Transcript Slide 1
MUSCLES 1 FUNCTIONS OF MUSCULAR SYSTEM Body movement Maintain posture Respiration Produce body heat Communication Constriction of organs and blood vessels Heartbeat 2 Connective Tissue Sheaths in Skeletal Muscle 3 Figure 10.1a TYPES OF MUSCLE PATTERNS PARALLEL PENNATE CONVERGENT CIRCULAR 4 PARALLEL MUSCLE The fascicles are parallel. They are long fibers, which can contract to 75% of their length. They contract a long way, but they are relatively weak, because there are relatively few fascicles. E.g. Sternocleidomastoid. 5 Arrangement of Fascicles in Muscles 6 Figure 11.3 PENNATE PENNATE (means “feather shape”) MUSCLES: three types: UNIPENNATE; looks like half a feather. The fascicles are short, but there are more of them. They are stronger, but do not have the same length contraction ability of the parallel muscles. BIPENNATE are fascicles that insert into the tendon from both sides; they are stronger than unipennate. MULTIPENNATE are the strongest (biceps femoris). The fascicles are in multiple bundles inserting on one tendon 7 PENNATE 8 9 CONVERGENT CONVERGENT MUSCLE has more fibers than parallel, but contracts a greater distance than pinnate. E.g. Pectoralis major. 10 11 CIRCULAR MUSCLE CIRCULAR MUSCLE (Sphincter) is arranged in a circle, with a small area of tendon on the sides. It allows closure of the eyes, mouth, etc. They are not very strong, but they don’t need to be. 12 13 TERMS: ORIGIN = The region which usually doesn’t move when the muscle contracts. Look at the biceps brachii; does the shoulder move when I bend my arm? No; the shoulder = origin. INSERTION= The point of attachment that moves; bend arm, radial tuberosity = attachment. AGONIST = The main muscle for a particular action; bend arm, biceps = agonist. ANTAGONIST = Does the opposite action; bend elbow, antagonist extends. Every muscle in the body has to have an antagonist. SYNERGIST = The muscle that helps the agonist. There are several muscles that assist when the arm is bent. 14 Muscle Attachments 15 Muscle Types Skeletal: elongated Smooth: spindle shaped striated Voluntary Moves the skeleton no striations Involuntary Found in organs and lining of blood vessels Cardiac: cylindrical shaped striated 16 involuntary (only responds to direct electrical stimulation) SKELETAL MUSCLE Theses are very long fibers (biceps muscle can be 8-10 cm). They have thousands of nuclei because they start from many stem cells that fuse together into one skeletal muscle fiber. 17 Skeletal Muscle Myoblasts exist in adults, so muscle heals well. A muscle cell torn in half can regenerate. There are almost no muscle diseases for this reason (muscular dystrophy is the main muscle disease). Muscles Overview Video http://www.youtube.com/watch?v=ren_IQPOhJc 18 Skeletal Muscle: Longitudinal section In skeletal muscle fibers, there are light and dark stripes called striations, which can be seen under a microscope. 19 Skeletal Muscle ON CROSS SECTION 20 A cross section of skeletal muscle looks like bundles of circles because you are looking at cut fascicles. 21 Skeletal Muscle The plasma membrane of muscles is called a SARCOLEMMA. The cytoplasm of muscle cells is called SARCOPLASM. Muscle cells contain many mitochondria and other organelles. One type of unusual organelle found only in muscle cells is called a myofibril. They are packed in bundles and fill up most of the cell. 22 • MUSCLE MYOFIBRILS • Cylindrical organelles found within muscle cells • Contain actin and myosin myofilaments • Extend from one end of the muscle fiber (muscle cell) to the other • Contain sarcomeres joined end to end. 23 Every dark band + light band is one sarcomere 24 SARCOMERES The striations result from the internal structure of SARCOMERES within the sarcoplasm. The sarcomere is the basic structural and functional unit of skeletal muscle. The sarcomere is what contracts. 25 Actin and Myosin Sarcomere model video Sarcomeres consist of two types of myofilaments made out of protein: thin (ACTIN) myofilaments Look like two strands of beads twisted together. thick (MYOSIN) myofilaments. Both ends of a thick filament are studded with knobs called myosin heads (look like little golf clubs). 26 27 Actin Myosin Actin Myosin 28 MECHANISM OF CONTRACTION The Sliding Filament Theory Contraction results as the myosin heads of the thick filaments attach like hooks to the thin actin filaments at both ends of the sarcomere and pull the thin filaments toward the center of the sarcomere. The myosin head is like a hook with a hinge. After a myosin head pivots at its hinge, it draws the actin closer, then lets go, springs up again to grab the actin filament again, pulls it closer, and it keeps repeating this until the entire actin filament has been drawn in as far as it can go. The sites where the myosin heads hook onto the actin are called cross-bridges. 