Micro Muscle Anatomy And Physiology

Question 1

How motion is generated

Answer 1

Forces(muscle)- acting on levers(bones) - about axes(joints)
Skeletal muscle provides the force for motion (torque to occur)
Muscles must convert chemical energy into mechanical work

Question 2

Types of Human muscle tissue

Answer 2

Smooth muscle
Cardiac muscle
Skeletal muscle

Question 3

Smooth muscle

Answer 3

Involuntary
Blood vessels and organs
Slow, uniform motion
Fatigue resistant
Ex. Eye iris and digestive tract muscles

Question 4

Cardiac muscle

Answer 4

Involuntary
Muscles of th heart
Self generating impulses
Features both smooth and skeletal muscle tissue
Very fatigue resistant

Question 5

Skeletal muscle

Answer 5

voluntary
Connects to bony segments via tendons
Repeated contractions may lead to fatigue
Striated

Question 6

Anatomy of skeletal muscle

Answer 6

Connective tissue, compromised mainly of the protein collagen
Surrounds all muscle fibre bundles
It is continuous with, and part of the tendons that join muscle to bone
Sometimes the “tendon” is in the form of broad sheets called fassia

Question 7

Macro to micro: muscle

Answer 7

Muscle
Fascicle
Muscle cell (muscle fibre)
Myofibril
Myofilaments

Question 8

What is a Muscle cell/muscle fibre

Answer 8

A single cell is the diameter of a thin human hair
Maximum length is 12 cm
Multi-nucleated cylindrical cell
Myocyte

Question 9

Sarcolemma

Answer 9

Muscle Cell membrane

Question 10

Sarcoplasm

Answer 10

Cytoplasm

Question 11

Sacromere

Answer 11

Functional unit (contractile unit) of a muscle fibre

Question 12

Myofibrils

Answer 12

Made up of contractile proteins
Actin and myosin
Makes up muscles fibres ( a bunch of them together)

Question 13

Actin

Answer 13

Thin filaments
Forms the framework and slides over (outside)

Question 14

Myosin

Answer 14

Thick filaments in the middle
Fibrous protein that makes up contractile filaments of muscle cells

Question 15

Sacroplasmic reticulum

Answer 15

Net like labryinth of tubules inside fiber

Question 16

T (transverse) tubules

Answer 16

Connects sarcoplasmic reticulum with outer membrane (Sarcolemma)

Question 17

Mechanical movement required for contraction (sliding filament theory)

Answer 17

Myosin heads (cross bridges) grabs actin, actin slides across myosin causing contraction of the Sacromere unit and thus muscle contraction
(Person climbing tree)

Question 18

A muscle contracting (sarcomeres)

Answer 18

Many sarcomeres (actin sliding over the myosin)

Question 19

What changes length in a muscle

Answer 19

Sarcomere units

Question 20

Sarcomere unit

Answer 20

Myosin and actin (myofilaments)

Question 21

Muscle contraction ?

Answer 21

Muscles can shorten, stay the same length or enlarge

Question 22

Isometric state

Answer 22

When muscle force equals the load, the muscles will not change in length

Question 23

Eccentric state

Answer 23

When muscle force is less than the load, the muscle will lengthen
Ex. Moving heel away from the buttocks is an example of eccentric contraction of the hamstring
Has the greatest force

Question 24

Concentric state

Answer 24

Classic muscle function
When muscle force exceeds the load, the muscle will shorten
Ex. Moving heel closer to the buttocks is an example of concentric contraction of the hamstring

Question 25

What contraction state produces the greatest force

Answer 25

Eccentric- greatest force production
Isometric- 2nd greatest force
Concentric state- least force production

Question 26

Other factors that influence the force of muscle contractions

Answer 26

1. The individuals state of health
2. The individuals training status
3. Joint angle and (coordination of movement)
4. Muscle cross-sectional area
5. Speed o movement
6. Muscle fibre type
7. Age
8. Sex (male/female)

Question 27

Joint angle

Answer 27

the type of contraction and the force required to resist an external load as the joint angle changes
-the contraction type and force required depend on wether the external force exceeds, or is less than, the internal (applied) force
-static (isometric) and dynamic (concentric and eccentric) contractions may all be required
-coordination between agonists and antagonists muscle is required

Question 28

Joint angle and length relationship

Answer 28

maximal force is produced at a joint angle that corresponds to maximal cross-bridge interaction (where is it hardest to lift) ex. Bicep curl, most difficult at the beginning; length tension as you reach 90 the force increases; once you pass 90 the force goes back down, actin has nowhere left to slide

