Cardiovascular mechanics

Question 1

Which ion do ventricular cells require for contraction?

Answer 1

Calcium

Question 2

What is the shape of ventricular cells?

Answer 2

Rod shaped

Question 3

What is the distinctive difference regarding the heart v skeletal muscle for contraction?

Answer 3

The heart will not beat without external calcium difference to skeletal muscle which is independent

Question 4

What is the 3 stages for ventricular contraction?

Answer 4

Electrical event (action potential)
Calcium transient (Amount of calcium  in sarcoplasm has increased for short period of time)
Contractile

Question 5

What is the length and width of a ventricular cell?

Answer 5

100microm,

15 Microm

Question 6

Describe the position of T-tubules respect to the Z-discs of a sarcomere?

Answer 6

The t-tubules is intermediate between each z-line of Myofibrils, transmitting surface depolarisation deep into the cell

Question 7

SAQ: What organelle is prevalent in ventricular cells?

Answer 7

Mitochondria

Question 8

SAQ: Why is there a high prevalence of mitochondria within ventricular cells? (2 marks)

Answer 8

Supply adequate amount of ATP (1)

To supply the sledding filament theory (2), myosin globular heads require ATP binding to reconfigure in high energy state.

Question 9

Which type of channel opens in response to the action potential within the cardiomyocyte?

Answer 9

L-type calcium channel

Question 10

Why do L-type calcium channels open?

Answer 10

Upon excitation, the depolarisation is sensed by the ion channel within the caridomyocyte, opening in response

Question 11

How does extracellular calcium enter into the cardiac cell?

Answer 11

Passive diffusion across concentration gradient

Question 12

What is the fate of the diffused intracellular calcium?

Answer 12

Minor proportion directly activates the contraction of sarcomere, binding onto TnC of actin filaments, causing contraction

Majority bind to ryanodine receptors on SR to cause Ca efflux from SR.

Question 13

Which receptor does Calcium ions bind onto within the sarcoplasmic reticulum?

Answer 13

Ryanodine receptor

Question 14

Upon ligand calcium activation of ryanodine receptor, what occurs?

Answer 14

Receptor undergores conformation change, opening the ryanodine receptor, thus enabling calcium efflux from sarcoplasmic reticulum

Question 15

Which complex does calcium bind to on the actin filaments?

Answer 15

Troponin-C.

Question 16

Upon TnC-Ca binding, what occurs to the actin filaments?

Answer 16

Myosin-binding site becomes exposed, through withdraw of tropomyosin complex, enables myosin head to bind, and undergo power stroke, sarcomere shortening is activated

Question 17

How is ionic balance achieved within ventricular cells upon relaxation phase?

Answer 17

Calcium is actively pumped out into stored position by Ca2+ ATPase channels of sarcoplasmic reticulum.
Same
Calcium-induced calcium release via sodium-calcium exchanger

Question 18

How much calcium is effluxed from the sodium-calcium exchanger?

Answer 18

Same amount of calcium that came in = same amount effluxed

Question 19

Is calcium-induced released passive or active?

Answer 19

Passive

Question 20

Why is calcium-induced release passive?

Answer 20

Does not require energy, since energy is transferred through the passive diffusion of sodium ions into the cell to expel calcium

Question 21

What is the relationship between contractile force and cytoplasmic calcium concentration?

Answer 21

Sigmoidal relationship

As intracellular cytoplasmic calcium increases, the force exerted by muscles increases

Question 22

What is the optimum cytoplasms calcium concentration sufficient to produce maximum force?

Answer 22

10micrometers

Question 23

What is the relationship between muscle length and baseline force?

Answer 23

Direct proportionality

Question 24

What is the relationship shown by the active force production line?

Answer 24

Cardiac preparation increases, muscular force increases

Question 25

What is the relationship with muscle length and passive force?

Answer 25

Direct proportionality

Question 26

Why does passive force increase as muscle length increases?

Answer 26

Elastic components (elating) stretch, passive tension is produced; cytoskeletal components of cells stretch, elastic potential energy is stored, during no sarcomere shortening of the muscle isometric contraction

Question 27

What is an isometric contraction?

Answer 27

Tension provided does not cause muscular shortening, exerts pulling force

Question 28

Why is there a limit of proportionality for active force line?

Answer 28

Stretching point
Further stretching cannot occur to generate force, insufficient overlap between actin and myosin filament within the A band

Question 29

Why is passive force greater in cardiomyocytes than myocytes?

Answer 29

Cardiac is less compliant, and resilient to stretch, thereby can withstand greater isometric contractions before sarcomere shortening proceeds.

Question 30

Why are cardiac muscles less compliant?

Answer 30

Properties of the extracellular matrix and cytoskeleton influence this

Question 31

Why is there a descending limb in the muscle force relationship?

Answer 31

Overstretch of muscle beyond the actin and myosin filament overlap will result in a decrease in force, behaviour is exhibited in skeletal muscle.

Question 32

What is passive force?

Answer 32

based on resistance to stretch of the muscle

Question 33

What is the total force produced?

