Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Human Anatomy & Physiology SEVENTH EDITION Elaine N. Marieb Katja Hoehn PowerPoint.

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Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Human Anatomy & Physiology SEVENTH EDITION Elaine N. Marieb Katja Hoehn PowerPoint ® Lecture Slides prepared by Vince Austin, Bluegrass Technical and Community College C H A P T E R 9 Muscles and Muscle Tissue P A R T B

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Depolarization  Initially, this is a local electrical event called end plate potential  Later, it ignites an action potential that spreads in all directions across the sarcolemma

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Action Potential: Electrical Conditions of a Polarized Sarcolemma  The outside (extracellular) face is positive, while the inside face is negative  This difference in charge is the resting membrane potential Figure 9.8a

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings  The predominant extracellular ion is Na +  The predominant intracellular ion is K +  The sarcolemma is relatively impermeable to both ions Action Potential: Electrical Conditions of a Polarized Sarcolemma Figure 9.8a

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Action Potential: Depolarization and Generation of the Action Potential  An axonal terminal of a motor neuron releases ACh and causes a patch of the sarcolemma to become permeable to Na + (sodium channels open) Figure 9.8b

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Action Potential: Depolarization and Generation of the Action Potential  Na + enters the cell, and the resting potential is decreased (depolarization occurs)  If the stimulus is strong enough, an action potential is initiated Figure 9.8b

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Action Potential: Propagation of the Action Potential  Polarity reversal of the initial patch of sarcolemma changes the permeability of the adjacent patch  Voltage-regulated Na + channels now open in the adjacent patch causing it to depolarize Figure 9.8c

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Action Potential: Propagation of the Action Potential  Thus, the action potential travels rapidly along the sarcolemma  Once initiated, the action potential is unstoppable, and ultimately results in the contraction of a muscle Figure 9.8c

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Action Potential: Repolarization  Immediately after the depolarization wave passes, the sarcolemma permeability changes  Na + channels close and K + channels open  K + diffuses from the cell, restoring the electrical polarity of the sarcolemma Figure 9.8d

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Action Potential: Repolarization  Repolarization occurs in the same direction as depolarization, and must occur before the muscle can be stimulated again (refractory period)  The ionic concentration of the resting state is restored by the Na + -K + pump Figure 9.8d

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Excitation-Contraction Coupling  Once generated, the action potential:  Is propagated along the sarcolemma  Travels down the T tubules  Triggers Ca 2+ release from terminal cisternae  Ca 2+ binds to troponin and causes:  The blocking action of tropomyosin to cease  Actin active binding sites to be exposed

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Excitation-Contraction Coupling  Myosin cross bridges alternately attach and detach  Thin filaments move toward the center of the sarcomere  Hydrolysis of ATP powers this cycling process  Ca 2+ is removed into the SR, tropomyosin blockage is restored, and the muscle fiber relaxes

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Action Potential Scan Figure 9.9

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Excitation-Contraction (EC) Coupling 1.Action potential generated and propagated along sarcomere to T-tubules 2.Action potential triggers Ca2+ release 3.Ca++ bind to troponin; blocking action of tropomyosin released 4.contraction via crossbridge formation; ATP hyrdolysis 5.Removal of Ca+2 by active transport 6.tropomyosin blockage restored; contraction ends Figure 9.10

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Figure 9.10 ADP PiPi Net entry of Na + Initiates an action potential which is propagated along the sarcolemma and down the T tubules. T tubule Sarcolemma SR tubules (cut) Synaptic cleft Synaptic vesicle Axon terminal ACh Neurotransmitter released diffuses across the synaptic cleft and attaches to ACh receptors on the sarcolemma. Action potential in T tubule activates voltage-sensitive receptors, which in turn trigger Ca 2+ release from terminal cisternae of SR into cytosol. Calcium ions bind to troponin; troponin changes shape, removing the blocking action of tropomyosin; actin active sites exposed. Contraction; myosin heads alternately attach to actin and detach, pulling the actin filaments toward the center of the sarcomere; release of energy by ATP hydrolysis powers the cycling process. Removal of Ca 2+ by active transport into the SR after the action potential ends. SR Tropomyosin blockage restored, blocking myosin binding sites on actin; contraction ends and muscle fiber relaxes. Ca

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Figure 9.10 Synaptic cleft Synaptic vesicle Axon terminal ACh Neurotransmitter released diffuses across the synaptic cleft and attaches to ACh receptors on the sarcolemma.

