Survey
* Your assessment is very important for improving the work of artificial intelligence, which forms the content of this project
Download Skeletal Muscles
Document related concepts
no text concepts found
Transcript
Biomedicine: Human Sciences Lecture 3: Muscular System 1 Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. Learning Outcomes In today’s topic you will learn: Ø Have knowledge and understanding of the structure, function, types of muscles in the human body. Ø Be able to identify major muscles of the body and recognise their functions Ø Knowledge of common muscular pathologies. http://www.endoszkop.com/ Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 2 Function 1. Movement –a result of muscular contraction and relies on the integrated functioning of the muscles, bones and joints. 1. Posture - stabilising joints, posture and balance through continual partial contraction of muscles. 2. Heat production - This process is called thermogenesis and helps maintain normal body temperature. (Shivering = involuntary contractions of the skeletal muscle) 3. Glycogen storage – energy (glycogen) and oxygen 4. Movement of substances: – Sphincters prevent out-flow from hollow organs (stomach and bladder). – Smooth muscle in blood vessel walls helps control blood flow – Smooth muscle contractions move food through the gastrointestinal tract (GIT), urine through the urinary system and gametes through the reproductive system. – Skeletal muscle: diaphragm – draws air into airways/lungs Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 3 Muscle Properties 1. Contractility – ability to contract (shorten). 2. Excitability – the ability to generate an electrical current. Nerve impulses also called action potentials are triggered by electrical signals or chemical stimuli (neurotransmitters, hormones) which causes the muscles to contract. 3. Extensibility – ability to stretch without being damaged. 4. Elasticity – can return to it’s original length and shape after contraction or extension (spring) http://cinak.com/ Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 4 Muscle Properties http://cinak.com/ Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 5 Muscle Types Striated = From Latin ‘stria’ meaning furrow 1. STRIATED - cells are aligned in parallel bundles, so that their different regions form stripes visible with a microscope. • SKELETAL: voluntary muscle attached to bone & cartilage. • CARDIAC: involuntary heart muscle = autorhythmic (auto = automatic, rhythmic = recurring regularity). http://www.kidsbiology.com/human_biology/muscles2.php 2. NON-STRIATED - randomly arranged cells (no stripes visible) • SMOOTH: involuntary muscles in the walls of hollow organs, blood vessels etc. (i.e pupil constriction/dilation). Smooth muscle does not tire http://www.mhhe.com/biosci/ap/histology_mh/nonstria.html Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 6 Muscle Types https://prezi.com/br7nbxpsahcs/tissue-types-sneed/ http://www.sciencelearn.org.nz/ Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 7 Muscle Anatomy What might happen to muscles at puberty? • Muscle is made up of cells called muscle fibres (myocytes) • Muscle fibres are formed from the embryonic fusion of myoblasts so each muscle fibre (skeletal muscle cell) has many nuclei. • Once mature (fused) they can no longer undergo mitosis. • Limited regeneration – by satellite cells. my(o) is Greek, of or relating to muscle cyt(o) is Greek for cell blast(o) is Greek, for germ / bud hyper is Greek for beyond normal trophy is Greek for development • This means that the number of skeletal muscle fibres each person has is set at birth • In contrast muscles can develop by: • Hypertrophy = enlargement of existing fibres, induced by strength training. • Atrophy = wasting. Associated with immobility, inactivity, injury and old age. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 8 Skeletal muscle • 640 skeletal muscles in the body • Comprises on average 40% of our body weight • Under voluntary control (for the most part) • Permits voluntary movement: • Motion and posture • Speech (larynx, lips, tongue) • Breathing • Covered by fascia – dense sheet of connective tissue that organises muscle, secures it to skin and provides stability. Collagen is a major component. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 9 Video: Muscular Dissection Lesson 1: Movement https://www.youtube.com/watch?v=kbyUzsHP3Po 10 Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. Skeletal Muscle Hierarchy http://moodle2.rockyview.ab.ca/mod/book/view.php?id=52001&chapterid=25486 Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. Skeletal Muscle Cells • Sarcolemma = plasma membrane of a muscle cell • Transverse tubules = tubes extending from the plasma membrane surface into muscle cell. • Sarcoplasm = muscle cell cytoplasm. Arranged as sarcoplasmic reticulum (SR). A tubular network that circulates cytoplasm. sarco is Greek for muscular plasm – Greek for plasma – a semifluid translucent fluid my(o) is Greek relating to muscle globin from Latin globus - a sphere. Globin in biology is protein fibril is Latin relating to fibre/filament • Within the SR there are tiny sacs called terminal cisterns (which store calcium) • Myoglobin = red coloured oxygen binding proteins present in sarcoplasm. • Many mitochondria – located close to myoglobin 12 https://www.studyblue.com/notes/note/n/muscle-tissue/deck/15713823 Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. Skeletal Muscle Cells • Action potentials travel through the sarcolemma and transverse tubules spreading through the muscle to cause contraction. • Myofibrils are contractile threads arranged in a striated pattern: • Each myofibril is surrounded by a network of sarcoplasmic reticulum. • Made up of smaller filaments called myofilaments: • Made up of protein molecules called actin (thin) and myosin (thick). • Overlap to form sarcomeres. • ‘A bands’ = dark area where myofilaments overlap. myo = muscle fibril is Latin relating to • ‘I bands’ = light area of only actin filaments fibre/filament Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 13 Repeated banding pattern forms striations One sarcomere sarco is Greek for muscular mere from Latin meaning part H = Myosin only A = Actin and Myosin I = Actin only https://www.studyblue.com/notes/note/n/other-structural-components-of-skeletal-muscle/deck/1411879 Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 14 Muscle Connective Tissues • Muscles are surrounded by lots of connective tissue • Collagen fibres in connective tissue assist to intermingle with other structures - tight connections transfers force better. • Vessels pass through connective tissue to deliver blood. 1. Epimysium: Wrapped around entire muscles. Anchor point for fascia/tendons/ligaments. 2. Perimysium: Surrounds groups/bundles of 10-100 muscle fibres, forming fascicles 3. Endomysium: Thin sheath around individual muscle cells. epi = ‘upon’ or ‘over peri = ‘around’ endo = ‘within’ mysium = muscle Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 15 http://droualb.faculty.mjc.edu/course%20materials/elementary%20anatomy%20and%20physiology%2050/lecture%20outlines/skeletal_muscle_physiology.htm Muscle Connective Tissues epi- ;Greek, before, upon, on peri-; Greek, denoting something with a position 'surrounding' endo-; Greek; denotes something as 'inside' or 'within‘ my(o) is Greek for relating to muscle http://biologyonline.us/Online%20Human%20Biology/Northland/HB%20Lab/HB%20Lab%205/29.htm Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 16 Neuromuscular Junction (NMJ) Neuro – Greek for pertaining to nerves / muscular- pertaining to muscle • Neuromuscular junction: the meeting point (synapse) where motor neurons meets motor end plate (muscle fibre). • The axon of the neuron divides into synaptic end bulbs. Within synaptic end bulbs there are vesicles containing the neurotransmitter Acetylcholine • Motor end plate: termination of motor neurons in minute pads on the muscle fibre. • Acetylcholine crosses the junction gap and opens post-synaptic channels (sodium) triggering action potential to continue along the sarcolemma. • Motor unit: 1 nerve and its corresponding muscle fibres (between 1-1000) • Strength of muscle contraction depends on the number of motor units in action at one time as well as the frequency of nerve impulses at which they are stimulated. • When a motor unit responds to a single nerve impulse by contracting and relaxing we call this a ‘twitch’. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 17 Neuromuscular Junction (NMJ) Video: Neuromuscular Junction www.youtube.com/watch?v=CLS84OoHJnQ https://online.science.psu.edu/biol141_wc/node/7548 Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 18 Sliding Filament Theory Contraction: sarco is Greek for muscular plasm – Greek for plasma – a translucent fluid 1. Action potential arrives at the neuromuscular junction. 2. The action potential spreads along the sarcolemma and transverse tubules in to the muscle cell releasing calcium (Ca2+) from storage (sarcoplasmic reticulum) 3. Calcium & adenosine triphosphate (ATP) trigger myosin to bind to the actin filament next to it so that the filaments slide over each other thereby shortening the fibre (exposes heads) • If enough fibres are stimulated at once the whole muscle will contract Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 19 Sliding Filament Theory http://www.thealevelbiologist.co.uk/the-sliding-filament-theory-of-muscle-contraction Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 20 Sliding Filament Theory http://legacy.owensboro.kctcs.edu/gcaplan/anat/notes/api%20notes%20j%20%20muscle%20contraction.htm Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 21 Sliding Filament Theory Relaxation: 1. Nerve stimulation stops: no action potential 2. Using magnesium (Mg) & ATP, Calcium is actively transported (pumped back) into storage, breaking the actin & myosin bond. 3. Actin & myosin slide back into starting positions, lengthening the fibre again = relaxation. • Magnesium makes muscle fibres less excitable and prevents myosin binding with actin. Video: Sliding Filament www.youtube.com/watch?v=hr1M4SaF1D4 Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 22 Muscle Metabolism “The breakdown (or production) of compounds to produce energy in the form of ATP for all bodily functions” • “How we transform the food (glucose, fatty acids and amino acids) we eat into energy” • Muscles require a good blood supply • Blood provides oxygen & nutrients as well as removing waste • Muscle contraction requires large amounts of ATP • ATP is derived from breakdown of carbohydrates (glucose), fats and proteins. • ATP is converted into energy & heat. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 23 Muscle Metabolism Muscle fibres have three ways of producing ATP: ATP = adenosine triphosphate 1. Creatine phosphate (unique to muscles): 15 seconds An- is Greek without • Resting muscles store excess ATP as creatine phosphate Aerobic = with oxygen • 3 - 6x more creatine phosphate in a muscle cell than ATP. • During muscle contraction when ATP is used up, creatine phosphate is used to regenerate the ATP so contraction can be sustained for longer 2. Anaerobic respiration: 30 seconds of intense muscle activitiy • Absence of oxygen • Net production of 2 ATP + lactic acid • Occurs via glycolysis (breaking down of glucose) 3. Aerobic respiration: hours of activity • With oxygen • Produces 38 ATP (36 net production) + water + carbon dioxide (CO2) – glucose, fats & protein metabolism Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 24 Types of Skeletal Muscle my(o) is Greek, of or relating to muscle globin from Latin globus - a sphere. Globin in biology is protein White muscle fibres Less myoglobin Red muscle fibres Lots of myoglobin more mitochondria greater blood supply Appear lighter (e.g. breast meat on a chicken) Appear darker (e.g. leg meat on a chicken) Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 25 Types of Skeletal Muscle Fibre Type Fibre name Type I Fibres SLOW TWITCH Slow oxidative Type IIa fibres FAST TWITCH Fast oxidative – glycolytic Type II b fibres FAST TWITCH Fast glycolytic Diameter Small Intermediate Large Colour Dark red (high myoglobin & mitochondria) Dark red (high myoglobin, capillaries & GLYCOGEN) White (low / no myoglobin, fewer capillaries & mitochondria) Type of Respiration Aerobic respiration (oxidative metabolism generates ATP) Aerobic respiration (oxidative metabolism generates ATP) Mainly Anaerobic respiration Power Least powerful (major storage fuel is triglycerides) Medium power (major storage Most powerful (major storage fuel fuel is creatine phosphate & is glycogen) creatine phosphate & glycogen) Contraction type Slowest contraction Faster contraction Quick & strong Duration Longest duration Resistant to fatigue Fatigue quickly Good for: Endurance Walking & sprinting Weight training / power training Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 26 Types of Skeletal Muscle • Most skeletal muscles are a mixture of muscle fibres in varying proportions Ø Shoulders /arms: high amount of fast glycolytic 50% are Slow Ø Legs & back (postural): fast oxidative-glycolytic and slow oxidative Oxidative • Relative ratio SO:FG fibres (and tendon/ligament elasticity) is genetically determined accounting for individual differences in physical performance. • Proportions vary depending on the individual and their training/lifestyle • Exercise can cause muscle fibres to change: Ø Endurance training converts fast glycolytic to fast oxidative – glycolytic ( diameter and no. mitochondria, blood supply) Ø Strength training increases the size & strength (hypertrophy) of fast glycolytic fibres hyper is Greek for beyond normal trophy is Greek for development glyco- sugar -lytic from Latin to release Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 27 QUIZ: What am I? 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. I am a red protein that binds oxygen in myocytes I am an invagination into a muscle cell to assist in action potential conduction I am the larger of the two proteins that form the myofilament structure I am connective tissue that surrounds the entire muscle and anchors it to other structures I am the molecule/structure that stores ATP in myocytes Slow oxidative muscle fibres are this colour I am the largest type of muscle fibre, with low levels of myoglobin, but large amounts of glycogen stored that can be used for respiration I am a method of ATP production that produces a net of 36 ATP molecules from 1 glucose I am a type of cell in skeletal muscles that provides some regeneration capacity I am the structure inside a muscle cell that stores calcium Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 28 Skeletal Muscles: Face • The names of most skeletal muscles describe some of their key features e.g. size, shape, action, number of origins, location, sites of origin or insertion. Name Function /Action Occipitofrontalis Occipit – of the occiput (back of head) Frontalis = front Raises eyebrows Orbicularis oculi Orbi = circular, Ocul = eye Closes eyes Orbicularis ori Orbi = circular, Or = mouth Closes/pouts lips Masseter Mastication i.e. elevates & protrudes mandible / closes the jaw Temporalis Mastication Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 29 Skeletal Muscles: Face Occipitofr ontalis Orbicularis Oculi Te mp Orbicularis Oris ora lis Masset er Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 30 Skeletal Muscles: Neck Name Sternocleidomastoid: Sterno = sternum Cleido = clavicle Mastoid = mastoid process of the temporal bone Function /Action Turns & tilts head Trapezius: Pulls head backwards. Trapezi = trapezoid shape Elevates, retracts and depresses shoulders Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 31 Skeletal Muscles: Back Name Function /Action Supraspinatus (one of the rotator cuff muscles) Initial abduction of shoulder Psoas Hip flexor: pulls thigh towards trunk Latissimus Dorsi Latissimus = widest Dorsi = of the back Extends, adducts & medially/internally rotates arms Quadratus Lumborum Quad = four, Lumbo = lumbar region Attached to 4 lumbar vertebrae Bending backwards (vertebral extension) Bending sideways (lateral flexion) Erector Spinae (muscle group) Erector = erect, Spinae = spine Extension of the vertebral column Keeps spine upright Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 32 Skeletal Muscles: Back Erector Spinae Latissimus Dorsi Psoas Quadratus Lumborum http://www.corpshumain.ca/en/muscle_dos_en.php http://www.musclesused.com/erector-spinae-2/ http://corewalking.com/psoas-quadratus-lumborum/ Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 33 Skeletal Muscles: Chest & Abdomen Name Function /Action Pectoralis Major Pector = chest, Major = largest Attaches from clavicle & sternum to humerus Rectus Abdominis Rectus = fascicles parallel to midline Abdominis = of the abdomen Attaches from pubis to lower sternum and ribs Draws arms forward: Shoulder flexion & adduction Medial rotation Transversus Abdominis Transversus = across Abdominis = of the abdomen Compresses abdominal organs Increased IAP Internal & External Obliques Internal = inner, external = outside, Rotation, bending sideways Vertebral flexion: bending forward (“crunches”) Increased Intra-abdominal pressure (IAP) Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 34 Skeletal Muscles: Chest & Abdomen Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 35 Respiratory Diaphragm Name Diaphragm Attaches to the lower 6 ribs, sternum and upper lumbar spine Function /Action When contracts, it descends into the abdominal cavity, increasing the space for air to enter in the lungs (moves down concentration gradient) http://www.inpursuitofyoga.com/blog/2015/3/11/chest-breath-vs-belly-breath Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 36 Skeletal Muscles: Arm Name Function /Action Deltoid Attaches from the scapula, acromion and clavicle to the humerus Flexion, abduction & extension of shoulder joint Biceps Brachii Biceps = two heads, Brachii = arm Attaches from the scapula to the radius Stabilizes shoulder joint, flexion & supination of forearm Triceps Brachii: Triceps = 3 heads of origin – 2 on humerus, 1 on scapula Brachii = arm Arm adduction, extends elbow Flexor Carpi Ulnaris Attaches from the humerus to the carpal bones Flexes the hand at the wrist joint (supination) Ulnar deviation (adducts) Extensor Carpi Radialis (Longus & Brevis) Extensor = increase angle, Carpi = wrist In Extend the hand at the wrist joint Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 37 Skeletal Muscles: Arm Deltoid Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 38 Skeletal Muscles: Legs Name Function /Action Gluteus Maximus Glute = buttock, Maximus = largest Attaches from the ilium (pelvis) to the femur External rotation, abduction and extension of the hip joint Gluteus Medius Attaches from the ilium (pelvis) to the femur Abducts leg, Stabilises pelvis Hamstrings: 3 separate muscles 1.Biceps Femoris 2.Semi-membranosus 3.Semi-tendinosus Rectus Femoris (One of 4 quadricep muscles) Attaches from the ilium (pelvis) to the tibia (via patella ligament) Bend knee (Flex knee) Flexes hip Extends knee “kicking a football” Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 39 Skeletal Muscles: Legs Name Function /Action Thigh Adductors Attaches from the pubis to the femur Squeeze the thighs together Tibialis Anterior: Front of tibia Attaches from the tibia to the metatarsals Dorsiflexion and inversion of the foot (& supports medial arch of foot!) Soleus Attaches from the posterior tibia & fibula to the calcaneum (heel bone) Plantar flexion of the foot at the ankle. Stabilising ankle Gastrocnemius Gastro = belly, cnem = leg Attaches from the femur to the calcaneum (heel) Flexes leg at the knee Plantar flexion of foot Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 40 Skeletal Muscles: Legs Gluteus Maximus & Minimus Rectus femoris The hamstrings.. https://healingbyyang.com/low-back-pain/ http://www.dailybandha.com/2014/06/the-rectus-femoris-muscle-in-yoga.html http://www.footmechanicspodiatry.co.nz/problems/leg-pain/hamstring-tear/ Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 41 Skeletal Muscles: Legs Soleus Adductor longus Gastrocnemius (deep to the gastrocnemius) Tibialis Anterior 42 Skeletal Muscles SOURCE: http://www.e-missions.net/cybersurgeons/?/musc_teacher/ Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 43 Skeletal Muscle Mechanics • Tendons attach the muscle to bone (periosteum) • Fleshy part of a muscle is called the belly • When tendons span across a joint they can produce movement (i.e. flex or extend the joint). http://imgarcade.com/1/triceps-origin-and-insertion/ • When fibres contract the muscle becomes thicker & shorter. • This exerts a force on the tendons which pull on bones producing movement. • Unlike ligaments, tendons are inelastic. Allowing the full force of muscle contraction to be transferred onto the bone. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 44 Skeletal Muscle Mechanics • When skeletal muscle contracts it pulls one articulating bone towards a stationary bone. • Some sources describe muscle attachment points as origins and insertions. However, due to debate as to which point is what, they are now often simply referred to as attachments. • Muscles that move a body part often do not cover that body part e.g. bicep – moves forearm. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 45 Skeletal Muscle Mechanics • Movements are the result of several skeletal muscles acting as a group. • Muscles can be prime movers, antagonists, synergists and fixators - depending on the movement. • Most skeletal muscles are arranged in antagonistic pairs on opposite sides of the joint. • Depending on the movement one muscle is the prime mover, the other the antagonist. • A synergist muscle assists the prime mover in it’s action e.g. when flexing the bicep, the brachialis also helps by pulling the ulna towards the humerus. • A fixator is a muscle that keeps the origin (anchor) bone stable while a prime mover contracts. Mostly found within the hip and shoulder joints. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 46 Skeletal Muscle Mechanics Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 47 Cardiac Muscle myo = muscle cardium = heart Inter = between calate = ‘to proclaim’ http://sciencelearn.org.nz/Contexts/Sporting-Edge/Sci-Media/Images/Cardiac-muscle • Specialised muscle only found in the heart. It forms the myocardium • Fibres are striated http://www.cytochemistry.net/microanatomy/muscle/striated_cardiac_muscle.htm • Intercalated discs: This interconnection of fibres allows contraction to spread from cell to cell like a wave. Unique to cardiac muscle. • Has endomysium & perimysium but no epimysium • More and larger mitochondria, less sarcoplasmic reticulum • These fibres have a branched shape, so each cell is in contact with 3-4 other cells http://bio1152.nicerweb.com/Locked/media/ch40/muscle-cardiac.html Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 48 Cardiac Muscle • Cardiac muscle stays contracted 10-15 times longer than skeletal muscle – calcium channels stay open for longer. • Cardiac muscle contracts when stimulated by it’s own autorhythmic muscle fibres (about 75 times a minute at rest). auto = automatic rhythmic = recurring regularity What is another input affecting the rate of cardiac muscle contraction? • Under involuntary control • Cardiac muscle depends mainly on aerobic respiration – requires a constant supply of oxygen. • Can also use lactic acid to produce ATP Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 49 Smooth Muscle • Found in walls of blood vessels, airways, hollow organs (i.e. stomach), as well as the iris and arrector pili in the skin. arrector = Latin for ‘to raise’ pili = latin for Hair • Used to change diameter, shape or orientation of the tissue. • Under autonomic nervous system control (involuntary) • Also contracts in response to hormones, paracrine (cell-to-cell) signalling, and local chemical agents. http://io9.gizmodo.com/5966571/why-do-your-pupils-get-larger-when-youre-on-drugs Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 50 Smooth Muscle • Each fibre is just 30 - 200 micro-metres long with a single nucleus (central) • Non-striated: filaments are not arranged into orderly sarcomeres – giving it a smooth appearance. • Filaments are attached to structures called dense bodies (similar function to Z-discs in skeletal muscle) • During contraction the dense bodies are pulled closer together by the filaments causing the muscle to shorten & twist like a corkscrew. • No T-Tubules and small amount of SR http://medicalterms.info/anatomy/Smooth-Muscle/ Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 51 Smooth Muscle Types 1. Visceral / single unit: • Found in the walls of vessels and hollow viscera e.g. stomach, arterioles, veins & venules, bladder etc. • Auto-rhythmic • Fibres connected by gap junctions to allow action potential to spread through the muscle. • One stimulus causes contraction of many adjacent fibres together - functioning as a single unit. 2. Multi unit: • Found in walls of large arteries & airways; iris & ciliary body that focuses lens of the eye and in arrector pili muscles in hair follicles. • Fibres are stimulated individually & operate independently from each other. https://www.studyblue.com/notes/note/n/muscle-physiology/deck/11561636 Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 52 Smooth Muscle https://uk.pinterest.com/pin/210191507584664470/ http://flylib.com/books/en/2.953.1.41/1/ Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 53 Smooth Muscle PROPERTIES: • Slower and longer contractions – takes longer for calcium to get in and out of muscle cells (no T tubules). • Shorten and stretch more than skeletal muscle. • Produce ‘Stress-relaxation response’ – allow organs such as stomach and bladder to expand when filled, causing a contraction in order to carry contents. • Continues partial contraction/tonicity (important for blood pressure regulation) CONTRACTION in response to: • Action potential from the autonomic nervous system. • Stretching • Hormones e.g. adrenaline • pH, O2 and CO2 levels, temperature, ion concentration what effect does adrenaline have on smooth muscle in airways and blood vessels? Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 54 Muscle Types Have a go at adding more comparisons to this table… Skeletal Cardiac Smooth Voluntary Involuntary Involuntary Striated Striated Non-striated Multinucleated Single nucleus Single nucleus Contains T tubules Contains T Tubules No T Tubules Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 55 Muscle Regeneration hyper is Greek for beyond normal trophy is Greek for development -plasia; Greek, formation or development Skeletal Muscle • Cells can’t divide! • Growth occurs by hypertrophy - enlargement of existing cells. • Limited regeneration by satellite cells (muscle precursor cells) – when damage occurs, they divide slowly & fuse with existing fibres to assist muscle repair. Smooth Muscle • Can undergo hypertrophy. • Can also undergo hyperplasia - new muscle cells can be generated from pericytes - stem cells in capillaries & veins. peri- is Greek for 'surrounding' • Some areas retain capacity for division eg. Uterus cyto is Greek for cell Cardiac Muscle • Can regenerate under certain circumstances (cardiac stem cells in endothelium). • Can also hypertrophy – enlarged hearts.