29 Sarcomere Contraction The complete process of contraction of the sarcomere takes only a fraction of a second. The actin and myosin filaments do not shorten; they merely slide past each other. The energy required is ATP. Muscle Contraction http://www.youtube.com/watch?v=CepeYFvqmk4 30 Muscle Contraction A muscle TWITCH is one single muscle fiber contraction. It takes 1/20th of a second. How is it that I can pick up and hold a chair if the fiber only contracts for 1/20th second? There are ten thousand fibers per muscle; each one contracts at different intervals, so contraction is maintained, just like tug-of-war. One person in ten can drop the rope and get a better grip because the others are maintaining the tension. 31 Motor Units A MOTOR UNIT is a single neuron and all of the muscle fibers on which it synapses. If one neuron sends a signal, only its muscle fibers contract (the motor unit). This allows for strength variations in lifting a chair vs. an eraser. For full strength, all the motor units contract. For half strength, half of the motor units contract. 32 Motor Units There are 3 motor units in this diagram; that allows for 3 different levels of contraction. The more motor units there are, the more precisely the muscle can respond. 33 Motor Units The action potential continues from one motor neuron to the next motor neuron until the last neuron lands on its target cells; in this case, skeletal muscle fibers. A single motor neuron and all the skeletal muscle fibers it innervates constitute a motor unit. A muscle in your tongue may only have a few muscle fibers innervated by a neuron to allow for precise movement. However, large thigh muscles may have as many as 1000 muscle fibers per neuron, since precision is not necessary. 34 Motor Units The muscles of the back are larger motor units (many muscle fibers per neuron). Since there are fewer motor units present (one neuron for a thousand muscle cells, we get strength, but less precision. The muscles that move the tongue have smaller motor units (one neuron for 10 muscle cells). Since there are many motor units present = less strength, more precision. 35 36 37 TETANUS TOXIN A toxin caused by a certain bacteria can cause muscle to remain contracted (in tetanus). It quickly results in death because the diaphragm and other respiratory muscles cannot function properly, and the person suffocates. The bacteria that make this toxin live deep in the soil and cannot survive in air. If you step on something that imbeds soil deeply into your tissues (like a rusty nail), you might contract the bacteria. You will need a tetanus vaccine before the toxins accumulate. 38 Muscle Tone Even when muscles are relaxed, some of their fibers are still contracting, giving the muscle some tone. Therefore, the normal state of a muscle, with some contraction, is called muscle tone. This is important in posture so you can stand upright but mostly relaxed. Muscle tone refers to the constant tension produced by muscles of the body over long periods of time. It is responsible for keeping the back and legs straight, the head held in an upright position, and the abdomen from bulging. it declines during REM sleep. 39 Muscle Tone Upper Extremity Tone VIDEO Lower Extremity Tone VIDEO 40 Motor Neurons A neuron (nerve cell) that innervates (supplies) skeletal muscle is called a motor neuron (causes the body to move). There are 2 motor neurons involved in this task. The Upper Motor Neuron has its cell body in the brain, and its axon (like a stem) lands on the cell body of the Lower Motor Neuron, which is in the spinal cord. The axon of the Lower Motor Neuron leaves the spinal cord and innervates the muscle. 41 Upper and Lower Motor Neurons (in red) Upper motor neuron Lower motor neuron 42 Muscle Tone Hypertonia Can present clinically as either spasticity or rigidity. Seen in upper motor neuron diseases, such as multiple sclerosis or cerebral palsy. Hypotonia Seen in lower motor neuron diseases (spinal cord damage and ALS/Lou Gehrig Disease) Can present clinically as muscle flaccidity, where the limbs appear floppy, stretch reflex responses are decreased, and the limb’s resistance to passive movement is also decreased. 