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Figure 9.10 Net entry of Na + Initiates an action potential which is propagated along the sarcolemma and down the T tubules. T tubule Sarcolemma Synaptic cleft Synaptic vesicle Axon terminal ACh Neurotransmitter released diffuses across the synaptic cleft and attaches to ACh receptors on the sarcolemma. 1

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Figure 9.10 Net entry of Na + Initiates an action potential which is propagated along the sarcolemma and down the T tubules. T tubule Sarcolemma SR tubules (cut) Synaptic cleft Synaptic vesicle Axon terminal ACh Neurotransmitter released diffuses across the synaptic cleft and attaches to ACh receptors on the sarcolemma. Action potential in T tubule activates voltage-sensitive receptors, which in turn trigger Ca 2+ release from terminal cisternae of SR into cytosol. SR Ca

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Figure 9.10 Net entry of Na + Initiates an action potential which is propagated along the sarcolemma and down the T tubules. T tubule Sarcolemma SR tubules (cut) Synaptic cleft Synaptic vesicle Axon terminal ACh Neurotransmitter released diffuses across the synaptic cleft and attaches to ACh receptors on the sarcolemma. Action potential in T tubule activates voltage-sensitive receptors, which in turn trigger Ca 2+ release from terminal cisternae of SR into cytosol. Calcium ions bind to troponin; troponin changes shape, removing the blocking action of tropomyosin; actin active sites exposed. SR Ca

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Figure 9.10 Net entry of Na + Initiates an action potential which is propagated along the sarcolemma and down the T tubules. T tubule Sarcolemma SR tubules (cut) Synaptic cleft Synaptic vesicle Axon terminal ACh Neurotransmitter released diffuses across the synaptic cleft and attaches to ACh receptors on the sarcolemma. Action potential in T tubule activates voltage-sensitive receptors, which in turn trigger Ca 2+ release from terminal cisternae of SR into cytosol. Calcium ions bind to troponin; troponin changes shape, removing the blocking action of tropomyosin; actin active sites exposed. Contraction; myosin heads alternately attach to actin and detach, pulling the actin filaments toward the center of the sarcomere; release of energy by ATP hydrolysis powers the cycling process. SR Ca

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Figure 9.10 Net entry of Na + Initiates an action potential which is propagated along the sarcolemma and down the T tubules. T tubule Sarcolemma SR tubules (cut) Synaptic cleft Synaptic vesicle Axon terminal ACh Neurotransmitter released diffuses across the synaptic cleft and attaches to ACh receptors on the sarcolemma. Action potential in T tubule activates voltage-sensitive receptors, which in turn trigger Ca 2+ release from terminal cisternae of SR into cytosol. Calcium ions bind to troponin; troponin changes shape, removing the blocking action of tropomyosin; actin active sites exposed. Contraction; myosin heads alternately attach to actin and detach, pulling the actin filaments toward the center of the sarcomere; release of energy by ATP hydrolysis powers the cycling process. Removal of Ca 2+ by active transport into the SR after the action potential ends. SR Ca

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Figure 9.10 ADP PiPi Net entry of Na + Initiates an action potential which is propagated along the sarcolemma and down the T tubules. T tubule Sarcolemma SR tubules (cut) Synaptic cleft Synaptic vesicle Axon terminal ACh Neurotransmitter released diffuses across the synaptic cleft and attaches to ACh receptors on the sarcolemma. Action potential in T tubule activates voltage-sensitive receptors, which in turn trigger Ca 2+ release from terminal cisternae of SR into cytosol. Calcium ions bind to troponin; troponin changes shape, removing the blocking action of tropomyosin; actin active sites exposed. Contraction; myosin heads alternately attach to actin and detach, pulling the actin filaments toward the center of the sarcomere; release of energy by ATP hydrolysis powers the cycling process. Removal of Ca 2+ by active transport into the SR after the action potential ends. SR Tropomyosin blockage restored, blocking myosin binding sites on actin; contraction ends and muscle fiber relaxes. Ca