(athletes and heart disease) Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 56 Homeostasis Within all body systems muscle tissue: • Produces movement. • Stabilises body position. • Move substances within the body. • Produces heat to help maintain body temperature. Integumentary system (skin) – Facial expression. – Muscle action increases blood flow to skin. Skeletal system – Movement. – Joint stability. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 57 Homeostasis Nervous system • Muscle carries out commands of the nervous system. • Shivering – generate heat and raise body temperature. Endocrine (glands & their secretions – hormones) • Exercise can improve action of some hormones e.g. insulin • Muscle protects some endocrine glands. Cardiovascular • Cardiac muscle pumps heart. • Smooth muscle in blood vessel walls controls blood flow. • Muscle contraction in legs helps return blood to heart. • Exercise leads to hypertrophy of cardiac muscle = increased efficiency. • Lactic acid produced in skeletal muscle can be used to make ATP in the heart. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 58 Homeostasis Lymphatic (the interconnected system of spaces and vessels between body tissues and organs by which lymph circulates throughout the body) • Muscle protects lymph nodes and vessels. • Promotes lymph flow. • Exercise can increase or decrease immune response. Respiratory (organs, collectively, concerned with breathing / respiration) • Respiratory muscle facilitate airflow in and out of lungs. • Smooth muscle adjusts airway size. • Skeletal muscle in larynx controls air flow past vocal cords – changes voice. • Coughing and sneezing – clears airways. • Exercise improves breathing efficiency. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 59 Homeostasis Digestive • Skeletal muscle protects and supports digestive organs. • Chewing and swallowing. • Smooth muscle sphincters control volume of GIT organs. • Smooth muscle in intestinal wall helps mix contents and move it through digestive system. Urinary • Smooth muscle sphincter and smooth muscle in. • Wall of bladder control stored and release of urine. Reproductive • Skeletal and smooth muscle contractions eject semen. • Smooth muscle contraction propel egg along uterine tubes, control menstrual flow and expel baby from uterus in childbirth. • Skeletal muscle contractions are associated with orgasm. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 60 Activity • Get into groups of 3. Choose 1 person to model. • Please identify the following muscles on the body surface: 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. Sternocleidomastoid Trapezius Pectoralis major Rectus abdominis Gluteus maximus Deltoid Triceps brachii Rectus femoris Tibialis anterior Gastrocnemius Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 61 Muscle Pathologies: Muscle Fatigue and Shortening Muscular Fatigue • Muscle fibres can fatigue if overused • Common in sports, occupational overuse and poor posture • Cell respiration becomes anaerobic and by-products such as lactic acid can cause pain Muscle Shortening • If a muscle is continuously contracted, the actin-myosin filaments remain attached • Chronic muscle contracture causes muscle fatigue but also places a strain on the muscles skeletal attachments • For example, a ‘stressed’ individual commonly sustains prolonged contraction of the upper trapezius muscle fibres. As this muscle attaches to the cervical vertebrae, this may cause a strain of these joints and possibly even lead to headaches http://www.popsugar.com/fitness/Relax-Already-Stiff-Neck-Shoulders-Gone-1845331 Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 62 Muscle Strain and Tear MUSCLE STRAIN: • Over-stretching of muscle fibrils or the tendon. Occurs when a • • • • • joint is forced beyond its normal range. The muscle remains whole Blood supply to muscle is still sufficient to provide good healing Activated satellite cells divide slowly and fuse with existing fibres Commonly call strains "pulled" muscles. Hamstring and back overstraining injuries are common MUSCLE TEAR: • More significant • The muscle tears - no longer whole! • Can cause local separation of the tissue & defective blood supply. • Preventing natural complete healing. • Complication: muscular fibrosis Why do muscle tears often cause bruising? http://triathlete-europe.competitor.com/2011/11/07/expert-advice-did-i-pull-or-tear-a-muscle Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 63 Muscle Strain and Tear TREATMENTS: • RICE: Rest, ice, compression, elevation • Herbal medicine (pain, inflammation, connective tissue repair), acupuncture, homeopathy (arnica), nutritional support (anti-inflammatory & tissue repair). • If torn, avoid heat, exercise, massage http://triathlete-europe.competitor.com/2011/11/07/expert-advice-did-i-pull-or-tear-a-muscle Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 