muscle contraction
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Dr. Niranjan Murthy H L
Asst. Prof., Dept. of Physiology
Sree Siddhartha Medical College & Hospital, Tumkur
THEORIES OF CONTRACTION
1) Viscoelastic (new elastic body theory) theory- 1840s to1920s- muscle acts like a stretched spring contained in a viscous medium.
2) Continuous filament theory- during contraction actin and myosin combine to form a single filament. This undergoes folding and shortening due to thermal agitation or loss of water molecules
3) Sliding filament theory
SLIDING FILAMENT THEORY
• 1954 by A.F.Huxley and H.E.Huxley independently
• Two overlapping sets of filaments sliding past each other.
• Thin filaments at each end of sarcomere move towards center between thick filaments.
• Globular heads of myosin form cross-bridges with actin monomers- cross-bridge theory
• Huxley (1969)- cross-bridges attach to thin filament pull towards center detach attach further down ratchet theory or walk-along theory
ATP attaches to myosin head
ATP split into ADP+Pi
Myosin head cocks up
Attaches to actin monomer
Head tilts towards arm
PowerstrokeActin is pulled
ADP & Pi released
ATP attaches to head
Head releases from actin
ATP is cleavedTo ADP & Pi
Head cocks up
EVENTS DURING MUSCLE CONTRACTION
1. Chemical changes
2. Mechanical changes
3. Thermal changes
4. Electrical changes
Chemical changes
• ATP attaches to myosin head splits to ADP+Pi myosin head cocks up attaches to actin power-stroke ADP & Pi discarded new ATP attaches to myosin head myosin head released from actin
• ATP yields 11.5kcal/mol
Sources of ATP1. ATP present in sarcoplasm- suffice for
1-2sec
2. Creatine phosphate- suffice for 5-8sec. Lohman’s reaction CP+ADP=Creatine+ATP
3. Glycolysis- suffice for 1min
4. Oxidation of cellular foodstuff- for longer periods
Mechanical changes
• Isotonic contraction- shortening of muscle but volume remains the same
• Isometric contraction- no change in the length
Thermal changes
1. Resting heat- A.V.HILL- 300cal/min in 70kg man with 30kg of skeletal muscles.
2. Activation heat- energy required for Ca2+ influx, binding to troponin & pumping out of Ca2+- 10cal/gm
3. Shortening heat- proportional to amount of shortening
4. Maintenance heat
5. Relaxation heat
6. Recovery heat- restitution of ATP and glycogen
Electrical changes
• RMP of -90mv
• AP moves along sarcolemma
• Velocity of AP conduction- 5m/sec
MOTOR UNIT
• Single nerve fiber with all the muscle fibers it supplies for a motor unit
• Motor units may contain 2 to few hundred muscle fibers
• Smaller motor units are associated with muscles of fine movements
WORKING MODEL
• Muscle consists of 3 components
1. Contractile element
2. Series elastic element- arms of cross-bridges, tendon fibers
3. Parallel elastic element- connective tissue
TYPES OF CONTRACTION
1. Isometric contraction- length remains same whereas tension increases. Eg: pushing the wall
2. Isotonic contraction- tension remains same whereas length changes. Eg: throwing a stone
LENGTH-TENSION RELATIONSHIP
Muscle length is held constant at various lengths.
Muscle directly stimulated at many points.Tension developed is measured using
transducer.Maximum tension at rest length.When muscle is stretched, passive tension
is developed due stretching of elastic elements
• Studied in single muscle fiber using optical diffraction patterns of laser.
• Tension developed is maximum at 2-2.2μ when there is optimum overlap of actin and myosin
• No tension when muscle is stretched so that there is no overlap of actin & myosin filaments
• With shorter lengths, tension reduces
FORCE-VELOCITY RELATIONSHIP
• Muscle is allowed to contract with various loads attached
• Isotonic contraction
• Initial latency is time for activation of contractile machinery
• Later part of latency is time taken to stretch the SEE
• As the load increases, velocity decreases
• Rigor mortis:-Seen after deathState of extreme rigidityDue to fixed interaction between actin &
myosin headsATP is needed to break actin-myosin
bondLoss of rigidity after few hours due to
proteolysis
Types of skeletal muscleRed muscle fiber White muscle fiber
Slow twitch period Fast twitch period
Extensive blood supply Lesser blood supply
Thinner fiber Thicker fiber
Plenty of mitochondriae Less mitochondria
Copious myoglobin Less myoglobin
Less glycogen and glycolytic enzymes
More glycogen & glycolytic & phosphorylase enzymes
Less ATPase activity Less ATPase activity
Sustained contraction Short bursts of activity
ELECTROMYOGRAPHY
• During a normal twitch, minute electrical potential is dissipated into surrounding. This can be picked up by surface electrodes on skin.
• All the motor units do not contract at same time- so the electrical potential is prolonged.
• Amplitude of 0.5mv & duration of 5-8ms
• Electromyograph is a high gain amplifier
• Skin electrodes or needle electrodes are used
• Motor unit potentials are displayed on CRO
• Potential is a sharp spike, usually biphasic
• Larger the motor-unit potential, larger the motor unit.
• Useful for distinguishing nerve from muscle disease
• EMGs are obtained at rest, during slight muscle contraction, and during maximal muscle activity
• Henneman principle
• Fibrillation- contraction of single muscle cells
• Fasciculation- contraction of groups of muscle cells supplied by a single axon
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