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Role of Ionic Calcium (Ca 2+ ) in the Contraction Mechanism  At low intracellular Ca 2+ concentration:  Tropomyosin blocks the binding sites on actin  Myosin cross bridges cannot attach to binding sites on actin  The relaxed state of the muscle is enforced Figure 9.11a

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Role of Ionic Calcium (Ca 2+ ) in the Contraction Mechanism  At higher intracellular Ca 2+ concentrations:  Additional calcium binds to troponin (inactive troponin binds two Ca 2+ )  Calcium-activated troponin binds an additional two Ca 2+ at a separate regulatory site Figure 9.11b

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Role of Ionic Calcium (Ca 2+ ) in the Contraction Mechanism  Calcium-activated troponin undergoes a conformational change  This change moves tropomyosin away from actin’s binding sites Figure 9.11c

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Role of Ionic Calcium (Ca 2+ ) in the Contraction Mechanism  Myosin head can now bind and cycle  This permits contraction (sliding of the thin filaments by the myosin cross bridges) to begin Figure 9.11d

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Sequential Events of Contraction  Cross bridge formation – myosin cross bridge attaches to actin filament  Working (power) stroke – myosin head pivots and pulls actin filament toward M line  Cross bridge detachment – ATP attaches to myosin head and the cross bridge detaches  “Cocking” of the myosin head – energy from hydrolysis of ATP cocks the myosin head into the high-energy state PLAY InterActive Physiology ®: Sliding Filament Theory, pages 3-29

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings ATP ADP Myosin head (high-energy configuration) Myosin head attaches to the actin myofilament, forming a cross bridge. Thin filament ADP ATP hydrolysis As ATP is split into ADP and P i, the myosin head is energized (cocked into the high-energy conformation). ADP Inorganic phosphate (P i ) generated in the previous contraction cycle is released, initiating the power (working) stroke. The myosin head pivots and bends as it pulls on the actin filament, sliding it toward the M line. Then ADP is released. Myosin head (low-energy configuration) Thick filament ATP PiPi PiPi As new ATP attaches to the myosin head, the link between myosin and actin weakens, and the cross bridge detaches. PiPi Figure 9.12

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings ADP Myosin head (high-energy configuration) Myosin head attaches to the actin myofilament, forming a cross bridge. 1 PiPi Figure 9.12

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings ADP Myosin head (high-energy configuration) Myosin head attaches to the actin myofilament, forming a cross bridge. ADP Inorganic phosphate (P i ) generated in the previous contraction cycle is released, initiating the power (working) stroke. The myosin head pivots and bends as it pulls on the actin filament, sliding it toward the M line. Then ADP is released. 1 2 PiPi PiPi Figure 9.12

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings ADP Myosin head (high-energy configuration) Myosin head attaches to the actin myofilament, forming a cross bridge. ADP Inorganic phosphate (P i ) generated in the previous contraction cycle is released, initiating the power (working) stroke. The myosin head pivots and bends as it pulls on the actin filament, sliding it toward the M line. Then ADP is released. ATP 1 2 PiPi PiPi Figure 9.12

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings ATP ADP Myosin head (high-energy configuration) Myosin head attaches to the actin myofilament, forming a cross bridge. ADP Inorganic phosphate (P i ) generated in the previous contraction cycle is released, initiating the power (working) stroke. The myosin head pivots and bends as it pulls on the actin filament, sliding it toward the M line. Then ADP is released. Myosin head (low-energy configuration) ATP PiPi As new ATP attaches to the myosin head, the link between myosin and actin weakens, and the cross bridge detaches. PiPi Figure 9.12

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings ATP ADP Myosin head (high-energy configuration) Myosin head attaches to the actin myofilament, forming a cross bridge. Thin filament ADP ATP hydrolysis As ATP is split into ADP and P i, the myosin head is energized (cocked into the high-energy conformation). ADP Inorganic phosphate (P i ) generated in the previous contraction cycle is released, initiating the power (working) stroke. The myosin head pivots and bends as it pulls on the actin filament, sliding it toward the M line. Then ADP is released. Myosin head (low-energy configuration) Thick filament ATP PiPi PiPi As new ATP attaches to the myosin head, the link between myosin and actin weakens, and the cross bridge detaches. PiPi Figure 9.12