Answer 33

Active force + Passive force

Question 34

Why is there not an ascending limb of length-tension curve?

Answer 34

Important in physiological circumstance in cardiac muscle; the descending limb does not occur in physiological condition because pericardium restricts stretching

Question 35

What is an isometric contraction?

Answer 35

Sarcomeres and muscle fibres do not change length, however pressures increase in both ventricles, attributed to the passive force of cytoskeleton stretch.

Question 36

What is an isotonic contraction?

Answer 36

Shortening of fibres, and blood is subsequently ejected from ventricles.

Question 37

What is preload?

Answer 37

Degree to which are stretched from filling of the ventricles prior to contraction. Therefore, preload is a way of expressing end-diastolic volume. Increasing ventricular filling, increases EDV, and cardiac muscle is stretched to a greater degree.

Question 38

What influences preload directly?

Answer 38

Venous return and end diastolic volume

Question 39

What is end-diastolic volume?

Answer 39

The volume of blood president within the ventricles before ventricular systole

Question 40

How does tachycardia affect preload?

Answer 40

Decreases, reduced duration of ventricular diastole, thus diastolic volume decreases, shorter filling, lowering preload

Question 41

How does a reduced preload due to tachycardia overcome?

Answer 41

Increased contractility, raises the stroke volume

Question 42

What is the Frank-Starling relationship?

Answer 42

Ventricular stretch and contraction. Within physiological limits, the force of heart contraction is directly proportional to initial length.
Greater stretch = more preload = contractility increased = greater stroke volume

Question 43

What is cardiac contractility?

Answer 43

Cardiac contractility: Tension developed and velocity of shortening (Strength of contraction) of myocardial fibres at a given preload, and afterload.

Question 44

How does sympathetic activity influence preload?

Answer 44

Increased venous return to heart, contributes to ventricular filling, EDV + preload.

Question 45

What is afterload?

Answer 45

The load against which the left ventricle ejects blood after opening the aortic valve.

Refers to the tension/force that the ventricle must develop to pump blood effectively against the resistance in the vascular system.

Question 46

Which conditions increase afterload?

Answer 46

Vasoconstriction, stenosis, atherosclerosis

HYPERTENSION

Question 47

Why does vasoconstriction, stenosis and hypertension cause greater afterload?

Answer 47

Greater backforce on aortic valves, thus greater pressure is required to open the aortic semi-lunar valves for ventricular systole to occur (Magnitude of isotonic contraction must increase)

Question 48

What effect does an increased afterload have on isotonic shortening?

Answer 48

Decreases isotonic shortening, and contractility (velocity of shortening)

Question 49

Which factors decrease vascular resistance?

Answer 49

Vasodilation (Increased radius)

Question 50

What are the measure of afterload?

Answer 50

Diastolic arterial blood pressure

Afterload is blood pressure

Question 51

Why do shorter muscle lengths produce less tension?

Answer 51

Reduces actin-myosin filament overlap, fewer cross-bridges can be made.

Question 52

Which two factors influence cardiac contractility?

Answer 52

Changes in the number of myofilament cross-bridges that interact
Changes in calcium seb sensitivity of the myofilaments

Question 53

How does ventricular stretching influence contractility in respect to calcium?

Answer 53

Ventricular stretching subsequently increases the contact between the myosin heads with the myosin binding sites presented by the thin actin filaments, lattice-spacing decreases.
Decreasing myofilament lattice spacing increases the probability of forming strong-binding cross-bridges; providing more force for the same amount of activating calcium.

Question 54

How does calcium sensitive influence contractility?

Answer 54

Ca2+ required for myofilament activation, troponin C (TnC), is thin filament protein that binds Ca2+, subsequently causing tropomyosin to expose the myosin binding sites, regulating the formation of cross-bridges between actin and myosin.
At longer sarcomere lengths, the affinity of TnC for Ca2+ is increased due to conformational change in protein; thereby less Ca2+ is required for equivalent amount of force.

Question 55

What is stroke work?

Answer 55

Work done by the heart to eject blood under pressure into aorta and pulmonary artery

Question 56

What is stroke work?

Answer 56

Area beneath pressure volume loop

Stroke volume x pressure

Question 57

What is stroke volume?

Answer 57

End diastolic volume - end systolic volume

Question 58

Which factors affect stroke work?

Answer 58

Preload
Contractility
Afterload

Question 59

What is Law of Laplace?

Answer 59

Assuming pressure within a cylinder is held constant, the tension exerted onto the walls increases with increasing radius. (h=Wall thickness)
Increase radius = Increase tension
𝑾𝒂𝒍𝒍 𝑻𝒆𝒏𝒔𝒊𝒐𝒏=𝑷 𝒙 𝑹
𝑻=𝑷𝑹/𝒉

Question 60

How is the left ventricular adapted to cope with systemic circulation (afterload increased) in regards to Law of Laplace?

Answer 60

Radius of curvature is comparatively less than RV, allowing LV to generate higher pressures with equivalent wall stress