Neuromuscular Fundamentals
Download
Report
Transcript Neuromuscular Fundamentals
Neuromuscular
Fundamentals
Anatomy and Physiology of
Human Movement
420:050
1
Outline
Introduction
Structure and Function
Fiber Arrangement
Muscle Actions
Role of Muscles
Neural Control
Factors that Affect Muscle Tension
2
Introduction
Responsible for movement of body and all of its
joints
Muscles also provide
Protection
Posture and support
Produce a major portion of total body heat
Over 600 skeletal muscles comprise approximately
40 to 50% of body weight
215 pairs of skeletal muscles usually work in
cooperation with each other to perform opposite
actions at the joints which they cross
Aggregate muscle action - muscles work in groups
rather than independently to achieve a given joint
motion
3
Muscle Tissue Properties
Irritability or Excitability - property of muscle being
sensitive or responsive to chemical, electrical, or
mechanical stimuli
Contractility - ability of muscle to contract & develop
tension or internal force against resistance when
stimulated
Extensibility - ability of muscle to be passively
stretched beyond it normal resting length
Elasticity - ability of muscle to return to its original
length following stretching
4
Outline
Introduction
Structure and Function
Fiber Arrangement
Muscle Actions
Role of Muscles
Neural Control
Factors that Affect Muscle Tension
5
Structure and Function
Nervous system structure
Muscular system structure
Neuromuscular function
6
7
Figure 14.1, Marieb & Mallett (2003). Human Anatomy. Benjamin
Cummings.
Nervous System Structure
Integration of information from millions of
sensory neurons action via motor neurons
Figure 12.1, Marieb & Mallett (2003). Human Anatomy. Benjamin
Cummings.
8
Nervous System Structure
Organization
Brain
Spinal cord
Nerves
Fascicles
Neurons
Figure 12.2, Marieb & Mallett (2003).
Human Anatomy. Benjamin Cummings.
Figure 12.7, Marieb & Mallett (2003). Human
Anatomy. Benjamin Cummings.
9
Nervous System Structure
Both sensory and motor neurons in nerves
10
Figure 12.11, Marieb & Mallett (2003). Human Anatomy. Benjamin
Cummings.
Nervous System Structure
The neuron: Functional unit of nervous tissue (brain,
spinal cord, nerves)
Dendrites: Receptor sites
Cell body: Integration
Axon: Transmission
Myelin sheath: Protection and speed
Nodes of Ranvier: Saltatory conduction
Terminal branches: Increased innervation
Axon terminals: Connection with muscular system
Synaptic vescicles: Delivery mechanism of “message”
Neurotransmitter: The message
11
Dendrites
Cell body
Axon
Myelin sheath
Node of Ranvier
Terminal ending
Terminal branch
Figure 12.4, Marieb & Mallett (2003). Human
12
Anatomy. Benjamin Cummings.
Figure 12.8, Marieb & Mallett (2003). Human Anatomy.
Benjamin Cummings.
Terminal ending
Synaptic vescicle
Neurotransmitter:
Acetylcholine (ACh)
13
Figure 12.19, Marieb & Mallett (2003). Human Anatomy.
Benjamin Cummings.
14
Structure and Function
Nervous system structure
Muscular system structure
Neuromuscular function
15
Classification of Muscle Tissue
Three types:
1. Smooth muscle
2. Cardiac muscle
3. Skeletal muscle
16
Skeletal Muscle: Properties
Extensibility: The ability to lengthen
Contractility: The ability to shorten
Elasticity: The ability to return to original
length
Irritability: The ability to receive and respond
to stimulus
17
Muscular System Structure
Organization:
Muscle (epimyseum)
Fascicle (perimyseum)
Muscle fiber (endomyseum)
Myofibril
Myofilament
Actin and myosin
Other Significant Structures:
Sarcolemma
Transverse tubule
Sarcoplasmic reticulum
Tropomyosin
Troponin
18
19
Figure 10.1, Marieb & Mallett (2003). Human Anatomy. Benjamin Cummings.
Figure 10.4, Marieb & Mallett (2003). Human Anatomy. Benjamin Cummings.
20
21
http://staff.fcps.net/cverdecc/Adv%20A&P/Notes/Muscle%20Unit/sliding%20filament%20theory/slidin16.jpg
22
Figure 10.8, Marieb & Mallett (2003). Human Anatomy. Benjamin Cummings.
