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Neuromuscular Adaptation

Neuromuscular Adaptation. Muscle Physiology 420:289. Agenda. Introduction Morphological Neural Histochemical. Introduction. The neuromuscular system readily adapts to various forms of training: Resistance trainin Plyometric training Endurance training

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Neuromuscular Adaptation

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  1. Neuromuscular Adaptation Muscle Physiology 420:289

  2. Agenda • Introduction • Morphological • Neural • Histochemical

  3. Introduction • The neuromuscular system readily adapts to various forms of training: • Resistance trainin • Plyometric training • Endurance training • Adaptations vary depending on type of training • Skeletal muscle adapts in many different ways • Morphological • Neural • Histochemical

  4. Agenda • Introduction • Morphological • Neural • Histochemical

  5. Morphological Adaptations • Morphology: The study of the configuration of structure of animals and plants • Most obvious morphological adaptation is increase in cross-sectional area (CSA) and/or muscle mass • Hypertrophy vs. Hyperplasia

  6. Hypertrophy and Myofibrillar Proliferation • Two mechanisms in which protein is accumulated  muscle growth • Increased rate of protein synthesis -Myosin and actin added to periphery of myofibrils • Decreased rate of protein degradation -Proteins constantly being degraded -Contractile protein ½ life = 7-15 days -Regular and rapid overturn  adaptability

  7. Hypertrophy and Myofibrillar Proliferation • Mechanism of action: • Myofibrils increase in mass and CSA due to addition of actin/myosin to periphery • Myofibrils reach critical mass where forceful actions tear Z-lines longitudinally • Myofibril splits

  8. Figure 8.3 b, Komi, 1996

  9. Figure 8.3 a, Komi, 1996

  10. Hypertrophy and Myofibrillar Proliferation • Hypertrophy of different fiber types: • Fast twitch: -Mechanism: Mainly increased rate of synthesis -Potential for hypertrophy: High -Stimulation: Forceful/high intensity actions • Slow twitch: -Mechanism: Mainly decreased rate of degradation -Potential of hypertrophy: Low -Stimulation: Low intensity repetitive actions -FT may atropy as ST hypertrophy

  11. FT ST FOG Figure 8.5, Komi, 1996

  12. Hypertrophy and Myofibrillar Proliferation • Role of satellite cells • History: • First identified in 1961 – Thought to be non-functioning • Adult myoblasts • Believed to be myoblasts that did not fuse into muscle fiber • Called satellite cells due to ability to migrate

  13. Brooks, et al., Fig 17.2, 2000

  14. Brooks et al., Fig 17.3, 2000

  15. Hypetrophy and Myofibrillar Proliferation • Satellite cell activation due to injury: • Dormant satellite cells become activated when homeostasis disrupted • Satellite cells proliferate via mitotic division • Divided cells align themselves along the injured/necrotic muscle fiber • Aligned cells fuse into myotube, mature into new fiber and replace old fiber

  16. Figure 5.7, McIntosh et al. 2005

  17. Hypertrophy and Myofibrillar Proliferation • Satellite cell activation due to resistance training: • Resistance training causes satellite cell activation as well • Interpretation: -Satellite cells repair injured fibers as a result of eccentric actions -Hyperplasia

  18. Hyperplasia • Muscle fiber proliferation during development – 4th week of gestation  several months postnatal • Millions of mononucleated myoblasts (via mitotic division) align themselves • Fusion via respective plasmalellae (Ca2+ mediated) • Myotube is formed • Cell consituents are formed  myofilaments, SR, t-tubules, sarcolemma . . .

