Muscle Response Lecture
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Transcript Muscle Response Lecture
Muscle Response
How do muscles respond to
stimuli as an organ?
Muscle Tension vs. Load
Muscle Tension: Force
exerted by a muscle on
an object.
Muscle Load: Opposite
of tension, force exerted
on the muscle by the
weight of the object
being moved
Isometric vs. Isotonic Contractions
Isometric Contraction:
Muscle tension = Muscle load
Load does not move
Isotonic Contraction: Load moves
Two Types
1. Concentric
Muscle tension > Muscle load
Muscle shortens
2. Eccentric
Muscle tension < Muscle load
Muscles lengthens
Motor Unit
A motor neuron and all of the muscle fibers it
innervates
Motor Twitch
Response of a motor unit to a single action
potential
All-or-nothing contractions, no partial
The time course of the action
potential is indicated in A
Longer development of tension
of the twitch contraction is
shown in B.
Wave Summation
describes response to successive action
potentials.
Frequency of stimuli increases
….so, muscle can’t fully relax between contractions
…and contraction force increases (wave
summation)
Twitches link together and fuse to become a
smooth contraction (tetanus)
Tetanus
No relaxation between action potentials
Allows for smooth, continuous contraction:
(important in maintaining posture, sitting/standing upright)
Degree of contraction/tetanus depends on:
Speed of stimulation
Number of muscle fibers activated. (recruitment)
100 to lift a pencil
1000’s to lift a barbell
Order of recruitment controlled by size of fibers: small
motor units first.
Treppe
A staircase pattern in strength of contraction.
Initial contractions weaker than response to
stimuli of same strength later
“Warm-up” period of muscles
Heat increases enzyme activity
Increases in Ca2+ availability in Sarcoplasmic
Reticulum
Muscle Tone
Constant action potentials in different motor
units causing muscle to maintain a slight
contraction.
Muscle firm, ready to respond.
Energy for Contractions
ATP
Little ATP stored in muscles.
4-6 seconds worth
Must be regenerated quickly.
Methods of regenerating ATP
Methods of regenerating ATP:
Creatine phosphate (for sudden, high demands of ATP)
CP stored in muscle
Directly makes ATP by phosphate transfer
Glycolysis (splitting of sugar, prior to CR)
Cellular Respiration (aerobic, mitochondrial)
Anaerobic respiration – w/o enough O2, pyruvic acid
made in glycolysis is converted into lactic acid:
to regenerate NAD for glycolysis to continue
some ATP can therefore be formed through
glycolysis.
Causes muscle soreness and fatigue
Sports Activities and Energy
Sports involving burst of power: tennis,
soccer, sprints, diving, volleyball
Rely on creatine phosphate and ATP
stores.
Anaerobic respiration fuels ATP production
Sports involving endurance: cross-country,
basketball, swimming.
Fueled by aerobic respiration
If demands are too great, switch to
anaerobic and muscle fatigue will set in.
Muscle Fatigue
Physiological inability to contract
Lactic Acid Build up
Not enough ATP to keep muscle working.
Cramps occur when no ATP available to
detach myosin heads
Oxygen Debt
Amount of O2 needed to restore body back to
proper state after exercise.
Lactic acid is converted back to pyruvic acid.
New ATP and creatine phosphate made.
Ion levels restored = Na+, K+, Ca2+