Structure and Function
Nervous system structure
Muscular system structure
Neuromuscular function
23
Neuromuscular Function
Basic Progression:
1. Nerve impulse
2. Neurotransmitter release
3. Action potential along sarcolemma
4. Calcium release
5. Coupling of actin and myosin
6. Sliding filaments
24
Nerve Impulse
What is a nerve impulse?
-Transmitted electrical charge
-Excites or inhibits an action
-An impulse that travels along an axon is an
ACTION POTENTIAL
25
Nerve Impulse
How does a neuron send an impulse?
-Adequate stimulus from dendrite
-Depolarization of the resting membrane potential
-Repolarization of the resting membrane potential
-Propagation
26
Nerve Impulse
What is the resting membrane potential?
-Difference in charge between inside/outside of the
neuron
-70 mV
27
Figure 12.9, Marieb & Mallett (2003). Human Anatomy. Benjamin Cummings.
Nerve Impulse
What is depolarization?
-Reversal of the RMP from –70 mV to +30mV
Propagation of the
action potential
28
Figure 12.9, Marieb & Mallett (2003). Human Anatomy. Benjamin Cummings.
Nerve Impulse
What is repolarization?
-Return of the RMP to –70 mV
29
Figure 12.9, Marieb & Mallett (2003). Human Anatomy. Benjamin Cummings.
+30 mV
-70 mV
30
Neuromuscular Function
Basic Progression:
1. Nerve impulse
2. Neurotransmitter release
3. Action potential along sarcolemma
4. Calcium release
5. Coupling of actin and myosin
6. Sliding filaments
31
Release of the
Neurotransmitter
Action potential axon terminals
1. Calcium uptake
2. Release of synaptic vescicles (ACh)
3. Vescicles release ACh
4. ACh binds sarcolemma
32
Figure 12.8, Marieb & Mallett (2003). Human Anatomy. Benjamin Cummings.
Ca2+
ACh
33
Figure 14.5, Marieb & Mallett (2003). Human Anatomy. Benjamin Cummings.
34
Neuromuscular Function
1. Nerve impulse
2. Neurotransmitter release
3. Action potential along sarcolemma
4. Calcium release
5. Coupling of actin and myosin
6. Sliding filaments
35
Ach
36
AP Along the Sarcolemma
Action potential Transverse tubules
1. T-tubules carry AP inside
2. AP activates sarcoplasmic reticulum
37
38
Figure 14.5, Marieb & Mallett (2003). Human Anatomy. Benjamin Cummings.
Neuromuscular Function
1. Nerve impulse
2. Neurotransmitter release
3. Action potential along sarcolemma
4. Calcium release
5. Coupling of actin and myosin
6. Sliding Filaments
39
Calcium Release
AP T-tubules Sarcoplasmic reticulum
1. Activation of SR
2. Calcium released into sarcoplasm
40
CALCIUM
RELEASE
Sarcolemma
41
Neuromuscular Function
1. Nerve impulse
2. Neurotransmitter release
3. Action potential along sarcolemma
4. Calcium release
5. Coupling of actin and myosin
6. Sliding filaments
42
Coupling of Actin and Myosin
Tropomyosin
Troponin
43
Blocked
Coupling of actin and myosin
44
Neuromuscular Function
1. Nerve impulse
2. Neurotransmitter release
3. Action potential along sarcolemma
4. Calcium release
5. Coupling of actin and myosin
6. Sliding filaments
45
Sliding Filament Theory
Basic Progression of Events
1. Cross-bridge
2. Power stroke
3. Dissociation
4. Reactivation of myosin
46
Cross-Bridge
Activation of myosin via ATP
-ATP ADP + Pi + Energy
-Activation “cocked” position
47
Power Stroke
ADP + Pi are released
Configurational change
Actin and myosin slide
48
Dissociation
New ATP binds to myosin
Dissociation occurs
49
Reactivation of Myosin Head
ATP ADP + Pi + Energy
Reactivates the myosin head
Process starts over
Process continues until:
-Nerve impulse stops
-AP stops
-Calcium pumped back into SR
-Tropomyosin/troponin back to original position
50
51
Outline
Introduction
Structure and Function
Fiber Arrangement
Muscle Actions
Role of Muscles
Neural Control
Factors that Affect Muscle Tension
52
Shape of Muscles & Fiber
Arrangement
Muscles have different shapes & fiber
arrangements
Shape & fiber arrangement affects
Muscle’s ability to exert force
Range through which it can effectively exert force
onto the bones
53
Shape of Muscles & Fiber
Arrangement
Two major types of fiber arrangements
Parallel & pennate
Each is further subdivided according to shape
54
Fiber Arrangement - Parallel
Parallel muscles
fibers arranged parallel to length of
muscle
produce a greater range of movement
than similar sized muscles with pennate
arrangement
Categorized into following shapes:
Flat
Fusiform
Strap
Radiate
Sphincter or circular
55
Fiber Arrangement - Parallel
Flat muscles
Usually thin & broad, originating from broad, fibrous,
sheet-like aponeuroses
Allows them to spread their forces over a broad area
Ex: Rectus abdominus & external oblique
Modified from Van De Graaff KM: Human
anatomy, ed 6, Dubuque, IA, 2002, McGraw-Hill.
