15 - Muscle Structure

Question 1

What is myalgia, myasthenia, myocardium, myopathy and myoclonus?

Answer 1

Myalgia - Muscle pain

Myasthenia - Muscle weakness

Myocardium - Muscular part of heart

Myopathy - Muscle disease

Myoclonus - Muscle spasm

Question 2

What are the categories of muscle?

Answer 2

Question 3

What is myoglobin?

Answer 3

A red single subunit protein that stores oxygen and supplies oxygen to striated muscle.

Higher affinity for O₂ than Hb and no affinity for CO₂

Question 4

How does oxygen get from Hb to Myoglobin?

Answer 4

Hb gives O₂ to myoglobin as myoglobin has higher affinity, especially at low pH

Question 5

Why do you get renal damage from muscle tears?

Answer 5

• Striated muscle damaged or dies then myoglobin is released into the blood stream.

This is removed by the kidneys, producing tea coloured urine, causing renal damage

Question 6

What is the structure of a striated muscle cell including terminology?

Answer 6

Question 7

What are the three types of connective tissue in striated muscle?

Answer 7

- Endomyisum (loose) : Between each cell

• Perimyisum (loose): Between each bundle (fasicle)

- Epimyisum (dense): Outside of whole muscle

Carry nerves and vessels

Question 8

Why would you not see striations looking down a microscope at heart tissue?

Answer 8

• May be looking at it in transverse, not longitudinal.
• May need to look down TEM

Question 9

What are the different shapes of muscles?

Answer 9

Question 10

What cause the striations?

Answer 10

Myofilament, actin and myosin

Question 11

What are the layers of making a muscle?

Answer 11

• Muscle cells held together by CT to form fibres
• Fibres held together to form fasicles
• Fasicles held together to form muscle

CT contains collagen and reticulin

Question 12

How does striated muscle conect to bones?

Answer 12

• Connected to tendon which is connected to the periosteum

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Question 13

What is the insertion and origin point of a tendon?

Answer 13

• Origin is where the tension is (closest to body)
• Insertion is where the movement is (distal from body)

Question 14

Why are muscles in the tongue not attached to bone?

Answer 14

• Not all muscles are attached to bone, allows tongue to change shape, aiding swallowing

Question 15

What does the tongue muscles look like under a microscope?

Answer 15

Question 16

What does circular, convergent, parallel and fusiform muscles do?

Answer 16

1. Normally sphincter muscles that surround an opening. Open when ingress and exgress of materials is required
2. Origin wider than insertion. Triangular used for lots of force
3. Long muscles that cause large movements. Not strong but high endurance
4. Can be grouped with parallel. muscle beller wider than insertion and origin

Question 17

What do pennate muscles do?

Answer 17

- Uni: Great strength as at diagonals

- Bi: Central tendon. Greater power but less range of motion

• Multi: Multiple tendons as muscle fibres in both directions

Question 18

What are the nuclei like in skeletal muscle?

Answer 18

• Peripheral, very close to sarcolemma
• Binucleated

Question 19

What is the blood supply like to thin and thick muscle fibres?

Answer 19

Thin fibre - less blood

Thick fibre - more blood

Question 20

What does the plasmalemma consist of?

Answer 20

• Plasma membrane
• Basal lamina
• Connective tissue

Question 21

Label this muscle cell in transverse section

Answer 21

• Abundant mitochondria between myofibrils

Question 22

Label this diagram of a muscle contraction component.

Answer 22

Question 23

Label this diagram of a sarcomere

Answer 23

Question 24

What factors affect how a muscle contracts?

Answer 24

Fibre arrangements (muscle shape) and what types of fibres (I,IIA,IIB)

Question 25

What is a type I fibre?

Answer 25

• Slow twitch oxidative
• Red due to lots of myoglobin
• Lots of mitochondria and cytocromes
• Resistant to fatigue
• Aerobic respiration
• Postural muscles

Question 26

What are type IIa fibres?

