1. Muscles!
REMINDERS:
Skull Model due Wed
PA Guest Speaker ??!
Bellwork 9/22/14
1.) Which type (s) of muscle is voluntary? 2.) Which type (s) of muscle is involuntary? 3.) Which type is usually attached to bones? 4.) Which type is found in the heart? 5.) Which type is found in walls of organs? 6.) Which has intercalated discs? 7.) Which muscle tissue (s) is striated? 8.) Which muscle tissue is multinucleated?
Learning Targets:
*I can ID major muscles location and fxn.
*I can describe steps of muscle contraction and relate it to exercise.

2. Muscles!
REMINDERS:
Skull Model due Wed
PA Guest Speaker ??!
Bellwork 9/23/14
Bellwork: compare 3 types of muscle (complete as much as possible) Classwork: labeling muscles and primary function Intro of sarcomere
Learning Targets:
*I can ID major muscles location and fxn.
*I can describe steps of muscle contraction and relate it to exercise.

3. Muscles!
REMINDERS:
Skull Model due MONDAY
(NO LATER)
PA Guest Speaker ??!
Bellwork 9/24/14
Bellwork: label and color skeletal muscle cell (on back of sarcomere sheet from yesterday) Classwork: sliding filament theory
Learning Targets:
*I can ID major muscles location and fxn.
*I can describe steps of muscle contraction and relate it to exercise.

4. Muscles!
Bellwork 9/29/14
Bellwork: 1. Sit with your partner, have skull and Self-evaluation completed! 2. review skeletal muscle structure and fxn Classwork: label and color skeletal muscle cell; I.D. fxns of all muscles.
Learning Targets:
*I can ID major muscles location and fxn.
*I can describe steps of muscle contraction and relate it to exercise.

6. Muscular System

8. FUNCTIONS Produce skeletal movement Maintain posture and body position
Support soft tissues
Guard entrances and exits
Heat Generation body temp.

9. Types of Muscle Tissue
Skeletal
Cardiac
Smooth

13. SKELETAL MUSCLES
Includes all of the skeletal muscles that can be controlled voluntarily
Approx have been identified in the human body
Shape indicates function

14. Functional Characteristics of Muscle Tissue
Excitability: receive and response to stimuli
Contractibility: shorten forcibly when stimulated
Extensibility: stretch and extension
Elasticity: bounce back to original length after being shortened or lengthened.

15. TYPES OF MOVEMENTS BY MUSCLE CONTRACTIONS
Each muscle begins at an origin, ends at an insertion, and contracts to produce an action. Origin: immovable (anchored end) Insertion: movable end of a muscle ** When a muscle contracts and shortens, its insertion is pulled toward its origin.

16. Types of Movement Actions Include:
Flexion - a movement that reduces the angle between 2 bones; Opposite = Extension
Abduction - moving a part away from midline of body; Opposite = Adduction
Dorsiflexion - elevates top of foot and tilts it up; Opposite = Plantar flexion
Eversion – sole of foot out
Opposite= Inversion
Supination - turn palm to anterior position; Opposite = Pronation
Rotation - movement around a longitudinal axis

17. Extension
Flexion
Dorsiflexion
Extension
Adduction
Plantar
Flexion
Flexion
Abduction

18. Supination
Eversion
Inversion
Pronation
Rotation

19. Muscle Organization
Muscles are grouped according to their primary action:
Agonist - produces a particular movement (triceps)
Synergist - assists in producing movement
Antagonist - opposes agonist; relaxes during the prime movement

20. Figure 9.2

21. Connective Tissue Coverings
Epimysium: connective tissue that surrounds a skeletal muscle.
Perimysium: connective tissue that extends inward from the epimysium and separates the muscle into bundles of muscle fibers called fascicles.
Endomysium: Connective tissue that surrounds each fascicle.

22. Skeletal Muscle Structure
A muscle is composed of skeletal muscle tissue, nervous tissue, blood, and connective tissue.
Individual muscles are held in place by fascia, dense connective tissue.
Tendons are extensions of the fascia and intertwine with the fibers in the periosteum of the bone.
Muscles are connected to muscles by sheets of connective tissue called aponeuroses.

24. Organization of Muscle Fibers
Parallel - fascicles are parallel to the long axis of muscle (most muscles); strength
Convergent - fibers are based over a broad area, but all fibers come together at a common attachment site (pectoralis); more versatile in movement
Pennate - fascicles form a common angle with the tendon; uni, bi, multipennate; produces high tension
Circular/spinchter - fibers are concentrically arranged around an opening (orbicularis oris)

26. Skeletal Muscle Fibers
A muscle fiber is a multinucleated cell that attaches to connective tissue.
Sarcolemma is the muscle cell membrane.
Sarcoplasm is the cytoplasm containing nuclei, mitochondria, and myofibrils.
Myofibrils are composed of protein filaments, myosin and actin.

27. Protein Filaments
Myosin: Thick filament of twisted protein strands with globular ends called cross- bridges.
Actin: Thin filament protein, also contains tropomyosin and troponin. (movable)
Organization of filaments leads to light and dark striations seen in skeletal muscle.

30. Sarcomere Structure
Sarcomere: The fundamental Unit of a muscle; contains repeating patterns of striations
Striations: repeating light and dark regions

31. Sarcomere Structure
I bands (light bands) are composed of actin filaments attached to Z lines.
A bands (dark bands) are composed of myosin overlapping actin attached to Z lines by titin.
A central region (H zone) consists of myosin only with a thick line, the M line.

33. Microscopic structure
Sarcoplasmic reticulum: network of membranous sacs surrounding myofibrils.
Transverse tubules (T-tubules) extend into the sarcoplasm and contain extracellular fluid.

34. Microscopic structure
Cisternae: enlarged portions of the sarcoplasmic reticulum.
These three structures form a triad where the actin and myosin overlap.

38. http://highered. mcgraw-hill

39. Muscle Contraction Quiz
Name of the fundamental unit of a muscle.
What are the two globular proteins (myofibrils) found in muscle?
What two proteins are associated with the thin filament?
What neurotransmitter cause stimulation of SR-sarcoplasmic reticulum?
What molecule is necessary for cross bridge formation?
When this molecule is released from the SR-sarcoplasmic reticulum, what does it bind to?
When a muscle contracts the length of the muscle ___________.
Describe a resting sarcomere.