56
Fiber Arrangement - Parallel
Fusiform muscles
Spindle-shaped with a central belly
that tapers to tendons on each end
Allows them to focus their power onto
small, bony targets
Ex: Brachialis, biceps brachii
57
Figure 3.3. Hamilton, Weimar & Luttgens (2005). Kinesiology:
Scientific basis for human motion. McGraw-Hill.
Fiber Arrangement - Parallel
Strap muscles
More uniform in diameter
with essentially all fibers
arranged in a long
parallel manner
Enables a focusing of
power onto small, bony
targets
Ex: Sartorius,
sternocleidomastoid
58
Figure 8.7. Hamilton, Weimar & Luttgens (2005). Kinesiology:
Scientific basis for human motion. McGraw-Hill.
Fiber Arrangement - Parallel
Radiate muscles
Also described sometimes as being triangular, fanshaped or convergent
Have combined arrangement of flat & fusiform
Originate on broad aponeuroses & converge onto a
tendon
Ex: Pectoralis major, trapezius
Modified from Van De Graaff KM: Human
anatomy, ed 6, Dubuque, IA, 2002, McGraw-Hill.
59
Fiber Arrangement - Parallel
Sphincter or circular muscles
Technically endless strap muscles
Surround openings & function to close them upon
contraction
Ex: Orbicularis oris surrounding the mouth
Modified from Van De Graaff KM: Human
anatomy, ed 6, Dubuque, IA, 2002, McGraw-Hill.
60
Fiber Arrangement - Pennate
Pennate muscles
Have shorter fibers
Arranged obliquely to their tendons in a manner
similar to a feather
Reduces mechanical efficiency of each fiber
Increases overall number of fibers “packed” into
muscle
Overall effect = more crossbridges = more force!
61
Fiber Arrangement - Pennate
Categorized based upon the exact
arrangement between fibers & tendon
Unipennate
Bipennate
Multipennate
Modified from Van De Graaff KM: Human anatomy, ed
6, Dubuque, IA, 2002, McGraw-Hill.
62
Fiber Arrangement - Pennate
Unipennate muscles
Fibers run obliquely from a tendon on
one side only
Ex: Biceps femoris, extensor digitorum
longus, tibialis posterior
63
Fiber Arrangement - Pennate
Bipennate muscle
Fibers run obliquely on both sides from
a central tendon
Ex: Rectus femoris, flexor hallucis
longus
64
Fiber Arrangement - Pennate
Multipennate muscles
Have several tendons with fibers running
diagonally between them
Ex: Deltoid
Bipennate & unipennate produce more
force than multipennate
65
Outline
Introduction
Structure and Function
Fiber Arrangement
Muscle Actions
Role of Muscles
Neural Control
Factors that Affect Muscle Tension
66
Muscle Actions: Terminology
Origin (Proximal Attachment):
Structurally, the proximal attachment of a muscle
or the part that attaches closest to the midline or
center of the body
Functionally & historically, the least movable part
or attachment of the muscle
Note: The least movable may not necessarily be
the proximal attachment
67
Muscle Actions: Terminology
Insertion (Distal Attachment):
Structurally, the distal attachment or the part that
attaches farthest from the midline or center of the
body
Functionally & historically, the most movable part
is generally considered the insertion
68
Muscle Actions: Terminology
When a particular muscle is activated
It tends to pull both ends toward the center
Actual movement is towards more stable
attachment
Examples:
Bicep curl vs. chin-up
Hip extension vs. RDL
69
Muscle Actions
Action - when tension is developed in a
muscle as a result of a stimulus
Muscle “contraction” term is exclusive in
nature
As a result, it has become increasingly
common to refer to the various types of
muscle contractions as muscle actions
instead
70
Muscle Actions
Muscle actions can be used to cause,
control, or prevent joint movement or
To initiate or accelerate movement of a body
segment
To slow down or decelerate movement of a body
segment
To prevent movement of a body segment by
external forces
71
Types of Muscle Actions
Muscle action (under tension)
Isometric
Isotonic
Concentric
Eccentric
72
Types of Muscle Actions
Isometric action:
Tension is developed within
muscle but joint angles remain
constant
AKA – Static movement
May be used to prevent a
body segment from being
moved by external forces
Internal torque = external
torque
73
Types of Muscle Actions
Isotonic (same tension) contractions involve
muscle developing tension to either cause or
control joint movement
AKA – Dynamic movement
Isotonic contractions are either concentric
(shortening) or eccentric (lengthening)
74
Types of Muscle Actions
Concentric contractions involve muscle developing
tension as it shortens
Internal torque > external torque
Causes movement against gravity or other resistance
Described as being a positive action
Eccentric contractions involve the muscle
lengthening under tension
External torque > internal torque
Controls movement caused by gravity or other resistance
Described as being a negative action
75
What is the role of the elbow extensors in
each phase?