  19. Evidence of Hyperplasia • Animal studies: • Cats: 9% increase in fiber number after heavy resistance training (Gonyea et al, 1986) • Quail: 52% in latissimus dorsi fiber number after 30 days of weight suspended to wing (Alway et al, 1989)

  20. Evidence of Hyperplasia • Human study: MacDougall et al. (1986) • Method of estimation: • Fiber number Fn of total muscle area (CT scan) and fiber diameter (biopsy) • Compared biceps of elite BB, intermediate BB and untrained controls • Results: Range: • 172,000 – 419,000 muscle fibers • Means between groups not significant • Conclusion: • Large variation between individuals • Variation due to genetics

  21. Other Morphological Adaptations • Angle of pennation • In general  as degree of pennation increases, so does force production • Why? • More muscle fibers/unit of muscle volume • More cross-bridges • More sarcomeres in parallel

  22. Sarcomeres in series  displacement and velocity Sarcomeres in parallel  force Figure 17.20, Brooks et al., 2000

  23. Figure 17.22, Brooks et al., 2000 Muscle length (ML) to fiber length (FL) ratio also an indicator of force and velocity properties of muscle

  24. Training?

  25. Other Morphological Adaptations • Capillary density: • High intensity resistance training: Decrease in capillary density • Endurance training: Increase in capillary density (body building) • Mitochondrial density: • High intensity resistance training: Decrease in mitochondrial density • Endurance training: Increase in mitochondrial density

  26. Agenda • Introduction • Morphological • Neural • Histochemical

  27. Neural Adaptations • Recall: • Motor unit: Neuron and muscle fibers innervated • Increasing force via recruitment of additional motor units  Number coding

  28. Figure 9.6, Komi, 1996

  29. Neural Adaptations • Recall: • Increasing force via greater neural discharge frequency  Rate coding • Maximum force of any agonist muscle requires: • Activation of all motor units • Maximal rate coding

  30. Neural Adaptations • Timeline

  31. Fig 20.8, Brooks et al. 2000

  32. Neural Adaptations • Increased activation of agonist motor units: • Untrained subjects are not able to activate all potential motor units • Resistance training may: • Increase ability to recruit highest threshold motor units • Increase rate coding of all motor units

  33. Neural Adaptations • Neural facilitation • Facilitation = opposite of inhibition • Enhancement of reflex response to rapid eccentric actions

  34. Fig 20.10, Brooks et al., 2000

  35. Neural Adaptations • Co-contraction of antagonists • Enhancement of agonist/antagonist control during rapid movements • Joint protection • Evidence: Sprinters greater hamstring EMG during knee extension compared to distance runners

  36. http://www.brianmac.demon.co.uk/sprints/sprintseq.htm

  37. Neural Adaptations • Neural disinhibition: • Golti tendon organs (GTO): • Location: Tendons • Role: Inhibition of agonist during forceful movements • Examples: • Muscle weakness during rehabilitation • Arm wrestling • 1RM

  38. 1. High muscle tension GOLGI TENDON REFLEX 3. GTO activation 4. Inhibition of agonist 2. High tendon tension Figure 4.16, Knutzen & Hamill (2004)

  39. Neural Adaptations • Progressive resistance training may inhibit GTO • Anecdotal evidence: • Car accidents • Hypnosis

  40. Neural Adaptations • Resistance training vs. plyometric training • Load: • RT: Heavy • PT: Light • Velocity of movement: • RT: Low • PT: High • Stretch shortening cycle (SSC): • RT: Minimal • PT: Yes

  41. Agenda • Introduction • Morphological • Neural • Histochemical

  42. Histochemical Adaptations • Histochemistry: Identification of tissues via staining techniques • Recall

  43. Table 12.8, McIntosh et al., 2005

  44. Histochemical Adaptations • Muscle fiber distribution shifts • Generally believed that ST do not change to FT and vice-versa • Several studies have observed IIB  IIA in humans • Fiber shifts from ST to FT and vice-versa have been observed in animals under extreme conditions

  45. Histochemical Adaptations • Chronic long term low frequency (10 Hz) stimulation of rabbit tibialis anterior • 3 hours: Swelling of SR • 4 days: Increased size/# of mitochondria, increased oxidative [enzyme], increased capillarization • 14 days: Increased width of Z-line, decreased SERCA activity • 28 days: ST isoforms of myosin and troponin, decreased muscle mass and CSA

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