43 Muscle Spasticity: Hypertonia Clinically spasticity is defined as velocity dependent resistance to stretch. Passively moving (the doctor does the movement) the patient’s elbow quickly will elicit spastic twitches, but passively moving elbow slowly is normal. It mostly occurs from upper motor neuron lesions (scar, tumor, or other damage), but it can also present in multiple sclerosis, which is an autoimmune condition. Can also be seen in cerebral palsy (lack of oxygen at birth). 44 Muscle Spasticity There is a difference in cause of two of the most common spasticity conditions, spastic diplegia (cerebral palsy) and multiple sclerosis. In spastic diplegia, the upper motor neuron lesion arises often as a result of neonatal asphyxia (lack of oxygen in a newborn), while in conditions like multiple sclerosis, spasticity is from multiple sclerosis, which is an autoimmune destruction of the myelin sheaths around nerve endings. 45 Muscle Spasticity Causes include Spastic diplegia (Cerebral palsy) Multiple sclerosis Spinal cord injury Stroke Test for clonus to see if spasticity is present. 46 Muscle Clonus Clonus (from the Greek for "violent, confused motion") is a series of involuntary muscular contractions initiated by a reflex. Clonus is a sign of certain neurological conditions, and is particularly associated with upper motor neuron lesions such as in spastic diplegia, stroke, multiple sclerosis, spinal cord damage. Clonus is most common in the ankles, where it is tested by rapidly dorsiflexing the foot. If the foot then jerks 5 times or more, clonus is present. A positive clonus test means the patient has spasticity, usually due to an UMN disorder. VIDEO: Ankle clonus http://www.youtube.com/watch?v=iWEJIVO85TI 47 Muscle Rigidity Unlike spasticity, rigidity is velocityindependent resistance to passive stretch. There is uniform increased tone whether the elbow is passively moved quickly or slowly. 48 Muscle Fasciculations These are small, local, involuntary muscle contractions. Fasciculations have a variety of causes, the majority of which are benign, but can also be due to disease of the lower motor neurons. Fasciculations VIDEO Tremor VIDEO 49 Muscle Fasciculations Benign causes of fasciculations include: Magnesium deficiency Diarrhea Overexertion Inadequate intake from diet (almonds are a good source of magnesium) Dehydration Fatigue A small neuron dying can also cause fasciculations. 50 Muscle Fasciculations They can also be caused by long-term use of: Benadryl (antihistamine) Dramamine (for nausea and motion sickness). Caffeine Sudafed (for allergies) Asthma medicines ADD medicines 51 Muscle Fasciculations More serious conditions causing fasciculations include Fibromyalgia Myasthenia Gravis Lyme Disease Rabies 52 Hyperreflexia We talked about hypertonia; some people have hyperreflexia. The most common cause of exaggerated reflexes is spinal cord injuries (upper motor neuron diseases). Other causes include Medication Stimulants Hyperthyroidism Electrolyte imbalance Severe brain trauma. 53 Hyporeflexia This means diminished or absent reflexes. The most common cause is lower motor neuron diseases. 54 Muscle Strength and Coordination Upper Extremity Strength VIDEO Lower Extremity Strength VIDEO Strength Evaluation using squats VIDEO Hand coordination using Rapid Alternating Movements (RAM) VIDEO 55 Muscle Contractures Muscle contractures can occur from paralysis, muscular atrophy (immobilization from a cast), muscular dystrophy, and chronic spastic conditions like cerebral palsy. Fundamentally, the muscle and its tendons shorten, resulting in reduced flexibility. Muscle contractures in tendons are caused from the fibrinogen leaking out of the fibroblasts, which turn the elastic fibers into inelastic fibers. Most treatments involve surgery, so physical therapy efforts focus on prevention of contractures. 56 Sprint Runners Why do sprint runners tire out during the last part of a fast run? Sprinting is an anaerobic activity…the oxygen requirement is quickly exceeded, so the muscle has to use anaerobic respiration to continue to contract. This requires a lot of glucose and also results in a buildup of lactic acid. Once the sprint-runner has used up the available glucose, or has produced too much lactic acid, the muscles fatigue. 57 Sprint Runners http://www.youtube.com/watch?v=MTn1v5TGK_w Oxygen Debt Anaerobic respiration produces lactic acid, which causes the painful cramps because it creates an oxygen debt. The amount of oxygen needed to replenish the supply following aerobic demand is called the oxygen debt. When you continue to breathe heavily after exercising, it means you have an oxygen debt. Muscles can do without oxygen for a while pretty well, unlike the brain. To pay back a minor oxygen debt, you just have to breathe heavily for a while. 