, force/tension increases
34
Agenda
  • Introduction to the nervous system
  • Structural considerations
  • Motor efferents and gradations of force
  • Sensory afferents
  • Reflex movement

35
Sensory Afferents
  • Sensory afferents Sends signal towards the CNS
  • Dendrites are all over body (not in CNS)
  • Synaptic knobs are in spinal cord
  • Classifications of afferents
  • Exteroceptors
  • Interoceptors (visceroceptors)
  • Proprioceptors

36
Figure 14.1, Marieb Mallett (2003)
Proprioceptors are main concern
37
Proprioceptors
  • Location Tendons, skeletal muscle, ligaments,
    joint capsules and inner ear
  • Functions
  • Transmit movement information ? CNS
  • CNS integrates and initiates appropriate response
    (consciously/subconsciously)
  • Provide sense of body awareness
  • Provide stimulus for reflexes

38
Proprioceptor Classification
  • Muscle proprioceptors
  • Muscle spindles
  • Golgi tendon organs
  • Joint and skin proprioceptors
  • Ruffini endings
  • Pacinian corpuscles
  • Labyrinthine and neck proprioceptors
  • Labyrinthine proprioceptors
  • Neck proprioceptors

39
Muscle Proprioceptors Muscle Spindles
  • Location Lay between and parallel to muscle
    fibers
  • Structure
  • Tiny capsules (1 mm)
  • Filled with fluid and intrafusal muscle fibers
  • Nucleated and supplied with afferent neuron
  • Function
  • Sensitive to stretch and tension of skeletal
    muscle tissue
  • Transmit to CNS
  • Excitatory impulse ? agonist and synergists
  • Inhibitory impulse ? antagonists (reciprocal
    inhibition)

40
Figure 14.5, Knutzen Hamill (2004)
Stretch
Excitatory activation of agonists
Interneurons
Activation of synergists
Reciprocal inhibition of antagonists
41
Muscle Proprioceptors GTOs
  • Location Musculotendon junction of skeletal
    muscle
  • Structure
  • Mass of terminal endings in connective tissue
    capsule
  • Connections both with tendon and fibers
  • Function
  • Sensitive to tension in tendon due to both
    stretch and shortening of muscle
  • Transmit to CNS
  • Inhibitory impulse ? agonists and synergists
  • Excitatory impulse ? antagonists

42
1. High muscle tension
3. GTO activation
4. Inhibition of agonist
2. High tendon tension
43
Joint and Skin Proprioceptors Ruffini Endings
  • Location Beneath skin, joint capsules
  • Structure Spray of dendrites in flattened
    connective tissue capsule
  • Functions Sensitive to ?
  • Rapid changes in joint angle
  • Constant pressure resulting in deformation of
    capsule

44
Skin and Joint ProprioceptorsPacinian Corpuscles
  • Location Beneath skin, joint capsules, ligaments
    and tendons
  • Structure
  • Relatively large (naked eye)
  • Tip of single dendrite in connective tissue
    capsule
  • Function Sensitive to ?
  • Rapid changes in joint angle
  • Rapid, short-term changes in pressure resulting
    in deformation of capsule

45
Pacinian corpuscle
Ruffini endings
Free nerve endings
46
Labyrinthine Proprioceptors
  • Location Inner ear
  • Structure Several structures within the ear
  • Function
  • Detect orientation and movements of the head

47
Neck Proprioceptors
  • Location Ligaments of cervical vertebrae
  • Function
  • Head/neck movement ? transmit opposite signals
  • Prevents sense of imbalance

48
Agenda
  • Introduction to the nervous system
  • Structural considerations
  • Motor efferents and gradations of force
  • Sensory afferents
  • Reflex movement

49
Reflexes
  • Reflex Specific pattern response that occurs
    without volition
  • The reflex arc consists of
  • Receptor organ
  • Afferent neuron
  • Interneuron (sometimes)
  • Efferent neuron

50
Figure 12.18, Marieb Mallett (2003)
51
Classification of Reflexes
  • Exteroceptive reflexes Respond to external
    stimuli
  • Extensor thrust reflex
  • Flexor reflex
  • Crossed extensor reflex
  • Proprioceptive reflexes Response to internal
    stimuli
  • Stretch (myotatic) reflex
  • Tendon reflex
  • Righting reflex
  • Tonic neck reflex
  • Labyrinthine reflex

52
Exteroceptive Extensor Thrust Reflex
  • General mechanism Pressure stimulates pacinian
    corpuscles ? excitatory impulse to extensors
  • Examples
  • Standing
  • Shifting weight ? preparation for motion
  • Hands ? cartwheel or back handspring

53
Exteroceptive Flexor Reflex
  • General mechanism Typically in response to pain
    ? excitatory impulse to flexors
  • Examples
  • Pricking or burning hand

54
Exteroceptive Crossed Extensor Reflex
  • General mechanism Functions cooperatively with
    flexor reflex
  • Contralateral limb is extended
  • Examples
  • Stepping on tack
  • Pricking or burning hand

55
Proprioceptive Stretch Reflex
  • General mechanism Stretched muscle results in
    stretched muscle spindle ?
  • Excitatory impulse to agonist for protection
  • Inhibitory impulse to antagonists
  • Two types
  • Phasic Rapid stretching ? rapid powerful
    contraction that ends rapidly
  • Tonic Slow stretching ? smooth, less powerful
    contraction that lasts as long as the stretch

56
Elbow flexed 90 degrees while holding a bucket
1. Object dropped into bucket
2. Object dropped in from lesser height
3. Object placed into bucket
Figure 14.12, Hamilton
57
Explosive movements Long and rapid prep phases
(phasic stretch reflex)
Precise movements Short and slow prep phase
(tonic stretch reflex)
58
Proprioceptive Tendon Reflex
  • General mechanism Sensitive to tension in tendon
    due to
  • Muscle lengthening
  • Tendon reflex vs. stretch reflex
  • Muscle shortening
  • Very sensitive (low threshold)
  • Threshold stimulus ? inhibitory impulse to
    agonists
  • Extreme cases ? total relaxation
  • Training or extreme stress can increase the
    threshold

59
Proprioceptive Righting Reflex
  • General mechanism Body tilting ? thrusting of
    limbs to restore balance
  • Example
  • A gentle push with eyes shut

60
Proprioceptive Tonic Neck Reflex
  • General mechanism Head movement results in
    flexion or extension of limbs
  • Obvious in infants
  • Surpressed in adults ? evident under stress
  • Examples Symmetric vs. asymmetric
  • Neck flexion Upper extremities flex
  • Neck extension Upper extremities extend
  • Neck rotation
  • Extension/Abduction of contralateral arm
  • Flexion/abduction of ipsilateral arm.

61
Proprioceptive Labyrinthine Reflex
  • General mechanism Movements of the head ?
    activation of limbs to maintain balance
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