Cardiovascular Mechanics

Question 1

What ion produces a contractile event?

Answer 1

Calcium

Question 2

What happen when you remove calcium from the extracellular space of cardiac tissue?

Answer 2

The cardiac tissue will not contract

Question 3

What are T-Tubules?

Answer 3

Finger like invaginations from the cell surface that are spaced such that each T tubule lies alongside the Z line of every myofibril

Question 4

What do T tubules do?

Answer 4

Allow the excitatory depolarisation event to travel deep into the cell

Question 5

What is the lace like structure above the sarcomeres?

Answer 5

Sarcoplasmic reticulum

Question 6

What is the function of the sarcoplasmic reticulum?

Answer 6

holds and stores calcium

Question 7

What percentage of volume of cardiac cell does the sarcoplasmic reticulum occupy?

Answer 7

4%

Question 8

What channels lie in the T tubule membrane?

Answer 8

L type calcium channels

Question 9

What receptors lie above the L-type calcium channels

Answer 9

Ryanodine receptors

Question 10

Where are ryanodine receptors found?

Answer 10

Embedded within the sarcoplasmic reticulum membrane

Question 11

What are SR calcium release channels?

Answer 11

Ryanodine receptors

Question 12

What structure is involved with detecting the action potential / depolarisation event?

Answer 12

The L type calcium channel

Question 13

What first happens when a depolarisation event is detected?

Answer 13

Ca2+ ions from outside the cell enter through the calcium channels

Question 14

What two things happen to the calcium which enter into the L-type Ca2+ channel?

Answer 14

Most binds to Ryanodine receptor but some goes to sarcomere for muscle contraction

Question 15

What happen when the ryanodine receptor binds calcium?

Answer 15

Undergoes a conformation change, and allows stored calcium to be released from the sarcoplasmic reticulum into the cytoplasm

Question 16

What happens to the stored calcium that is released from the sarcoplasmic reticulum?

Answer 16

Binds to the myofilaments to initiate muscle contraction

Question 17

What is the calcium induced calcium release effect?

Answer 17

When calcium comes and binds to the ryanodine receptor, to trigger the release of more calcium from the sarcoplasmic reticulum

Question 18

How is relaxation of the muscle brought about?

Answer 18

The calcium ions are taken back up into the sarcoplasmic reticulum by SR Ca2+ ATPase

Question 19

What is the sodium calcium exchanger?

Answer 19

A protein embedded in the T tubule which allows calcium to leave into the extracellular space to trigger relaxation of the muscle

Question 20

What is the balance between the amount of calcium entering into the cell, and leaving the cell?

Answer 20

They are equal

Question 21

What does force production depend on?

Answer 21

The concentration of intracellular calcium

Question 22

What is the relationship between force production and calcium concentration in the cytoplasm?

Answer 22

Sigmoidal relationship

Question 23

What happens to the amount of force produced when you increase the stretch on the muscle?

Answer 23

The amount of force produced increases

Question 24

What is passive force?

Answer 24

As you stretch a muscle fibre more, the elasticity this results in is called the passive force - like a recoil force

Question 25

What happens to passive force as you stretch cardiac muscle more?

Answer 25

Passive force increases

Question 26

What is meant by isometric contraction?

Answer 26

Contraction that produces forces without the muscle shortening

Question 27

What is total force?

Answer 27

Active force + Passive force

Question 28

Between cardiac and skeletal, which produces more passive force?

Answer 28

Cardiac muscle

Question 29

Why does cardiac muscle have a larger passive force?

Answer 29

Cardiac muscle is more resistant to stretch, so when it does get stretched the passive elastic recoil force it can produce is greater

Question 30

Why is cardiac muscle more resistant to stretch?

Answer 30

The properties of the extracellular matrix and cytoskeleton

Question 31

Why does cardiac muscle only work on the ascending limb?

Answer 31

Because you cannot over stretch cardiac muscle

Question 32

Why does the active force fall when you overstretch skeletal muscle?

Answer 32

Because stretching it too much decreases the interdigitation between actin and myosin, so active force falls away

Question 33

Why can cardiac muscle not be over stretched?

Answer 33

Physiological constraints - The heart is contained within the pericardium

Question 34

what are the two forms of contraction the heart uses?

Answer 34

Isometric contraction and Isotonic contraction

Question 35

What is isometric contraction?

Answer 35

Muscle fibres do not change length but pressure increases in both ventricles

Question 36

What is isotonic contraction?

Answer 36

Shortening of fibres resulting in the ejection of blood from the ventricles

Question 37

During isometric contraction, why is blood not ejected from the ventricle?

Answer 37

The valves are shut

Question 38

Why does the pressure increase in the ventricle during isometric contraction?

