Skeletal Muscle Structure and Function

Functions of Skeletal Muscles

Skeletal muscles are essential for movement, posture, and various physiological processes. Their main functions can be summarized as follows:

• Movement: Muscles pull on bones to create body movements such as walking, running, or lifting objects.

• Posture and Body Position: Muscles help maintain posture, allowing you to sit, stand, and hold your body upright.

• Support of Soft Tissues: Muscles protect and support internal organs, especially in the abdominal and pelvic regions.

• Guarding Body Openings: Sphincter muscles control the opening and closing of passages such as the mouth, urethra, and anus.

• Heat Generation (Thermogenesis): Muscle contractions produce heat, helping to maintain body temperature (e.g., shivering).

Connective Tissue Organization in Muscle

Skeletal muscles are organized by layers of connective tissue that provide structure and support:

• Endomysium: Surrounds each individual muscle fiber (cell).

• Perimysium: Surrounds a fascicle (bundle of muscle fibers).

• Epimysium: Surrounds the entire muscle.

Mnemonic: ENDO > PERI > EPI (smallest to largest)

Anatomy of a Skeletal Muscle Fiber

Each muscle fiber is a specialized cell with unique structures for contraction:

• Sarcolemma: The cell membrane of a muscle fiber.

• Sarcoplasm: The cytoplasm of a muscle fiber.

• Nuclei: Multiple, located at the periphery of the cell.

• Myofibrils: Contractile organelles composed of myofilaments.

• Sarcoplasmic Reticulum (SR): Stores calcium ions necessary for contraction.

• T-tubules (Transverse Tubules): Carry electrical signals (action potentials) into the cell.

Sarcomere Organization

The sarcomere is the functional unit of muscle contraction, composed of repeating segments along the myofibril:

• Z line: Boundary of each sarcomere.

• I band: Contains only thin filaments (actin).

• A band: Entire length of thick filaments (myosin).

• H zone: Region with only thick filaments.

• M line: Center of the sarcomere.

During contraction:

• I band and H zone decrease in width.

• A band remains the same.

Key Terms in Muscle Structure

• Sarcolemma: Muscle cell membrane.

• Sarcoplasm: Muscle cell cytoplasm.

• Sarcoplasmic Reticulum: Stores and releases calcium ions.

• T-tubules: Carry action potentials into the muscle fiber.

• Myofibrils: Bundles of myofilaments (actin and myosin).

Contraction of Skeletal Muscle: Steps

Muscle contraction is a complex process involving electrical and chemical signals:

1. Nerve impulse arrives at the neuromuscular junction.

2. Acetylcholine (ACh) is released into the synaptic cleft.

3. Action potential spreads along the sarcolemma.

4. Calcium is released from the sarcoplasmic reticulum.

5. Calcium binds to troponin.

6. Tropomyosin moves, exposing active sites on actin.

7. Myosin binds to actin, forming cross-bridges.

8. Power stroke occurs (myosin pulls actin).

9. ATP binds to myosin, causing detachment from actin.

10. Muscle relaxes when calcium is reabsorbed into the SR.

Importance of the Sarcoplasmic Reticulum (SR)

• Stores calcium ions (Ca2+).

• Releases calcium for muscle contraction.

• Reabsorbs calcium for muscle relaxation.

The Triad

The triad is a structural feature important for excitation-contraction coupling:

• Consists of one T-tubule and two terminal cisternae of the sarcoplasmic reticulum.

Components of Actin (Thin Filament)

• Actin: Main protein forming the thin filament.

• Troponin: Binds calcium and regulates tropomyosin position.

• Tropomyosin: Blocks active sites on actin when muscle is at rest.

Neuromuscular Junction (NMJ)

The NMJ is the synapse between a motor neuron and a muscle fiber:

• Motor neuron

• Synaptic cleft

• Axon terminal

• Acetylcholine (ACh)

• Motor end plate

Types of Muscle Contractions

• Twitch: Single, brief contraction.

• Treppe: Gradual increase in contraction strength after repeated stimulation following rest.

• Wave Summation: Increased force due to repeated stimuli before relaxation is complete.

• Incomplete Tetanus: Partial relaxation between contractions.

• Complete Tetanus: Sustained contraction with no relaxation.

Isometric vs. Isotonic Contractions

Energy Sources for Muscle Contraction

• At rest: Aerobic respiration using fatty acids and glucose.

• During contraction:

  1. Stored ATP

  2. Creatine phosphate

  3. Glycolysis

  4. Aerobic respiration

Muscle Fatigue

Muscle fatigue is a temporary loss of ability to contract due to:

• ATP depletion

• Ion imbalances

• Lactic acid accumulation

• Nervous system factors

Muscle Fiber Types

Skeletal Muscle Arrangements

Muscle Attachments: Origin and Insertion

• Origin: Attachment point that remains relatively fixed during contraction.

• Insertion: Attachment point that moves during contraction.

Example: Biceps brachii Origin: Scapula Insertion: Radius When the biceps contract, the radius moves toward the scapula.

Muscle Roles in Movement

• Agonist (Prime Mover): Main muscle producing a movement (e.g., biceps brachii during elbow flexion).

• Antagonist: Opposes the agonist (e.g., triceps brachii during elbow flexion).

• Synergist: Assists the agonist (e.g., brachialis assists the biceps).

• Fixator: Stabilizes the origin of the agonist (e.g., muscles stabilizing the scapula during arm movement).

Axial vs. Appendicular Musculature

Muscle Identification (For Each Muscle)

For each muscle, know the following:

1. Origin

2. Insertion

3. Innervation (nerve supply)

4. Major action

Example: Biceps brachii Origin: Scapula Insertion: Radius Innervation: Musculocutaneous nerve Major action: Flexes elbow and supinates forearm

Additional info: For exam preparation, be able to identify these features for all major muscles discussed in class.