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Question 1

A diagram of an action potential in a cardiac muscle cell.

a) What causes the peak of depolarisation at the start?

Answer 1

• Influx of Na+
• T tubule membrane depolarised
• L-type Ca2+ channel opened (different type of DHPR channel to skeletal – its voltage dependent whereas skeletal isn’t)
• Ca2+ enters cell
• Binds to Ryanodine receptor
• Causes more Ca2+ channels to open
• Calcium induced calcium release from SR

Question 2

b) What ion is most important for standing membrane potential?

Answer 2

K+

Question 3

c) What is the main difference between cardiac and skeletal muscle cells’ methods of excitation-contraction?

Answer 3

• In skeletal muscle the dihydropyridine receptor (non-voltage gated sensor), changes conformation in response to Ca2+ which activates the ryanodine receptor and causes Ca2+ to be released from SR.
• In cardiac cells, the L-type Ca receptor (voltage gated) on t-tubules open Ca channels when depolarised - increase in intracellular Ca causes the ryanodine receptor to be activated and release Ca.

Question 4

d) What happens to force of contraction when there is Sympathetic stimulation to the heart? Why? (4 marks)

Answer 4

• Force increases
• CO and SV increase
• Steeper slope of AP in SAN (reaches threshold potential quicker)
• NA bind to beta-1 adrenoceptors located on cardiac muscle
• Activates adenyl cyclase, increase conc cAMP PKA in myocytes
• Phosphorylation of L type channels which activates them + SR Ca release channels more intracellular Ca more binding sites available (troponin C) more crossbridges stronger contraction

Question 5

a) Aside from skeletal muscle, name 2 other vascular beds to which vasodilation occurs in exercise

Answer 5

Bronchial mucosa (by adrenaline)
Vasodilation in skin vasodilation of heat
Coronary vessels
Metabolic activity increases larger blood supply needed to remove CO2 and supply O2 to muscles.

Question 6

Why does vasoconstriction occur to other organs’ vascular beds?

Answer 6

• So that blood is diverted towards more metabolically active organs and away from less active ones (more active ones need more O2).
• Vasoconstriction occurs in GIT + kidney: to increase the TPR, which helps to maintain MABP (despite vasodilation in skin, skeletal muscle) and keep blood flowing to organs.

Question 7

a) What occurs in exercise to lead to an increase in CO?

Answer 7

Activity of skeletal muscles -skeletal muscle and respiratory pumps - increased venous tone, pressure, return - increased EDV -increased preload - increased stroke volume - increased CO

Increased sympathetic activity and adrenaline - increase venoconstriction and HR.

Sympathetic nervous system -increase contractility.

Decrease in PNS activity - increase HR

Question 8

a) Why does venous return lead to increased CO?

Answer 8

Increased venous return - increase in venous pressure, return -increase in EDV - increase preload increase SV - increased CO.

Question 9

a) Name 2 exercise dependent events that lead to increased venous return

Answer 9

Respiratory (reduced intrathoracic pressure increases venous pressure)
Skeletal muscle pumps

Question 10

Name 2 exercise dependent events that lead to decreased venous return

Answer 10

Vasodilation of skin
Plasma vol decreases due to sweating
Vasodilation of the vessels in skeletal muscle + lungs reduced TPR
Increase in capillary pressure across wall hydrostatic pressure increased as MABP increased

Question 11

a) Name and explain 2 factors in “western culture” that can lead to a predisposition to atherosclerosis

Answer 11

Smoking, high blood lipids (diet), blood pressure, diabetes, obesity, lack of exercise.

Question 12

Name 2 of the 3 cells involved in atherosclerosis

Answer 12

Vascular smooth muscle cells, macrophages, vascular endothelial

Question 13

a) Name two non-modifiable risk factors for atherosclerosis (1)

Answer 13

Age, gender, genetic background

Question 14

a) Name 3 changes to the arterial wall due to atherosclerosis that might lead to clinical complications

Answer 14

1. Endothelial damage leads to macrophage infiltration and release of cytokines
2. Circulating low density lipoproteins are trapped in the lesion and oxidised
3. Oxidised LDL is proinflammatory and drives the progression of the atherosclerotic plaque
4. Smooth muscles cells migrate from the tunica media into the lesion and deposit a collagen-rich matrix that forms a protective fibrous cap

Question 15

What are the clinical complications that could occur due to atherosclerosis?

Answer 15

• Narrowing of vessel by fibrous plaque: renal artery stenosis, myocardial ischaemia, limb claudication
• Plaque ulceration or rupture: thrombotic stroke, unstable angina, myocardial infarction
• Interplaque haemorrhage: thrombotic stroke, unstable angina, myocardial infarction
• Peripheral emboli: embolic stroke, atheroembolic renal disease
• Weakening of vessel wall: aneurysms

Question 16

a) Give 2 ways in which the Vascular Smooth Muscle of the arteries can mediate the stability of plaques

Answer 16

• Smooth muscles cells migrate from the tunica media into the lesion and deposit a collagen-rich matrix that forms a protective fibrous cap
• Proliferation increases the thickness of the smooth muscle around plaque to prevent rupture.