58 EXERCISE 1. 2. 3. 4. 5. There are many physiological benefits of exercise: Improved muscular strength, endurance, flexibility Improved cardio-respiratory endurance Increased bone density and strength Relief from depression Increased HDLs 59 Hypertrophy Weight training and other exercises can cause muscles to hypertrophy (enlarge). This occurs as more myofilaments and myofibrils are produced inside a myofiber (muscle cell), causing the muscle cellto enlarge. The number of mitochondria also increases, causing additional enlargement. However, you don’t grow new muscle cells. The number of cells in a skeletal muscle remains relatively constant following birth. Myoblast stem cells don’t grow into new muscle cells; they just patch up damaged cells. Hypertrophy can happen in two ways: Increase in number of myofibrils inside a muscle cell Which causes the increase in size of individual muscle cells (myofibers) Muscle hypertrophy is greater in males due to the hormone testosterone. 60 61 Hypertrophy Eating protein does not automatically increase muscle. The average person only needs one ounce of protein a day, two if you work out. One ounce is the size of a deck of playing cards. Two ounces is like one mini hamburger. Most people eat too much meat. Fun Fact: -You use 200 muscles to take one step. 62 Fun Facts A muscle cell is about as thin as a hair. Muscles make up 1/3 of your body weight. There are 655 muscles in the body…that is three muscles per bone! We all have the same number of muscle cells. Muscles can generate 40 pounds per square inch. If all the muscles in the body were able to contract at once, they could pull 25 tons! 63 Atrophy Lack of use causes muscle ATROPHY. This happens quickly. Astronauts can lose 40% of their muscle in two weeks! It is regained quickly, too. Atrophy is a decrease in muscle size because of the decrease in myofilaments within muscle fiber. Severe atrophy involves the permanent loss of skeletal muscle fiber and the replacement of those fibers by connective tissue. Damage to the nervous system, or a severed motor nerve can cause atrophy. The muscle becomes flaccid (having no tone) . Casting a broken limb also leads to temporary atrophy. 64 Muscular Dystrophy This refers to a group of inherited muscle disorders in which skeletal, cardiac, and smooth muscle tissue degenerates and the person experiences progressive weakness and other symptoms, including heart problems. The muscle is replacement by fat and other connective tissue. 65 Muscular Dystrophy MUSCULAR DYSTROPHY This is a genetic lack of a protein called DISTROPHIN. It causes the muscle tissue to harden, inhibiting contraction, causing progressive paralysis. Duchenne muscular dystrophy is more common in males. 66 Muscle Problems Tendonitis is an inflammation of the tendon or its attachment point. It usually occurs from overuse of the muscle to which the tendon is attached. A strain is a tear in a muscle. Remember, a sprain is a tear in a ligament. A muscle strain will heal faster than a torn ligament because muscles have good blood supply and ligaments do not. 67 Treatment for Injuries: RICE Rest Ice Compression 20 minutes on, 20 minutes off Ice pack or frozen bag of peas! Ace wrap from distal to proximal Don’t leave any openings while wrapping Elevation 68 Above the heart Treatment for Injuries Ice for the first 72 hours (NO heat!) Anti-inflammatory medicines Ibuprofin, 600 mg TID (3x a day) Over the counter (OTC) pills are 200 mg Heat and massage as needed after third day. Can try a muscle stimulator too…works pretty well! 69 Muscle Spasms Muscle spasms/cramps are sudden and involuntary muscle contractions. They are painful, spastic contractions that are usually caused from overexertion. Lactic acid builds up and irritates the overused muscles, causing inflammation. If the muscle remains in spasm for longer than a few minutes, might need heat and massage to increase circulation. Avoid spasms by stretching before and after activities. For people with frequent low back spasms throughout the day, a portable muscle stimulator that clips to the belt will help a great deal. 70 Muscle stimulator to relieve muscle spasms or to prevent muscle atrophy in casts $59 http://www.m edicalproduct sonline.org/m eprondi75mu. html 71 72 $3.50 http://www.m edicalproduc tsonline.org/r ecaclel10pa. html 73 Fibromyalgia (muscle and tissue pain) Common disorder in adults, especially women Painful muscles, debilitating fatigue, sleep disturbance, and joint stiffness