Answer 38

Because the cardiac muscle is contracting against. blood volume

Question 39

When does isotonic contraction take over?

Answer 39

When the pressure in the ventricle is greater than the pressure in the aorta

Question 40

What is the preload?

Answer 40

The amount of stretch the muscle experiences before it is actually stimulated to contract

Question 41

What is the afterload?

Answer 41

The pressure the heart must work against to eject blood during systole (ventricular contraction)

Question 42

When is the afterload encountered?

Answer 42

when the muscle has started to contract

Question 43

When is isometric contraction in play?

Answer 43

During ventricular filling

Question 44

What is the relationship between the shortening of muscle and the afterload?

Answer 44

As the afterload increases, the amount of shortening decreases

Question 45

For the same afterload what happens to the shortening of a longer muscle length?

Answer 45

More shortening

Question 46

What is the preload defendant on?

Answer 46

Venous return

Question 47

What is the after Load?

Answer 47

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

Question 48

What is the after-load proportional to and why?

Answer 48

Arterial pressure - the arteries have smooth muscle and therefore can contract, increasing the pressure - this pressure can then back up towards the aorta as well

Question 49

What happens to velocity of contraction when you increase the afterload?

Answer 49

It decreases

Question 50

What happens to the amount of isotonic shortening when you increase the afterload?

Answer 50

It decreases

Question 51

What are measures of preload?

Answer 51

End diastolic volume, end diastolic pressure and right atrial pressure

Question 52

What are measures of the afterload?

Answer 52

Diastolic blood pressure

Question 53

Why is high blood pressure not a good thing for the heart?

Answer 53

Higher blood pressure means the heart has to work harder to efflux blood from the ventricles

Question 54

How does the force of contraction relate to venous return?

Answer 54

Venous return affects the preload, and a larger pre load increases the force of contraction

Question 55

What is the Frank-Starling law?

Answer 55

Increased diastolic fibre length increases ventricular contraction

Question 56

What is the consequence of the Frank-Starling Relationship?

Answer 56

A greater stroke volume is observed when the venous return and hence preload increases

Question 57

How does the heart have its own intrinsic regulatory mechanism?

Answer 57

Pumps out exactly the same amount of blood that returns to it

Question 58

What two factors cause Thr Starlings Law?

Answer 58

The change in the number of myofilaments cross bridges that interact

The changes in the Ca2+ sensitivity of the myofilaments

Question 59

Relationship between shorter lengths of muscle fiber and strength of contraction?

Answer 59

Shorter lengths that optical mean actin filaments overlap, which reduces the number of myosin cross bridges that can be made so less contracttion

Question 60

What happens to interdigitation when you stretch a muscle fibre?

Answer 60

It increases and more cross bridges are formed

Question 61

How does the stretch of muscle affect the Ca2+ sensitivity?

Answer 61

Longer sarcomere lengths increases the affinity of Troponin for Ca2+ due to a conformational change in the protein

Question 62

How is force affected by Ca2+ sensitivity?

Answer 62

The higher the Ca2+ sensitivity, The more cross bridges will form - this means more force is produced for the same amount of activating calcium

Question 63

What is the lattice spacing hypothesis?

Answer 63

With stretch, the space between the myosin and actin filaments decreases, so the probability of forming strong binding cross bridges increases, hence producing more force with the same amount of activating calcium

Question 64

What is the definition stroke work?

Answer 64

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

Question 65

How do you calculate stroke work?

Answer 65

Stroke work = the volume of blood ejected during each stroke x the pressure at which the blood is ejected

Question 66

What is the stoke volume greatly impacted by?

Answer 66

The preload and the afterload

Question 67

What affects the pressure at which the blood is ejected from the ventricle?

Answer 67

Cardiac structure

Question 68

What is the definition of the law of LaPlace?

Answer 68

When the pressure in a cylinder is held constant, the tension on its walls increases with an increase in radius

Question 69

What is the formula for wall tension?

Answer 69

(Pressure in vessel x radius of vessel) / wall thickness

Question 70

Which ventricle has a larger radius of curvature?

Answer 70

The Right ventricle

Question 71

Use the Law of LaPlace to explain why the pressure is higher in the Left Ventricle?

Answer 71

The tension in the walls of both ventricles is the same, and given that T = Pressure x Radius, since the radius of the left ventricle is lower, the pressure must to higher to compensate for this

Question 72

What happens to wall stress in failing hearts?

Answer 72

Wall stress increases due to dilation

Question 73

How does adrenaline secretion affect preload?

Answer 73

Ádrela one increases the venous return, and therefore increases the preload

Question 74

What factors affect the afterload?

Answer 74

Stenosis or hardening of the artery