Question 17

What organ produces renin? What are the cells in that organ that produce renin?

Answer 17

Kidney + juxtaglomerular cells.

Question 18

a) What does renin do?

Answer 18

Enzyme which catalyses the conversion of angiotensinogen angiotensin I.

Question 19

a) Where does angiotensin come from?

Answer 19

Angiotensinogen from liver
Angiotensin from kidneys
ACE from lungs and kidneys

Question 20

What 2 hormones have an effect on salt and blood pressure in the kidneys.

Answer 20

Aldosterone – effect on Na
Angiotensin II – Alice Lee
Vasopressin

Question 21

a) Which two limbs do Lead II attach to?

Answer 21

RA and LF

Question 22

b) What angle on the hexagonal system does Lead IIs positive end go to, (or something to that effect)

Answer 22

aVL = -30
avR = -150 
avF = 90
Lead I = 0
Lead II = +60
Lead III = +120

Question 23

c) Work out the heart beat per minute, given the R curves of the diagram

Answer 23

The rhythm strip is normally 25cm long and covers 10s.
Heart rate/min = number of QRS complexes in 10s * 6

1500/number of small squares between QRS

Question 24

d) Work out how long the PQR interval is

Answer 24

1 small square = 0.04s

1 large square = 0.2s

Question 25

e) How long is a normal PR interval?

Answer 25

0.12-0.20s

Question 26

a) Given graph of muscle length vs force for cardiac muscle. Label the axis and the lines.

Answer 26

Active line - up, curve, then down
passive line - diagonal, goes upwards

• X – muscle fibre length
• Y – force

Question 27

b) Draw out the myosin and actin filaments at the start, middle and end.

Answer 27

• Muscle relaxed at A – little overlap of actin and myosin

* Fully contracted at C – maximum overlap

Question 28

c) Which part of the curve is relevant for cardiac muscle in vivo?

Answer 28

The ascending part – cardiac muscle is more resistant to stretch due to the pericardial sac

Question 29

c) What does the frank-starling relationship mean?

Answer 29

Increased diastolic fibre length increases ventricular contraction (more preload equals greater stroke volume).

Question 30

d) In the cardiac cycle, where is it i) isometric contraction; ii) isotonic contraction?

Answer 30

i) Isovolumic contraction

ii) rapid ejection, reduced ejection, atrial systole (ventricular ejection)

Question 31

e) Name two properties of the myofilaments which are responsible for the Frank-Starling laws of the heart (2)

Answer 31

Length changing of sarcomere: 1. The number of cross bridges that can form between actin and myosin relative to amount of overlap between the myofilaments (at optimum the actin and myosin filaments are stretched out to form the maximum number of cross bridges).
B) ‘Lattice spacing’ between them: with stretch you increase the probability of creating strong binding between actin and myosin heads so more force for same Ca.

Conformation change in troponin C which means it is more sensitive to Ca therefore less Ca required to produce same force.

Question 32

a) What would be the changes under parasympathetic stimulation to i) airways (2), ii) heart (1), iii) pulmonary vasculature

Answer 32

Airways – bronchoconstriction
Reduce heart rate
Vagal stimulation dilates the pulmonary vascular bed

Question 33

a) Name the changes and associated receptors when there is sympathetic stimulation to i) airways (1), ii) heart (2), iii) arterioles (1)

Answer 33

Airways – bronchodilation, relax SM beta2
Heart – increase heart rate + force beta1
Arterioles – vasoconstriction alpha1

Question 34

c) What are the effects of NO on i) smooth muscle in the airways, ii) arteriolar smooth muscle (2)

Answer 34

Smooth muscle airways = bronchodilation: increase airflow.

Arterioles = relaxation of arterioles causing vasodilation, inhibit growth of smooth muscle.

Question 35

An ECG strip is shown from aVF.

a) Which limb is the positive end of the lead shown attached to?

Answer 35

Left foot

Question 36

b) What is the angle of the positive end of Lead III?

Answer 36

120

Question 37

How do factor Va and VIIa accelerate blood coagulation?

Answer 37

• 7a catalyses factor 99a (and then 9a catalyses more factor 10a from 10).
• 7a catalyses 1010a: more 10a means more prothrombinthrombin.
• 5a is a COFACTOR for Xa which catalyses prothrombinthrombin.
• [NB: 8a is a COFACTOR for 9a which catalyses 1010a.]
• Thrombin therefore catalyses the reaction fibrinogenfibrin (fibrin plug formed).
• Thrombin generates 13a from F13 (cross bridges in fibrin)
• Thrombin generates more 5a + 8a.