76
Modified from Shier D, Butler J, Lewis R: Hole’s human anatomy
& physiology, ed 9, Dubuque, IA, 2002, McGraw-Hill
Types of Muscle Actions
Movement may occur at any given joint
without any muscle contraction whatsoever
referred to as passive
solely due to external forces such as those
applied by another person, object, or resistance
or the force of gravity in the presence of muscle
relaxation
77
Outline
Introduction
Structure and Function
Fiber Arrangement
Muscle Actions
Role of Muscles
Neural Control
Factors that Affect Muscle Tension
78
Role of Muscles
Agonist muscles
The activated muscle group during concentric or
eccentric phases of movement
Known as primary or prime movers, or muscles
most involved
79
Role of Muscles
Antagonist muscles
Located on opposite side of joint from agonist
Have the opposite concentric action
Also known as contralateral muscles
Work in cooperation with agonist muscles by
relaxing & allowing movement
Reciprocal Inhibition
80
81
Role of Muscles
Stabilizers
Surround joint or body part
Contract to fixate or stabilize the area to enable
another limb or body segment to exert force &
move
Also known as fixators
82
Role of Muscles
Synergist
Assist in action of agonists
Not necessarily prime movers for the action
Also known as guiding muscles
Assist in refined movement & rule out undesired
motions
83
Role of Muscles
Neutralizers
Counteract or neutralize the action of another
muscle to prevent undesirable movements such
as inappropriate muscle substitutions
Activation to resist specific actions of other
muscles
84
Outline
Introduction
Structure and Function
Fiber Arrangement
Muscle Actions
Role of Muscles
Neural Control
Factors that Affect Muscle Tension
85
Factors That Affect Muscle
Tension
Number Coding and Rate Coding
Length-Tension Relationship
Force-Velocity Relationship
Uniarticular vs. Biarticular Muscles
Cross-sectional Diameter
Muscle Fiber Type
86
Number Coding & Rate Coding
Difference between lifting a minimal vs. maximal
resistance is the number of muscle fibers
recruited (crossbridges)
The number of muscle fibers recruited may be
increased by
Activating those motor units containing a greater
number of muscle fibers (Number Coding)
Activating more motor units (Number Coding)
Increasing the frequency of motor unit activation (Rate
Coding)
87
Number Coding & Rate Coding
Number of muscle fibers per motor unit
varies significantly
From less than 10 in muscles requiring precise
and detailed such as muscles of the eye
To as many as a few thousand in large
muscles that perform less complex activities
such as the quadriceps and gastrocnemius
88
Number Coding & Rate Coding
Greater contraction forces may also be
achieved by increasing the frequency or
motor unit activation (Rate Coding)
89
All or None Principle
Motor unit
Typical muscle contraction
Single motor neuron & all muscle fibers it innervates
The number of motor units responding (and number of
muscle fibers contracting) within the muscle may vary
significantly from relatively few to virtually all
All of the fibers within the motor unit will fire when
stimulated by the CNS
All or None Principle - regardless of number,
individual muscle fibers within a given motor unit
will either fire & contract maximally or not at all
90
Factors That Affect Muscle
Tension
Number Coding and Rate Coding
Length-Tension Relationship
Force-Velocity Relationship
Uniarticular vs. Biarticular Muscles
Cross-sectional Diameter
Muscle Fiber Type
91
Length - Tension Relationship
Maximal ability of a muscle to develop
tension & exert force varies depending
upon the length of the muscle during
contraction
Passive Tension
Active Tension
92
93
Figure 20.2, Plowman and Smith (2002). Exercise Physiology, Benjamin
Cummings.
