This week…

1. This week… • The functions of the Muscular System • The types of Muscle, where they are found and what they do • Muscle cells • How muscles contract on the microscopic level • How muscles use energy

2. THE MUSCULAR SYSTEM Why do we have muscles?

4. Functions • Movement • Jump, run, walk • Move eyeballs, swallow, blink, smile • Blood pressure, moving food, releasing urine, having a baby • Moving blood through the body • Support • Posture and stabilizing joints • Generate Heat

5. 3Types of Muscle • 1. Skeletal Muscle tissue • Attach to and cover the skeletal system • STRIATED and VOLUNTARY muscle • Can contract fast, but gets tired • Adaptable for light touch or strong

6. 2. Cardiac Muscle • Only found in the heart • STRIATED but INVOLUNTARY • Contracts at a steady rate

7. 3. Smooth Muscle • Found in the walls of your organs • NOT STRIATED and INVOLUNTARY • Contracts slow and the contractions can last a while

8. Why is each muscle tissue good for where it is found? - Skeletal- contracts fast, at variable amounts a lot or a little. We can control it for movements. Needs to rest though. - Cardiac- steady contractions. Can’t ever rest. We don’t want to have to think about beating our heart. - Smooth-slow and sustained contractions. Don’t want to have to think about moving our food along. Good for forcing things through our systems

9. Characteristics of Muscle • EXCITABILITY/ IRRITABILITY • Can receive and respond to a stimulus • CONTRACTILITY • Can shorten when stimulated • EXTENSIBILITY • Can be stretched or extended when relaxed • ELASTICITY • Can resume length after being stretched

10. Microscopic Anatomy of a Muscle Cell • Cell= Muscle Fiber • Very long- can run the length of the muscle • Cell Membrane =Sarcolema • Many Nuclei • Glycosomes store large amounts of glycogen (for making energy) and Myoglobin (stores Oxygen) • Cytoplasm =Sarcoplasm • Hundreds of Mitochondria here making ATP • ER = Sarcoplasmic Reticulum • Stores Calcium for muscle contractions

11. Muscle cell made of Myofibrils Myofibrils are cords of protein 2 types that alternate Thick – made of MYOSIN Thin – made of ACTIN A band = where thick and thin overlap (looks like DARK stripe) I band = only thin (looks like LIGHT stripe) SARCOMERE = from z disc to z disc

12. Myofibrils make up Muscle Cells

13. Muscle cells all held together with connective tissue into a muscle.

14. Muscles and Nerves • Neuromuscular junction = where nerve meets muscle for stimulus • Motor neurons = the nerve cells that stimulate the muscle fibers • Motor End Plate/ Synaptic Cleft = the part of the muscle cell that interacts with the motor neurons

15. Muscles and Nerves • Cell membranes have more positive ions on the outside than on the inside= RESTING MEMBRANE POTENTIAL • Nerve stimulus causes positive ions to rush into cells= ACTION POTENTIAL • NEUROTRANSMITTER = a chemical that carries the signal from a nerve to a muscle- Acetylcholine

16. How Info gets from Nerve to Muscle • An action potential arrives at the end of the motor neuron – Releases Acetylcholine- Goes across Synaptic Cleft to Motor End Plate. • Acetylcholine binds to muscle cell membrane causing positive (sodium) ions to rush into cell = Action potential in muscle cell • Action potential causes muscle to contract

17. Neuromuscular Junction

18. How Muscles Contract • Action potential allows CALCIUM into the muscle cells • Calcium binds to troponin molecules in the thin filaments causing a shape change • it is like the key opening a lock • Cross bridges form between Actin and Myosin while Calcium causes the breakdown of ATP • produces energy to move cross bridges and heat

19. The Sliding Filament Theory • YouTube - Sarcomere Contraction - Process Of Muscle Contraction With Myosin & Actin.mp4

20. Actin ratchets down the length of Myosin by forming and reforming cross-bridges • Sarcomeres get shorter causing muscle to become shorter = Muscle contraction