Introduction The Muscular System
Striated = striped. Skeletal muscle appears striped under a microscope Muscle Tissue Elongated cells, specialized for contraction Three types of muscle tissue: Skeletal muscle – striated/voluntary Cardiac muscle – striated/involuntary Smooth muscle – not striated/involuntary Striated = striped. Skeletal muscle appears striped under a microscope
Skeletal Muscle Functions Produces movement of the skeleton Maintains posture and body position Supports soft tissues Guards entrances and exits Maintains body temperature by generating heat Skeletal muscles pull on tendons attached to bones and thereby result in movement. 2. Continuous muscle contractions maintain posture. Without this constant action, you could not sit upright without collapsing.
Organization of Skeletal Muscle Organ-level structure “Muscle” = many bundles of muscle fibers Muscle fiber = single muscle cell (elongated) Fascicle = bundle of fibers fiber fascicle muscle
Organization of Skeletal Muscle Organ-level structure Connective Tissue layers: Endomysium (around a fiber) Perimysium (around a fascicle) Epimysium (outer layer) Connective tissue layers converge to become the tendon
Cellular Level Anatomy Sarcolemma = muscle fiber membrane Sarcoplasm = cytoplasm of muscle cell Sarcoplasmic reticulum = stores calcium for contraction Transverse (T) tubules = network of narrow tubes that form passageways through a muscle fiber Each muscle fiber contains hundreds to thousands of myofibrils. Myofibrils are responsible for muscle contraction. Because they are attached to the sarcolemma at each end of the cell, their contraction shortens the entire cell. Scattered among the myofibrils are mitochondria and granules of glycogen, a source of glucose. The breakdown of glucose and the activity of the mitochondria provide the ATP needed to power muscluar contractions
Organization of Skeletal Muscle Myofibrils = cytoskeletal proteins; composed of myofilaments (actin and myosin) Alternating arrangement of myofilaments gives skeletal muscle a striated appearance Actin = thin protein filament = light band Myosin = thick protein filament = dark band
Organization of Skeletal Muscle Nuclei (many) sarcolemma mitochondria sarcoplasm Myofibril; myofilaments
Organization of Skeletal Muscle Hierarchy of organization: Muscle fascicle fiber myofibrils myofilaments (actin/myosin)
The Sarcomere Functional unit of skeletal muscle Sarcomeres arranged end to end along a myofibril Arrangement of actin and myosin within the sarcomere produces a striped appearance Actin = light Myosin = dark Each myofibril consists of 10,000 sarcomeres arranged end to end. The sarcomere is the smallest functional unit of the muscle fiber. Interactions between the thick and thin filaments of sarcomeres are responsible for muscle contraction.
Sarcoplasmic reticulum Sarcomere Structure Z line = marks the boundaries of each sarcomere M line = middle of the sarcomere Sarcomere Sarcoplasmic reticulum Z line Z line M line
Sarcoplasmic reticulum Sarcomere Structure A band = Myosin (thick filament; dark band) I band = Actin (thin filament; light band) Sarcomere Sarcoplasmic reticulum Myosin Actin Z line Z line Neither type of filament spans the entire length of an individual sarcomere. The thick filaments lie in the center of the sarcomere, thin filaments at either end of the sarcomere. Differences in densities between actin and myosin account for the banded appearance of the sarcomere. M line I band A band I band
Sarcoplasmic reticulum Sarcomere Structure Animation H zone = no overlap between thick and thin filaments Sarcomere Sarcoplasmic reticulum Myosin Actin Z line H zone Z line M line I band A band I band
Label…A, I, M, Z, H nimation
Muscle at Rest Actin and myosin lie side-by side Myosin heads are “primed” for contraction H zone and I band are at maximum length
Changes to the sarcomere during contraction I band gets smaller Z lines move closer together H zone decreases Length of A bands doesn’t change Length of filaments doesn’t change animation
Sliding Filament Theory Model of muscle contraction in which actin “slides” past myosin to cause sarcomere shortening Involves 5 different molecules and calcium Myosin Actin Tropomyosin Troponin ATP myosin
Role of Nervous System Brain/spinal cord sends an impulse to the muscle Impulse = electrical signal Neuromuscular junction = nerve + muscle fiber Acteylcholine = neurotransmitter, activates the muscle Impulse travels through T-tubules triggering release of calcium from the sarcoplasmic reticulum
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At Rest
Sliding Filament Theory 1. The brain or spinal cord sends an impulse to the muscle; acetylcholine released at the neuromuscular junction
Sliding Filament Theory 2. Impulse triggered in the sarcolemma of the muscle fiber; impulse travels along T-tubules
Sliding Filament Theory 3. Calcium release: sarcoplasmic reticulum releases calcium; calcium diffuses through muscle fiber
Sliding Filament Theory 4. Active Site exposed: Ca2+ binds to troponin; tropomoyosin shifts; active sites for myosin are exposed
Sliding Filament Theory 5. Cross-bridge formation: Myosin head binds to actin
Sliding Filament Theory 6. Powerstroke: ADP and Pi are released from myosin; myosin moves, pulling the actin with it; sarcomere shortens
Sliding Filament Theory 7. Release: ATP binds to myosin; myosin released from actin; ATP reverts into ADP and Pi. Myosin is ready to form another crossbridge
Sliding Filament Theory 8. Relaxation: Impulse stops, calcium is released from troponin; tropomyosin covers the active site Ca+ is transported back into the SR
Contraction animation Muscle Contraction Contraction ends when nerve impulses stop AND calcium ion concentration returns to normal Contraction animation
Muscle stimulation Muscles shorten to produce tension (force; pull) Movement occurs when tension overcomes resistance Amount of tension produced depends on Frequency of fiber stimulation Number of fibers activates
Frequency of muscle fiber stimulation single stimulus-contraction-relaxation sequence (twitch) not enough to produce movement successive stimuli rise in tension (summation) Incomplete tetanus = tension peaks; relaxation is decreased Complete tetanus = relaxation phase completely eliminated
Frequency of muscle fiber stimulation
Tetanus shot? Lockjaw? Protects against infection by bacterium Clostridium tetani which can cause tetanus
Number of muscle fibers activated Motor unit = all the muscle fibers controlled by a single neuron The more precise the motor movement, the smaller the motor unit ( 1 nerve – 2 or 3 fibers) over time, more motor units are involved to produce smooth movements (recruitment)
Muscle Tone Muscle tone = resting tension Stabilizes the position of bones Low muscle tone = limp
atrophy Occurs when a muscle is not stimulated Muscle fibers become smaller and weaker Initially reversible Dying muscle fibers are not replaced Why physical therapy is important
Hypertrophy Excessive muscle stimulation Result = big muscles
Isotonic and Isometric Contraction Depends on pattern of tension production and overall change in length of muscle Isotonic = tension rises and muscle length changes EX: lifting something Isometric = tension rises but muscle length doesn’t change EX: postural muscles
Slow vs fast skeletal muscle fibers Slow fibers Endurance Contract slowly but for long periods of time Large amounts of mitochondria Fast fibers Speed Large in diameter Densely packed myofibrils Science of Marathon Running
Energy Muscle movements require HUGE amounts of ATP ~600 trillion molecules per second ATP in an energy transfer molecule not an energy storage molecules so not much ATP is stored Creatine phosphate (CP) can release stored energy to produce ATP; large amounts of CP stored
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Muscle Sketches Actin filament (see page 198) Label actin, troponin, tropomyosin, active site Myosin filament (see page 198) Label head Sarcomere (at rest and during contraction) Label all parts (A, I, actin, myosin, H, M, Z) Contracted sarcomere should be shorter than the relaxed