Answer 26

• Fast oxidative
• Hybrid of type I and II
• Many mitochondria and cytochromes
• Pink
• Anaerobic and aerobic
• Moderate resistance to fatigue
• Standing and walking muscles

Question 27

What are type IIb fibres?

Answer 27

• Fast glycolytic fibres
• White as low myoglobin
• Low mitochondria and cytochromes
• Fatigue easily
• Anaerobic respiration
• Muscles of arms and eyes
• Can convert to type IIa fibres with resistance training

Question 28

Compare and contrast the three types of muscle fibres.

Answer 28

• Slow have smaller diameter than fast so more blood can get to them
• Each fibre has own nerve supply

Question 29

What is flexion?

Answer 29

Joint movement that decreases the angle between two bones. Due to muscle contraction.

Which part of the body that moves depends on what is stationary, e.g same muscle can move different things (knee/foot thing)

Question 30

What muscles are levers and what are the three types of levers?

Answer 30

When muscles move against an object or force to create a movement.

Question 31

What are the main features of a cardiac muscle cell?

Answer 31

• Centrally positioned nuclei
• Intercalated discs
• Muscle fibres not as wide as skeletal muscles
• Can be binucleated
• Muscle fibres branch and join toger (anastomose)

Question 32

What are intercalated discs?

Answer 32

• Junctions between muscle cells containing desmosome, fascia adherens and gap junctions
• Gap junctions allow fast electrical conductance from cell to cell

Question 33

What is between cardiac muscle fibres?

Answer 33

• Small amont of connective tissue containing nuclei.
• Contains fibroblasts that secrete extracellular matrix for tissue stability
• When intercalated discs break and cardiomyocytes start to die, fibroblasts lay down more extracellular matrix and form scar tissue

Question 34

Compare cardiac and skeletal muscle?

Answer 34

Similarities:

• Both contract similarly
• Both have striations

Differences:

- Cardiac have central nuclei not peripheral

• Cardiac have less t-tubules and they’re found at Z-lines
• Sarcomere and sarocoplasmic reticulum not so developed
• Cardiomyocytes communicate through gap junction

Question 35

Why is the heart an endocrine organ?

Answer 35

• Secretes ANP (Atrial natriuretic peptide) in atria
• Secretes BNP (brain) from ventricles
• Released during heart failure (distension)
• Increase loss of water in the kidneys so lower blood volume so lower b.p for heart
• Also causes vasodilation

Question 36

When are ANP and BNP released?

Answer 36

BNP - Left ventricular hypertrophy and mitral valve disease

ANP - Congestive Heart Disease

Question 37

What is the difference between hypertrophy and hyperplasia?

Answer 37

Question 38

How does the heart get bigger and smaller?

Answer 38

Hypertrophy and Atrophy NOT Hyperplasia

Question 39

What is the structure of smooth muscle cells?

Answer 39

• Spindle-shaped (fusiform) parallel cells
• Single central elongated nucleus
• Not striated, no sarcomeres or t-tubules
• Can be stretched
• Forms sheets
• Caveolae (pinocytosis)

Question 40

Label this diagram

Answer 40

Question 41

What are the point of dense bodies in smooth muscle cells?

Answer 41

Attached to sarcolemma. They assemble actin and myosin filaments when the muscle is ready to contract. When myofilaments slide they pull different sides of the cell together not Z-lines

Question 42

How would you describe the contraction of smooth muscle?

Answer 42

• Relies on actin-myosin
• Slow but more sustained
• Less ATP
• Can contract for hours or days
• Contracts in response to hormones, blood gases etc

Question 43

Where is smooth muscle found?

Answer 43

• GI tract
• Genioutuary system
• Blood vessels

Question 44

What conditions can smooth muscle cause?

Answer 44

• Can develop ‘a mind of it’s own’
• Asthma
• Dysmenorrhea
• IBS
• Incontinence

Question 45

What happens to the histology of a smooth muscle cell when it contracts?

