1. Muscle Tissue Al Maarefa College

2. Objectives Identify basic structure of Muscles Recognize types of muscular tissues and the difference between them Recognize the relation between structure and function of various muscular tissues

3. Tissues Four fundamental tissues are recognized: – Epithelial tissue – Connective tissue – Muscular tissue – Nervous tissue

4. Muscle Tissue Characteristics – Cells are referred to as fibers – Contracts or shortens with force when stimulated

5. Special functional characteristics Contractility – Only one action: to shorten – Shortening generates pulling force Excitability – Nerve fibers cause electrical impulse to travel Extensibility – Stretch with contraction of an opposing muscle Elasticity – Recoils passively after being stretched

6. Muscle function Providing movement Maintaining posture Stabilizing joint Generating heat

7. Muscle Tissue Types Skeletal: – attached to bones Cardiac: – muscle of the heart Smooth: – muscle associated with tubular structures and with the skin

11. Skeletal muscle – Blood supply

12. Skeletal Muscle Nucleii are in periphery of cells, just under cell membrane

13. Skeletal Muscle A bands (dark-stained) I bands (light-stained) Z lines A bands I bands

14. Skeletal Muscle

20. Skeletal Muscle Tissue Figure 4.14a

21. Cardiac Muscle Tissue Figure 4.14b

22. Cardiac Muscle Tissue

25. Smooth Muscle Tissue

30. Skeletal Muscle Voluntary movement Long and cylindrical Transverse striation Each fiber is multi-nuclear (multinucleated cells – embryonic cells fuse) 40% of body weight

31. Skeletal Muscle

32. Smooth Muscle Long, spindle shape Not striated Single nucleus Involuntary movement Internal organs

33. Smooth Muscle

34. Cardiac Muscle Striations Involuntary One nucleus – Deep center Heart muscle

35. Cardiac Muscle

37. Similarities… Their cells are called fibers because they are elongated Contraction depends on myofilaments – Actin – Myosin Plasma membrane is called sarcolemma – Sarcos = flesh – Lemma = sheath

38. Skeletal Muscle Covering layers – Epimisium: surrounds the whole muscle – Perimesium: surrounds a muscle fascicle – Endomesium: surrounds each muscle fiber

39. Skeletal Muscle Epimysium surrounds whole muscle

40. Skeletal Muscle Perimysium is around fascicle Perimysium

41. Skeletal Muscle Endomysium is around each muscle fiber Endomysium

42. Some sites showing animations of muscle contraction http://entochem.tamu.edu/MuscleStrucContr actswf/index.html http://entochem.tamu.edu/MuscleStrucContr actswf/index.html http://www.brookscole.com/chemistry_d/tem plates/student_resources/shared_resources/a nimations/muscles/muscles.html http://www.brookscole.com/chemistry_d/tem plates/student_resources/shared_resources/a nimations/muscles/muscles.html

43. Skeletal muscle Fibers (each is one cell) have striations Myofibrils are organelles of the cell: these are made up of filaments Sarcomere – Basic unit of contraction – Myofibrils are long rows of repeating sarcomeres – Boundaries: Z discs (or lines) This big cylinder is a fiber: 1 cell -an organelle

44. Myofibrils Made of three types of filaments (or myofilaments): – Thick (myosin) – Thin (actin) – Elastic (titin) ______actin _____________myosin titin_____

45. Depending on the distribution and interconnection of myofilaments a number of "bands" and "lines" can be distinguished in the sarcomeres : I-band - actin filaments, A-band - myosin filaments which may overlap with actin filaments, H-band - zone of myosin filaments only (no overlap with actin filaments) within the A-band, Z-line - zone of apposition of actin filaments belonging to two neighbouring sarcomeres M-line - band of connections between myosin filaments.

46. Sliding Filament Model __relaxed sarcomere__ _partly contracted_ fully contracted “A” band constant because it is caused by myosin, which doesn’t change length Sarcomere shortens because actin pulled towards its middle by myosin cross bridges Titin resists overstretching

47. Another pic

48. EM (electron microscope): parts of 2 myofibrils Labeled and unlabeled

49. Sarcoplasmic reticulum is smooth ER – Tubules surround myofibrils – Cross-channels called “terminal cisternae” – Store Ca++ and release when muscle stimulated to contract – To thin filaments triggering sliding filament mechanism of contraction – T tubules are continuous with sarcolemma, therefore whole muscle (deep parts as well) contracts simultaneously

50. Neuromuscular Junction Motor neurons innervate muscle fibers Motor end plate is where they meet Neurotransmitters are released by nerve signal: this initiates calcium ion release and muscle contraction Motor Unit: a motor neuron and all the muscle fibers it innervates (these all contract together) Average is 150, but range is four to several hundred muscle fibers in a motor unit The finer the movement, the fewer muscle fibers /motor unit The fibers are spread throughout the muscle, so stimulation of a single motor unit causes a weak contraction of the entire muscle

53. Types of skeletal muscle fibers Fast, slow and intermediate Whether or not they predominantly use oxygen to produce ATP (the energy molecule used in muscle contraction) – Oxidative – aerobic (use oxygen) – Glycolytic – make ATP by glycolysis (break down of sugars without oxygen=anaerobic) Fast fibers: “white fibers” – large, predominantly anaerobic, fatigue rapidly (rely on glycogen reserves); most of the skeletal muscle fibers are fast Slow fibers: “red fibers” – half the diameter, 3X slower, but can continue contracting; aerobic, more mitochondria, myoglobin Intermediate: in between

54. A skeletal muscle contracts when its motor units are stimulated Amount of tension depends on 1.the frequency of stimulation 2.the number of motor units involved Single, momentary contraction is called a muscle twitch All or none principle: each muscle fiber either contracts completely or not at all Amount of force: depends on how many motor units are activated Muscle tone – Even at rest, some motor units are active: tense the muscle even though not causing movement: “resting tone”

55. Muscle hypertrophy Muscle hypertrophy – Weight training (repeated intense workouts): increases diameter and strength of “fast” muscle fibers by increasing production of Mitochondria Actin and myosin protein Myofilaments containing these contractile proteins The myofibril organelles these myofilaments form – Fibers enlarge (hypertrophy) as number and size of myofibrils increase [Muscle fibers (=muscle cells) don’t increase in number but increase in diameter producing large muscles] Muscle atrophy Muscle atrophy: loss of tone and mass from lack of stimulation – Muscle becomes smaller and weaker Note on terminology: in general, increased size is hypertrophy; increased number of cells is hyperplasia

56. Cardiac muscle Bundles form thick myocardium Cardiac muscle cells are single cells (not called fibers) Cells branch Cells join at intercalated discs 1-2 nuclei in center Here “fiber” = long row of joined cardiac muscle cells Inherent rhythmicity: each cell! (muscle cells beat separately without any stimulation) Intercalated disc__________

57. Smooth muscle Muscles are spindle-shaped cells One central nucleus Grouped into sheets: often running perpendicular to each other Peristalsis No striations (no sarcomeres) Contractions are slow, sustained and resistant to fatigue Does not always require a nervous signal: can be stimulated by stretching or hormones 6 major locations: 1.inside the eye 2. walls of vessels 3. respiratory tubes 4. digestive tubes 5. urinary organs 6. reproductive organs