cardio vascular

Question 1

what is blood flow determined by?

Answer 1

pressure and resistance.
p/r

Question 2

what side of the heart has oxygenated blood?

Answer 2

left side

Question 3

what does the myocardium do?

Answer 3

contracts to generate force and pump blood.

Question 4

what side of the heart wall is thicker?

Answer 4

the left, because it needs to pump blood around the body.

Question 5

what do heart valves do?

Answer 5

keep the blood flowing one way.

Question 6

where does the semilunar sit?

Answer 6

between the ventricles and arteries. pulmonary valve (right) and aortic valve (left)

Question 7

what are the two atrioventricular valves called?

Answer 7

Bicuspid/mitral valve (left) * Tricuspid (right).

Question 8

what is the SA node

Answer 8

the pacemaker of region of the heart, produces action potentials to generate heart beat. on right artium.

Question 9

what does the P-wave represent.

Answer 9

Action potential spreading through atria and depolarising of atria.

Question 10

what does the QRS represent?

Answer 10

action potential spreading through the AV bundle then to the ventricles. causing contraction of ventricles, having ventricular depolarisation.

Question 11

what does the T-wave represent?

Answer 11

the repolarisation of the ventricles.

Question 12

how is the ECG measured?

Answer 12

electrocardiogram

Question 13

what is diastole?

Answer 13

relaxation of the ventricles, 2/3 of the cardiac cycle. ventricles relax and fill with blood.

Question 14

what is systole?

Answer 14

1/3 cardiac cycle. Ventricle contract and pump blood out of the heart.

Question 15

what does the start of the cardiac cycle look like?

Answer 15

all four chambers of the heart relaxed. SA node generates action potential. AV valves are open with blood flowing into the ventricle as the pressure is higher in the atria. Whereas the pressure in the arteries is higher then the ventrcile causing the semilunar valves to be shut.

Question 16

step 2

Answer 16

isovolumetric contraction - systole.
- action potential spreads down the AV bundle and ventricles = ventricle depolarise causing them to contract. increasing the pressure in the ventricles becoming higher then the atria. AV valve closes. no volume change = isovolumetric.

Question 17

step 3

Answer 17

ventricular ejection - systole.
ventricles depolarise; continue to contract.
Semilunar valves open allowing blood to pass through to the arteries.

Question 18

stroke volume

Answer 18

the amount of blood being pushed out of the ventricle is known as the stroke volume.
In healthy adult SV is around 70mL at rest. 50-60% pumped out.

Question 19

step 4

Answer 19

Isovolumetric relaxation – diastole
Ventricles repolarise = T-wave.
Ventricles relax.
Pressure in the ventricles decreases as blood is ejected.
- Ventricle pressure drops lower than the arteries and the semilunar valves close.
Pressure drops in ventricles with no volume change = isovolumetric.

Question 20

step 5

Answer 20

Ventricular filling 1 – diastole.
All chambers are repolarised/relaxed.
Pressure in the ventricles drop back below pressure in atria.
- AV valves open. Semilunar valves closed.
Ventricles start to fill with blood, passive filling of ventricle.

Question 21

what is heart beat sound 1

Answer 21

The first sound “lub” happens with closing of the AV valves as the ventricles contract.
- This happens following the QRS complex on the ECG.

Question 22

heart beat sound 2

Answer 22

The second heart sound “dub” happens with closing of the semilunar valves as the ventricles relax.
- This happens following the T-wave on the ECG.

Question 23

cardiac output

Answer 23

Amount of blood we pump in one minute.
Heart rate x stroke volume.
In an average adult CO is around 5L/min at rest.

Question 24

what is flow determined by?

Answer 24

F= P/R. P = pressure. R = resistance.

Question 25

where is pressure higher venous system or arteries?

Answer 25

arteries. blood has further to travel and has to pass through smaller blood vessles.

Question 26

how is pressure gradient determined?

Answer 26

p1-p2.

Question 27

what is resistance proportional to?

Answer 27

fluid viscosity (n) how thick blood is
blood vessel length (l)

Question 28

what is resistance inversely proportional to?

Answer 28

blood vessel radius (r) (big difference with the power of 4)

Question 29

different blood flow in vessels.

Answer 29

laminar flow = smooth
turbulent flow = distructued, plaque developing on vessel walls.
Turbulence increases resistance and reduces flow.

Question 30

arteries anatomy

Answer 30

carry blood away from heart. carry both deoxygenated and oxygenated blood. have thick walls and large diameters. combination of elastic tissue and smooth muscle. low resistance.

Question 31

what do elastic arteries do?

Answer 31

allow for change in blood flow. reduce fluctuation. to provide steady blood flow to the body. this happens by the aorta getting a large volume of blood and being able to stretch like a balloon to always have blood to pump out. highly compliant.

Question 32

muscular arteries.

Answer 32

contain smooth muscle. distribute blood to skeletal muscle and internal organs through arterioles.

Question 33

arteriole anatomy

Answer 33

contain smooth and endothelim. change size and diameter to maintain blood flow.

Question 34

how does pulse pressure chnage around the body?

Answer 34

decrease as you get further away from the heart. pressure gradient. peaks because of the pumping of the heart.

Question 35

how to get pulse pressure (PP)

Answer 35

SP - DP.

Question 36

mean arterial blood pressure

Answer 36

(MABP) = DP + 1/3 x PP. Why 1/3? Since more of the cardiac cycle is spent more in diastole. Mean pressure is closer ot DP.

Question 37

what is the main way to alter flow and resistance?