Many trigger points: painful lumps in muscles Treatment includes anti-inflammatory medicines, physical therapy, acupuncture, and exercise. Muscle stimulators help 74 Ganglion Cysts Ganglion cysts arise as outpouchings from fluid filled areas such as the fluid around tendon sheaths. When the fluid, called synovial fluid, leaks out from these spaces, it can become a cystic structure. Treatment is to drain the fluid with a needle, but the fluid can be jelly-like and difficult to remove, and they frequently grow back. If conservative treatments fail to correct the cyst, an operation can be done to excise the cyst. Then you do a surgery to scoop out the whole cyst, find the stalk and tie it off. 75 • Ganglion cyst 76 What is the Rotator Cuff? Rotator Cuff Injury http://www.youtube.com/watch?v=-tx2SqWz3BY How do rotator cuff injuries occur? http://www.youtube.com/watch?v=t6FCBBijROo What is an MRI? http://www.youtube.com/watch?v=H0adTNhzGxU How does a CT scan work? http://www.youtube.com/watch?v=81PeTqmtzjk 77 AGING With aging, fibrous connective tissue replaces some muscle fibers, causing decreased strength. As people age, the number of muscle fibers decreases, and new ones cannot be added. 78 FUN FACTS ABOUT STRENGTH The strongest humans can lift about 3 times their own body weight, but the average gorilla can lift 10 times its own body weight! Gorillas can lift 4,600 pounds. But the strongest creature is the ant. If you had the strength of an ant, you could lift over your head and carry 6,600 pounds. The flea, however, can jump up to 200 times its own height. This is equivalent to a man jumping the Empire State Building in New York. Elephants are the only animals that cannot jump! 79 80 Smooth and Cardiac muscle 81 SMOOTH MUSCLE CELLS These are found around internal organs (intestines, uterus, blood vessels). They are involuntary and not striated. When smooth muscle contracts around the intestines, the movement is called PERISTALSIS. 82 SMOOTH MUSCLE CELLS • • • • • Smooth muscle cells are small and spindle shaped, usually with one nucleus per cell. They contain less actin and myosin, and the microfilaments are not organized into sarcomeres. As a result, smooth muscle cells are not striated. They contract more slowly and do not develop an oxygen debt. Smooth muscle cells can spontaneously generate action potentials that cause the cell to contract. 83 84 Smooth Muscle 85 CARDIAC MUSCLE CELLS Only found in the heart. The cells are involuntary (like smooth muscle) and striated (like skeletal muscle). They have intercalated discs which join each cell. 86 Cardiac Muscle 87 Cardiac Muscle Cardiac cells are long, striated, and branching, with one nucleus per cell. The actin and myosin myofilaments are organized into sarcomeres, but not as uniformly as in skeletal muscle. As a result, cardiac muscle cells are striated, but not as distinctly as skeletal muscle. Cardiac muscle is involuntary and does not fatigue. 88 Cardiac Muscle Cardiac muscle cells are connected to one another by intercalated discs which facilitate action potential conduction between themselves. This allows them to function as a unit and they all contract together. Contraction of cardiac cells is influenced by hormones, such as epinephrine. 89 Cardiac Muscle As one cell contracts, the action potential goes through all the cells, and they all contract as a unit. That’s why the heart contracts all at once. It has an intrinsic beat. The cells contract on their own, without a signal. Even if you chop a heart up, each piece will beat by itself! 90 Summary Skeletal muscle Smooth muscle Cardiac muscle Many One One Involuntary or voluntary? Voluntary Involuntary Involuntary Striated or non-striated Striated Non-striated Striated Number of nuclei per cell Where is it found? Inserts onto bones Intestines, blood vessels, other organs Myocardium of heart MUSCLE Adductors Biceps femoris Brachialis Deltoid Gastrocnemius Gluteus medius Gracili Infraspinatus Internal Oblique Latissimus dorsi Pectoralis major Pectoralis minor Psoas major Quadriceps femoris Rectus abdominis Semimembranosus Semitendinosus Serratus anterior Supraspinatus Tensor fascia latae Teres major Trapezius Triceps brachii BEEF CUT Top (inside) round Bottom (outside) round Shoulder rose Outside chuck (chuck) Round heel Top sirloin Inside round cap Top blade Sirloin butt Ribeye; Loin eye Brisket Brisket Tenderloin; filet mignon Knuckle; Sirloin tip Flank Top (inside) round Eye of round Boneless short ribs Chuck tender Tri-tip Shoulder Tender Outside chuck Ranch Cut Muscle Musician • http://vimeo.com/47875656