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings ATP ADP Myosin head (high-energy configuration) Myosin head attaches to the actin myofilament, forming a cross bridge. Thin filament ADP ATP hydrolysis As ATP is split into ADP and P i, the myosin head is energized (cocked into the high-energy conformation). ADP Inorganic phosphate (P i ) generated in the previous contraction cycle is released, initiating the power (working) stroke. The myosin head pivots and bends as it pulls on the actin filament, sliding it toward the M line. Then ADP is released. Myosin head (low-energy configuration) Thick filament ATP PiPi PiPi As new ATP attaches to the myosin head, the link between myosin and actin weakens, and the cross bridge detaches. PiPi Figure 9.12

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Contraction of Skeletal Muscle Fibers  Contraction – refers to the activation of myosin’s cross bridges (force-generating sites)  Shortening occurs when the tension generated by the cross bridge exceeds forces opposing shortening  Contraction ends when cross bridges become inactive, the tension generated declines, and relaxation is induced

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Contraction of Skeletal Muscle (Organ Level)  Contraction of muscle fibers (cells) and muscles (organs) is similar  The two types of muscle contractions are:  Isometric contraction – increasing muscle tension (muscle does not shorten during contraction)  Isotonic contraction – decreasing muscle length (muscle shortens during contraction)

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Motor Unit: The Nerve-Muscle Functional Unit  A motor unit is a motor neuron and all the muscle fibers it supplies  The number of muscle fibers per motor unit can vary from four to several hundred  Muscles that control fine movements (fingers, eyes) have small motor units

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Motor Unit: The Nerve-Muscle Functional Unit PLAY InterActive Physiology ®: Contraction of Motor Units, pages 3-9 Figure 9.13a

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Motor Unit: The Nerve-Muscle Functional Unit  Large weight-bearing muscles (thighs, hips) have large motor units  Muscle fibers from a motor unit are spread throughout the muscle; therefore, contraction of a single motor unit causes weak contraction of the entire muscle

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Muscle Twitch  A muscle twitch is the response of a muscle to a single, brief threshold stimulus  There are three phases to a muscle twitch  Latent period  Period of contraction  Period of relaxation

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Phases of a Muscle Twitch  Latent period – first few msec after stimulus; EC coupling taking place  Period of contraction – cross bridges from; muscle shortens  Period of relaxation – Ca 2+ reabsorbed; muscle tension goes to zero Figure 9.14a

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Muscle Twitch Comparisons Figure 9.14b

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Graded Muscle Responses  Graded muscle responses are:  Variations in the degree of muscle contraction  Required for proper control of skeletal movement  Responses are graded by:  Changing the frequency of stimulation  Changing the strength of the stimulus

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Muscle Response to Varying Stimuli  A single stimulus results in a single contractile response – a muscle twitch  Frequently delivered stimuli (muscle does not have time to completely relax) increases contractile force – wave summation Figure 9.15

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Muscle Response to Varying Stimuli  More rapidly delivered stimuli result in incomplete tetanus  If stimuli are given quickly enough, complete tetanus results Figure 9.15

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Muscle Response: Stimulation Strength  Threshold stimulus – the stimulus strength at which the first observable muscle contraction occurs  Beyond threshold, muscle contracts more vigorously as stimulus strength is increased  Force of contraction is precisely controlled by multiple motor unit summation  This phenomenon, called recruitment, brings more and more muscle fibers into play

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Stimulus Intensity and Muscle Tension Figure 9.16

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Size Principle Figure 9.17

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Treppe: The Staircase Effect  Staircase – increased contraction in response to multiple stimuli of the same strength  Contractions increase because:  There is increasing availability of Ca 2+ in the sarcoplasm  Muscle enzyme systems become more efficient because heat is increased as muscle contracts

Copyright © 2006 Pearson Education, Inc., publishing as Benjamin Cummings Treppe: The Staircase Effect Figure 9.18