Question 29

Joint angle (length tension relationship )

Answer 29

A- too far apart fewer cross-bridges can form =less force produced
B- optimal distance apart, maximal cross-bridge formation = maximal force production
C- too close together, cross-bridges overlap= less force production
-maximal force is produced at a joint angle that corresponds to maximal cross-bridge interaction
*reference photo

Question 30

Muscle cross-sectional area MSCA

Answer 30

1000s of sarcomeres in a muscle fiber; 1000s of muscle fibres in muscle
-body mass is positively correlated with strength, provided that mass is muscle tissue or lean mass
-the larger the muscle cross sectional area the more force it can generate
- the heaviest weights of all are lifted by athletes in the super-heavyweight category

Question 31

Speed and force ( force-velocity relationship)

Answer 31

Force-velocity relationship: with classic muscle contractions (concentric), as speed of movement increase, then force a muscle can generate decreases (the higher the force you try to produce, the slower it will be)
Why?
-cross bridges are compromised since they cannot couple and uncouple fast enough (myosin heads attaching to the actin filaments)

Question 32

Muscle fibre types: type 1

Answer 32

slow twitch: the greater the slow-twitch fibre intent of a muscle
-the lower the force-producing capacity
-the slower the contraction speed
-the greater the endurance characteristics of the muscle (energizer bunny)
(Distance athletes have high type one)

Question 33

Muscle fibre type: type 2

Answer 33

Type 2- fast twitch : the greater the fast-twitch muscle fibre content of a muscle
-the greater the force outpost
-the greater the overall speed of contraction: the nerve feeding a fast-twice higher fibre is thicker=information travels faster
-the greater the fatiguability will be
*fast-twitch fibres are larger, which means there are more sarcomeres = more force
(Sprinters have high type two)
No sex differences for type 2 and type 1 distribution

Question 34

How AGE effects muscles

Answer 34

-aging affects muscle force output
-there is a loss of fast-twitch fibres associated with aging
-may occur as a result of apoptosis (cell death)
-may occur as a result of diffuse
-sarcopenia is the medical term that described muscle loss

Question 35

Sex (male vs. female) effects muscles

Answer 35

-the absolute capacity of a female is often less than that of a male
-however there is not much difference between males and female when force and power data are normalized to selected anatomical variables
-the differences between males and females is mainly due to differences that exist in muscle volume

Question 36

What initiates muscle contractions

Answer 36

The nervous system
-neural impulse are electrical currents that pass along fibres to the muscle (like a light switch)
-also called action potential
-the brain delivers electricity to the muscle to turn on/contract (excitation)

Question 37

Nervous system ( muscle contractions)

Answer 37

each “motor” nerve innervates (turns on) many muscle fibres and is called a motor unit (one nerve and many fibres)
Motor nerves = motorneurons

Question 38

Slow twitch motor neurons

Answer 38

-small in diameter
-110 milliseconds to reach peak
-fatigue resistance
-innervates approx. 100 slow twitch muscle fibres

Question 39

Fast twitch motor neurons

Answer 39

-large in diameter
-50 milliseconds to reach peak
-fatigue quickly
-innervates approx. 500 fast twitch muscle fibres
-therefore generates greater force than slow twitch

Question 40

How action potential travels

Answer 40

Impulses cross gaps (synapses) between adjoining nerves
-impulses cross gap (motor end plate) to innervates muscle
-both gaps crossed using neurotransmitter, acetylcholine (Ach)

Impulse arrives at neuro-muscular junction (motor endplate)NMJ
Crosses over the synaptic cleft with the aid of acetylcholine
Impulse travels over Sarcolemma, through the t-tubules; causing calcium to be released from storage in sarcoplasmic reticulum
The release of calcium causes molecular cross bridging of actin and myosin

Question 41

Absence of neural impulse

Answer 41

In the absence of a neural impulse, the calcium is reabsorbed into sarcoplasmic reticulum thus stopping the contraction

Question 42

Review: muscle contraction

Answer 42

1. Impulse arrives at the NMJ (neuromuscular junction)
2. Impulse travels over Sarcolemma
3. Calcium is released from the SR (sarcoplasmic reticulum)
4. Cross bridges form
5. Muscle contracts

Question 43

Volitional contraction (efferent impulse) travelling via…

Answer 43

Pyramidal tract

Question 44

Reflexive contraction (afferent impulse) travelling via…

Answer 44

Posterior column

Question 45

Particularly kinaesthetic feedback (2 types)

Answer 45

Vestibular ( semi circular canals)
Proprioceptors ( muscle/joints)