64 Impingement Syndrome • The rotator cuff tendons connect the humerus and scapula. Together the group of muscles abduct and rotate the shoulder Syndrome: a group of symptoms that indicates or or characterises a disease • The space between the humeral head and the roof of the shoulder (acromion) is called the sub-acromial space. This contains one main bursae and the rotator cuff tendons. • These tendons and/or bursae can become inflamed and torn • Normally, when moving the shoulder, the structures have to maneuver intricately to prevent impingement. • If the tendons or bursae become inflamed/damaged, these movements can be painful http://www.ortho-md.com/procedures/subacromial_decompression.html Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 65 Impingement Syndrome: Rotator Cuff Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 66 http://www.mayoclinic.org/diseases-conditions/rotator-cuff-injury/home/ovc-20126921 Impingement Syndrome CAUSES: • Overuse & working with the arms raised overhead • More common with increasing age as blood supply is poor and the tendons degenerate • Positional fault – when the head of the humerus does not sit perfectly in the socket • Bone spurs - can reduce the space available for the bursa and tendons to move under the acromion. • Oddly sized acromion resulting in reduced space. http://www.parkclinic.com.au/home/conditions-treatment/shoulder/shoulder-impingement/ Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 67 Impingement syndrome SIGNS & SYMPTOMS: • Shoulder ache in early stages • Pain, mostly when abducting the shoulder or rotating (ie. Reaching into back pocket) • Painful arc of movement • A catching sensation is felt on lowering the arm. • Weakness and inability to raise the arm may indicate rotator cuff tear. http://www.southmountainrehab.com/extra/news/shoulder_impingement_syndrome.php Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 68 Impingement syndrome TREATMENT: • Manual therapy, exercise • Cortisone injection, anti-inflammatory drugs, surgery ALTERNATIVE TREATMENT: • Herbal medicine, acupuncture, homeopathy (arnica), nutritional support (anti-inflammatory). Video: Shoulder Impingement: www.youtube.com/watch?v=vARsKXb7wNc Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 69 Fibromyalgia Fibro = fibrous tissue -algia = painful condition myalgia = muscle pain • Widespread muscular and connective tissue pain, joint stiffness and fatigue (a chronic pain syndrome) • Often accompanied by multiple, unexplained symptoms, anxiety, depression and functional impairment of daily activities. • An absence of objective findings on physical examination and usual clinical investigations (makes it still a controversial diagnosis) • Has a neurophysiologic basis, characterised by abnormalities in pain processing by the central nervous system (CNS). • A form of “Central allodynia”: pain perception to stimulus not normally painful. Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 70 Fibromyalgia Criteria for diagnosis: pain on palpation must be present in at least 11 of the 18 points. The patient experiences pain at tender points at decreased threshold compared to ‘control’ patients But… Biopsy: shows no tissue specificity EMG: no specific changes in muscle tone Drug studies: no benefit of NSAIDS or steroids over placebo but significant benefit of SSRI/SSNRI http://www.home-health-care-physical-therapy.com/Fibromyalgia-Tender-Points.html Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 71 Fibromyalgia Suspected causes and triggers • Stress/trauma (neuroendocrine / Limbic system) • Most common in women:men (15:1) aged 25-50 years. • Sleep dysregulation • Post viral / chronic toxic load • Serotonin and noradrenaline deficiencies • High levels of substance P (nerves more sensitized to pain) http://www.durbanrheumatologist.co.za/fibromyalgia.php Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 72 Fibromyalgia SIGNS & SYMPTOMS: • Pain that results from gentle pressure at specific “tender spots”. • Generalised tenderness & muscle contracture • Debilitating fatigue & sleep disturbance • Difficulty with swallowing, bowel & bladder function, IBS, numbness & tingling • Anxiety and depression • Not all people with fibromyalgia experience all symptoms. http://www.fibrocenter.com/fibromyalgia-symptoms Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 73 Fibromyalgia ALLOPATHIC TREATMENT: • Medications (anti-depressants however these do not address the cause or cure the dysfunction. Often leads to high dependency on the medications) • Patient education, exercise, help groups, CBT, counselling ALTERNATIVE TREATMENT: • Acupuncture, herbal medicine, homeopathy, nutritional (nerve and muscular function, antiinflammatory). http://www.doctortipster.com/2480-fibromyalgia-causes-symptoms-risk-factors-and-treatment.html Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 74 Muscular Dystrophies • Group of inherited muscular diseases that cause degeneration and weakness of muscles • Many types CHARACTERISED BY: • Progressive skeletal muscle weakness/atrophy • Death of muscle cells & tissue (final stages). • Defects in muscle proteins Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 75 Myasthenia Gravis • Autoimmune disease characterised by fluctuating muscle fatigue & weakness. • A disease of the neuromuscular junction (NMJ). my(o)-; Greek, of or relating to muscle -asthenia; Greek, weakness What is an autoimmune disease? • Antibodies block acetylcholine receptors on the motor end plate preventing a nerve impulse being sent to muscle fibres. • Muscle becomes weaker, until it cannot function. • Most common in women, age 20-50. • Muscles of face & neck are commonly affected. https://app.emaze.com/@ACCFICOW/Myasthenia-Gravis Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 76 Myasthenia Gravis SIGNS & SYMPTOMS: • Weakness of ocular muscles, double vision and ptosis Ptosis = from Greek word “Fall” It is drooping of the upper eye lid • Weakness in facial muscles (expressions) which spreads to the proximal limbs • Difficulty with speech, chewing and swallowing • Death may result from failure of the respiratory muscles. http://www.nhs.uk/Conditions/Myasthenia-gravis/Pages/Introduction.aspx • Worsens throughout the day Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 77 Myasthenia Gravis ALLOPATHIC TREATMENT: • Acetylcholinesterase inhibitors, corticosteroids to reduce effects of the antibodies (side effects! Including osteoporosis, indigestion, rapid heartbeat, nausea, insomnia, mood changes, diabetes, glaucoma) • Plasma Exchange in severe cases, injections of normal immunoglobulins/antibodies from healthy donors ALTERNATIVE TREATMENT: • Herbal medicine (immune modulation), acupuncture, homeopathy, nutritional (nerve and muscular function) – calcium, magnesium. Video: Myasthenia Gravis (Ice Test) www.youtube.com/watch?v=oetVi29_qbE Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 78 Duchenne Muscular Dystrophy • Caused by a single gene defect on the X-chromosome • Affects males, females can be carriers • Affects 1 in 3500 males. Usually diagnosed 3-5 years • Lack of a protein called dystrophin in muscle cells. • Dystrophin anchors the cytoskeleton to the extracellular matrix (important for cell membrane integrity). • If this protein is missing, when the cell contracts there is no support and the cell membrane becomes leaky. Allowing calcium and other extra-cellular materials to flood in. • This results in muscle degeneration and necrosis Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 79 https://knowledgeforall1415.wordpress.com/about/ Duchenne Muscular Dystrophy SIGNS AND SYMPTOMS • Delayed walking • • • • • Waddling gait Clumsiness Proximal limb weakness Speech delay Gowers sign DIAGNOSIS • Serum creatine kinase (10-100x normal) • Genetic analysis and muscle biopsy https://app.emaze.com/@ALCOZWFZ/Duchenne-Muscular-Dystrophy 80 Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. Duchenne Muscular Dystrophy • All muscle types affected: skeletal, smooth and cardiac. • Small amounts of dystrophin also present in nerve cells (IQ is affected). • Prognosis poor: usually wheelchair support needed by 10yrs and ventilation by 20. • Death occurs in late 20s primarily cardiorespiratory failure. • Therapeutic strategies aimed at prolonging independent walking, managing scoliosis, nutrition and weight management. https://kin450-neurophysiology.wikispaces.com/Duchenne+Muscular+Dystrophy Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 81 DYSTROPHY: MYOTONIC CONGENITA MD Inherited – DOMINANT (Chromosome 19 – CAUSE many nucleotide CTG repeats) Prolonged contraction of muscles. Disease PROCESS “Locking in place” Which eventually leads to muscle atrophy MUSCLES MOST Muscles of lower legs hands, neck & face AFFECTED Young adulthood, but can occur at any age AGE of ONSET SEX most AFFECTED KEY SYMPTOMS PROGNOSIS FACIOSCAPULOHUMERAL (FSHD) MD Inherited – DOMINANT Chromosome 4 defect Gene makes a protein called DUX4 – that is toxic to muscles. Progressive weakening & loss of skeletal muscles Face, shoulder girdle & upper arms. Abdominal, hips, lower legs. Usually by age 20 - 2nd most prevalent muscular dystrophy affecting ADULTS Both Both Signs and symptoms of the disease become more severe with each successive generation 1. Wasting & weakness in lower legs, hands, neck & face 2. Mask-like, expressionless face 3. Premature Balding 4. Cataracts 5. Heart Arrhythmias No cure - severe case may require a wheelchair in later life. Respiratory infections pose a great danger 1. Shoulder weakness ie. Difficulty reaching above head 2. Lower limb weakness ie. Foot drop 3. Scapular winging 4. Facial weakness. 5. Lumbar lordosis. 6. Muscle pain and aching around scapula Most have a normal lifespan with varying degrees of disability / complications - hearing loss, vision problems & respiratory insufficiency 82 The complex internal structure of a myocyte https://www.jci.org/articles/view/38027/figure/1 Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 83 Summary Questions 1. Name the 4 properties of muscle 2. Explain one structural difference between cardiac muscle and other muscle types 3. What is the function of the following muscles: Hamstrings, deltoid, tibialis anterior, biceps brachIi, masseter. 4. Are skeletal, smooth and cardiac muscle striated or non-striated? 5. Name the three methods of producing ATP in muscle fibres 6. Name the two muscle myofilaments 7. Where is: a) oxygen and b) calcium stored in a muscle fibre? 8. Describe what takes place at a neuromuscular junction 9. Who is commonly affected by Duchenne's Muscular Dystrophy? What are the symptoms of this disease? 10. Describe the condition Myasthenia Gravis Copyright CNM 2016-17: Human Sciences – Muscular System. Last updated 31st August 2016. BQ. 84