Answer 45

NUCLEI SQUEEZE UP

Question 46

What is being pointed to here?

Answer 46

T-TUBULES.

Mitochondria on edges of myofibrils

Question 47

What type of muscle is this and why does the left side look different to the right?

Answer 47

• Smooth
• Left is transverse section and right is longitudinal

Question 48

How are smooth muscle cells controlled?

Answer 48

• Autonolmic nerve fibres surround muscle
• Release neurotransmitters from varicosities

Question 49

Can skeletal muscle repaire after tearing?

Answer 49

• YES, skeletal muscle cells cannot divide but satellite stem cells in endomysium divide by mitosis so hyperplasia.
• Satellite cells can also differentiate into myoblasts and fuse with existing muscle cells to cause hypertrophy

Question 50

Can cardiac muscles repair after tearing?

Answer 50

• In infants yes
• In adults no regneration
• Fibroblasts invade after damage, and lay down scar tissue

Question 51

Can smooth muscle repair after tearing?

Answer 51

• YES, smooth muscle cells retain their mitotic activity
• e.g in the pregnant uterus the muscle wall becomes thicker by hypertrophy and hypoplasia
• e.g hyperplasia of bronchial muscle for asthma

Question 52

What are the stages of muscle repair after tearing?

Answer 52

Question 53

What is the point of acetlycholinesterase?

Answer 53

• Catalyses acetylcholine when it has passed electrical signal onto sarcolemma
• Neurotransmitter can be recycle back into the presynaptic knob

Question 54

What is the function of the terminal Schwann cell and the kranocyte?

Answer 54

- Terminal Schwann Cell: Keep the motor neuron alive, insulate it from external nerve signals and regenerate and remodel nerve endings

- Kranocyte: Like fibroblasts. Produce a connective tissue layer of elastic and structural fibres that hold neuromuscular junction together

Question 55

How does electrical conduction in the heart occur?

Answer 55

• Electric signal passes from SA node through atrial walls to AV node
• AV node passes the signal to the bundle of His in the septum of the heart
• Signals passed to right and left bundle branches down to the apex of the heart
• Electrical signal travels up the Purkinje fibres up the ventricle walls

Question 56

What is the structure of purkinje fibres (modified myocytes)?

Answer 56

• Large cells with abundant glycogen (so pale staining sarcoplasm)
• Extensive gap junctions of connexins
• Central nuclei
• Myofilaments only in periphery
• No t-tubules
• Fastest electrical conduction, not contraction

Question 57

What is the structure of the SA node and where is it located?

Answer 57

• Banana shaped
• Cells in connective tissue so spread out
• Smaller and paler than atrial cells with less mitochondria, myofibres and sarcoplasmic reticulum so cant contract as well
• Surrounded by paranodal cells that insulate SA node so doesnt pass on electrical activity to surrounding atrial cells
• In the wall of the right atrium next to sinus venarum artery

Question 58

How is the SA node electrically insulated?

Answer 58

• Surrounded by paranodal cells
• Fewer and smaller connexins

Question 59

Where is the AV node and what is it’s structure?

Answer 59

• Right atrium atrioventricular wall
• Posterior section of the interatrial septum, near coronary sinus opening
• Compact compared to SA node

Question 60

What is the central fibrous body?

Answer 60

Connective tissue next to the AV node that contains mainly collagen so no contraction or electrical potential

Question 61

What is the structure of the Bundle of His?

Answer 61

Similar to that of Purkinje fibres but less glycogen and more myofibrils so more contractile ability than Purkinje and the nodes

Question 62

Why does electrical conduction not occur through the heart valves?

Answer 62

• Consist mainly of ECM, e.g collagen, and electricity always follows path of least resistance so wouldn’t go down valves

Question 63

What are the structure of the AV and SL valves?

Answer 63

• Fibrosa, Spongiosa, Atrialis/Ventricularis

F: provides strength (collagen)

S: shock absorber when valves close and allows movement between surface cells (proteoglycans)

A/V: elastic