Question 38

How are factors Va and VIIIa activated?

Answer 38

Trace amounts of thrombin activate Xa and XIIIa from their zymogen precursors.

Question 39

How are factors Va and VIIIa inactivated?

Answer 39

DIRECT: Antithrombin breaks down cofactors.
INDIRECT: Thrombin binds to thrombomodulin. Complexes with protein C and protein S (cofactor). This complex breaks down factor Va and XIIIa. (Therefore no more thrombin can be generated as Va is cofactor for Xa which catalyses prothrombin thrombin. XIIIa is a cofactor for IXa which catalyses XXa).

Question 40

What are the consequences for impaired activation of Va?

Answer 40

Disturbs haemostatic balance.
Va is not broken downstill active.
Va continues to act as cofactor for IXa which catalyses XXa.
Therefore excessive thrombin is formed (catalysed by Xa).
Thrombosis leading to venous thromboembolism. E.g. factor V lieden.
Fibrinogenfibrin. Blood is more likely to clot excessively/without need/without endothelial damage.
Blood clots may lead to thrombosismay embolise causing PE or may lodge in arteries causing an infarction (myocardial, brain).

Question 41

Write down the anatomical positions of the ECG chest electrodes as placed on the body.

Answer 41

V1: Right 4th ics next to sternum
V2: Left 4th ics next to sternum
V3: Left 5th ics between V2 and V4
V4: Left 5th ics at mid clavicular lin
V5: Left 5th ics at anterior-axilliary line
V6: Left 5th ics mid axillary line

Question 42

Name and briefly explain both of the mechanisms that are believed to be responsible for the phenomenon of autoregulation.

Answer 42

1. Myogenic - where the vascular smooth muscle of the arterioles contracts in response to being stretched. The vascular smooth muscle closest to the capillaries are the most sensitive. This mechanism is important for autoregulation in the kidney and skin
2. Metabolic - where a vasodilator substance is produced in the tissues and cleared by the blood. Higher blood flow lowers the concentration of the vasodilator in the tissue leading to increased resistance. The rate of production of the vasodilator is directly proportional to metabolism. This mechanism is important for autoregulation in the heart and skeletal muscle.

Question 43

Which of these statements about capillaries is true:
• Capillaries often contain smooth muscle
• Metabolically active tissues do not have many capillaries
• The kidneys contain only continuous capillaries
• Fenestrated capillaries are highly impermeable
• Discontinuous capillaries often allow proteins to cross the capillary wall.

Answer 43

Discontinuous capillaries often allow proteins to cross the capillary wall.

Question 44

Which of the following is NOT a mechanism by which capillaries optimise exchange:
•	Thin endothelium
•	Extensive capillary branching
•	High resistance
•	Dense networks in skeletal muscle
•	They have 80nM gaps throughout

Answer 44

• They have 80nM gaps throughout

Question 45

Atrial fibrillation:

a. is usually life-threatening
b. the atrial impulses often occur at 500 per minute or faster
c. becomes more common with increasing age
d. nearly always causes symptoms
e. increases the risk of stroke

Answer 45

increases the risk of stroke

Question 46

Valvular heart disease
the most important symptoms of aortic stenosis is palpitations (irregular heart beats)
mitral stenosis is often complicated by atrial fibrillation
atrial fibrillation increase the risk of systemic embolism
tricuspid regurgitation cause backpressure in the left atrium
the leaking mitral valve always needs to be replaced since it cannot be repaired

Answer 46

atrial fibrillation increase the risk of systemic embolism

Question 47

In the cardiac cycle, the period of isovolumic contraction:

a. starts with the first heart sound
b. produces an increase in pressure in the left ventricle that approaches aortic pressure
c. commences with the end of the QRS complex
d. forces blood into the aorta
e. follows the period of atrial systole

Answer 47

a. follows the period of atrial systole

Question 48

Describe the distribution of hypertension.

Answer 48

shape of curve of systolic BP of population – uniform distribution

Question 49

Name 2 causes of secondary hypertension:

Answer 49

• Renal artery stenosis
• Conn’s syndrome: excess production of aldosteroneby theadrenal glandsresulting in lowreninlevels.
• Oral contraceptive pill
• Liddle’s syndrome: excess reabsorption ofsodiumand loss ofpotassiumfrom therenal tubule.
• Pre-eclampsia

Question 50

1. Name 4 fatal diseases caused by hypertension:

Answer 50

• MI
• Heart Failure
• Stroke,
• Peripheral vascular disease
• Retinopathy
• Renal failure
• Atrial fibrillation
• Dementia

Question 51

What is the normal PR interval?

Answer 51

: 0.12-0.20s

Question 52

What is normal QT?

Answer 52

0.38-0.42s

Question 53

What is normal mean frontal plain axis?

Answer 53

-30 to 90