Factors That Affect Muscle
Tension
Number Coding and Rate Coding
Length-Tension Relationship
Force-Velocity Relationship
Uniarticular vs. Biarticular Muscles
Cross-sectional Diameter
Muscle Fiber Type
94
Force – Velocity Relationship
When muscle is contracting (concentrically or
eccentrically) the rate of length change is
significantly related to the amount of force potential
95
Force – Velocity Relationship
Maximum concentric velocity = minimum
resistance
As load increases, concentric velocity
decreases
Eventually velocity = 0 (isometric action)
96
Force – Velocity Relationship
As load increases beyond muscle’s ability
to maintain an isometric contraction, the
muscle begins eccentric action
As load increases, eccentric velocity
increases
Eventually velocity = maximum when
muscle tension fails
97
Muscle Force – Velocity
Relationship
Indirect relationship between force (load)
and concentric velocity
Direct relationship between force (load)
and eccentric velocity
98
Factors That Affect Muscle
Tension
Number Coding and Rate Coding
Length-Tension Relationship
Force-Velocity Relationship
Uniarticular vs. Biarticular Muscles
Cross-sectional Diameter
Muscle Fiber Type
99
Uni Vs. Biarticular Muscles
Uniarticular muscles
Cross & act directly only on the single joint that
they cross
Ex: Brachialis
Can only pull humerus & ulna closer
together
Ex: Gluteus Maximus
Can only pull posterior femur and pelvis
closer together
100
Uni Vs. Biarticular Muscles
Biarticular muscles
Cross & act on two different joints
May contract & cause motion at either one or
both of its joints
Advantages over uniarticular muscles
101
Advantage #1
Can cause and/or control motion at more
than one joint
Rectus femoris: Knee extension, hip flexion
Hamstrings: Knee flexion, hip extension
102
Advantage #2
Can maintain a relatively constant length
due to "shortening" at one joint and
"lengthening" at another joint (Quasiisometric)
- Recall the Length-Tension Relationship
103
Advantage #3
Prevention of Reciprocal Inhibition
This effect is negated with biarticular
muscles when they move concurrently
Concurrent movement:
Concurrent “lengthening” and “shortening” of
muscle
Countercurrent movement:
Both ends “lengthen” or “shorten”
104
What if the muscles of the
hip/knee were uniarticular?
Hip
Knee
Ankle
Muscles stretched/shortened to
105
extreme lengths! Implication?
106
Figure 20.2, Plowman and Smith (2002). Exercise Physiology, Benjamin
Cummings.
Quasi-isometric action?
Implication?
Hip
Knee
Ankle
107
Active & Passive Insufficiency
Countercurrent muscle actions can reduce the
effectiveness of the muscle
As muscle shortens its ability to exert force
diminishes
Active insufficiency: Diminished crossbridges
As muscle lengthens its ability to move through
ROM or generate tension diminishes
Passively insufficiency: Diminished crossbridges and
excessive passive tension
108
Factors That Affect Muscle
Tension
Number Coding and Rate Coding
Length-Tension Relationship
Force-Velocity Relationship
Uniarticular vs. Biarticular Muscles
Cross-sectional Diameter
Muscle Fiber Type
109
Cross-Sectional Area
Hypertrophy vs. hyperplasia
Increased # of myofilaments
Increased size and # of myofibrils
Increased size of muscle fibers
110
http://estb.msn.com/i/6B/917B20A6BE353420124115B1A511C7.jpg
Factors That Affect Muscle
Tension
Number Coding and Rate Coding
Length-Tension Relationship
Force-Velocity Relationship
Uniarticular vs. Biarticular Muscles
Cross-sectional Diameter
Muscle Fiber Type
111
Muscle Fiber Characteristics
Three basic types:
1. Type I:
-Slow twitch, oxidative, red
2. Type IIb:
-Fast twitch, glycolytic, white
3. Type IIa:
-FOG
112