Answer 37

change the radius of the vessel.

Question 38

vasodilation

Answer 38

blood vessels become wider.

Question 39

Physiological vasodilators: (4)

Answer 39

Adrenaline acting on beta (β) receptors in vessels * Increased nitric oxide (NO) release by endothelium * Atrial natriuretic peptide (ANP) * Local increases in CO2 levels.

Question 40

Vasoconstriction

Answer 40

blood vessels become narrower.

Question 41

Physiological vasoconstrictors: (3)

Answer 41

Adrenaline acting on alpha (α) receptors in vessels * Endothelin-1 (ET-1) release by endothelium * Vasopressin (ADH) and angiotensin II * Local increases in O2 levels

Question 42

what is filtration and what is it determined by?

Answer 42

movement of fluids. Determined by the balance of
- Capillary hydrostatic pressure (CHP)
- Blood colloid osmotic pressure (BCOP)

Question 43

what is CHP?

Answer 43

blood pressure within the capillaries. the driving force to push fluid out of the blood stream.

Question 44

what is BCOP?

Answer 44

osmotic pressure within the blood. force pulls fluid into the bloodstream to even it out.

Question 45

what is net filtration pressure (NFP)

Answer 45

The balance between BCOP and CHP. starts at the arteriole and ends at the venules.

Question 46

what happens when CHP>BCOP,

Answer 46

filtration occurs = positive NFP. Out of the blood.

Question 47

what happens when CHP<BCOP

Answer 47

reabsorption occurs = negative NFP. Into the blood.

Question 48

When CHP = BCOP

Answer 48

no net movement occurs. Things do move in and out but they balance out.

Question 49

diffusion in the blood is determined by…

Answer 49

concentration gradient - from high to low concentration.
solubility and size - Lipid-soluble molecules can diffuse through the cell membrane (co2 or o2).
Small non-lipid soluble molecules can pass through pores (e.g.) ions. Still down concentration gradient.
Large non-lipid soluble molecules must be transported in vesicles (e.g. proteins).

Question 50

venules

Answer 50

collect blood from the capillary beds. smallest venous vessels.

Question 51

veins.

Answer 51

carry blood back to the heart. highly distensible - can change their volume easily. can release or store blood in response to pressure change.

Question 52

how much blood does the average adult have?

Answer 52

5L.

Question 53

how is our blood broken up?

Answer 53

55% plasma. 45% solids.

Question 54

red blood cells.

Answer 54

the largest component of formed elements. major function is to carry oxygen-bound to haemoglobin. average lifespan is 120 days.

Question 55

white blood cells.

Answer 55

account for 0.1% of all blood. critical in the bodys immune.

Question 56

five types of white blood cells.

Answer 56

neutrophils 50-70% engulf pathogens and debris.
lymphocytes 20-40% - defend against specific pathogens or toxins.
monocytes 2-8% - become macrophages.
eosinophils 2-4% - engulf foreign material.
basophils <1% - release chemicals in damaged tissue.

Question 57

platelets

Answer 57

<0.1% of formed elements in blood.
Clump together and stick to damaged blood vessel walls.
Release chemicals to trigger blot clotting
Key component of haemostats.

Question 58

where does the innervation for both the parasympathetic and sympathetic pathways originate?

Answer 58

the medulla oblongata of the brainstem. The sympathetic pathway originates in the cardio accelerator centre.
Parasympathetic pathways originate in the cardioinhibitory centre.

Question 59

how does the sympathetic nerve system effect heart rate?

Answer 59

increases it. By releasing noradrenaline which binds to B receptors in the heart. which then reduces the resting repolarisation of the cells. cells reach the threshold faster which makes more action potentials. increasing the heat rate.

Question 60

how does the sympathetic nerve system effect the stroke volume?

Answer 60

b receptors activation increases the amount of force produced during contraction. atria and ventricles contract harder. stroke volume increases.

Question 61

parasympathetic nerve activity - Release acetylcholine which causes potassium channels to open. how does this effect the SA Node

Answer 61

• K channel activation hyperpolarisation the nodal cells
• Cells reach threshold slower = fewer action potentials
• Heart decreased.

Question 62

parasympathetic nerve activity - Release acetylcholine which causes potassium channels to open. how does this effect the Atrial myocardium.

Answer 62

• Atria contracts less
• Less filling of the ventricles
• Stroke volume decreases.

Question 63

how does the Sympathetic vasomotor nerves innervate arterioles?

Answer 63

• Release noradrenaline onto the smooth muscle cells of the blood vessel.
• Activate a-adrenergic receptors.
  = Vasoconstriction

Question 64

what is postural hypotension

Answer 64

when your blood pressure drops when you go from lying down to sitting up, or from sitting to standing. less blood to fill the ventricles = lower stroke volume and reduced cardiac output.

Question 65

Responding to exercise.

Answer 65

To meet increased metabolic demand during exercise, cardiac output must increase.
Heart rate x stroke volume.

Question 66

what is our heart rate at rest

Answer 66

60-100bpm

Question 67

how does our heart rate react to exercise?

Answer 67

increases to 3x, beacuse increase in sympathetic and decrease in para to SA node.

Question 68

stroke volume at rest

Answer 68

around 70mL

Question 69

what happens to stroke volume during exercise.

Answer 69

increases 2x. because: increase sympathetic to ventricle and increase venous return more filling.

Question 70

resting cardiac output

Answer 70

around 5L/min

Question 71

what happens to cardiac output during exercise

Answer 71

increases by 6x.