3.2.6 The Circulation of Blood and The Structure Of The Mammalian Heart

Question 1

What is the function of the circulatory system?

Answer 1

Transports raw materials from specialised exchange organs to body cells

Question 2

Describe the 2 circuits the circulatory system consists of

Answer 2

• 1 takes blood from heart to lungs, then back to heart
• Other loop takes blood around the rest of the body

Question 3

What the function of a vein?

Answer 3

Take blood back to heart under low pressure

Question 4

Describe the structure of a vein 4x

Answer 4

• Large lumen
• Very little elastic or muscle tissue = thin walls
• Contain valves to prevent blood flowing backwards
• Blood flow is helped by contraction of body muscles surrounding veins

Question 5

What is the function of arteries?

Answer 5

Carry oxygenated blood from heart to rest of body

Question 6

Describe the structure of arteries 2x

Answer 6

• Walls = thick, smooth muscular & have elastic tissue
• Endothelium (inner lining) is folded

Question 7

What does the walls of the arteries do and what does this help to do? (3)

Answer 7

• Stretches under high pressure
• Recoils under low pressure
• Helps to maintain blood pressure

Question 8

Arteries divide into smaller vessels called _____

Answer 8

arterioles

Question 9

What is the function of arterioles?

Answer 9

Control blood flow from arteries to capillaries

Question 10

Describe how arterioles control blood flow

Answer 10

• Muscles contracts & arterioles narrow to restrict blood flow to capillaries or relax to allow full blood flow

Question 11

Arterioles branch into _____

Answer 11

capillaries

Question 12

What is the function of capillaries?

Answer 12

Exchange substances between blood and body tissues

Question 13

Name 4 adaptations of capillaries for efficient diffusion

Answer 13

1. Found near cells in exchange tissues = short diffusion pathway
2. Walls = single layer of endothelium cells = shortens diffusion pathway
3. Large no. of capillaries & highly branched = increase SA for exchange
4. Narrow lumen so RBCs are squeezed flat against capillary
   
   • Reduces diffusion distance

Question 14

What are capillary beds?

Answer 14

Network of capillaries in tissue

Question 15

Capillaries have ___ between lining (endothelial) cells

Answer 15

gaps

Question 16

Why do capillaries have gaps between lining (endothelial) cells?

Answer 16

• They act as a sieve - controlling which molecules can leave the capillaries
• Allows WBCs to escape

Question 17

What is tissue fluid?

Answer 17

Fluid that surrounds cells

Question 18

What is tissue fluid made from?

Answer 18

Small molecules that leave blood plasma (e.g. oxygen, water and nutrients)

Question 19

Why doesn’t tissue fluid contain RBCs or big proteins?

Answer 19

∵ they’re too large to be pushed out through capillary walls

Question 20

What do cells do with tissue fluid?

Answer 20

They take in oxygen and nutrients from tissue fluid & release metabolic waste into it

Question 21

In capillary bed, substances move out of capillaries into tissue fluid, by ____ _____

Answer 21

pressure filtration

Question 22

Describe how substances move out of capillaries into tissue fluid by pressure filtration

Answer 22

1. At start/arterial end of capillary bed: hydrostatic (liquid) pressure inside capillaries > hydrostatic pressure in tissue fluid
2. Difference in hydrostatic pressure = pressure forces water/fluid + small molecules out of capillaries & into spaces around cells, forming tissue fluid
3. Loss of water/fluid = hydrostatic pressure reduces in capillaries ∴ hydrostatic pressure is lower at venule end
4. • there’s increasing conc. of plasma proteins ∴ Ψw at venule end is lower than Ψw in tissue fluid
5. Some water re-enters capillaries from tissue fluid at venule end by osmosis

Question 23

If asked about a particular end of the capillary, what do you need to do?

Answer 23

Compare hydrostatic pressure and osmotic pressure

Question 24

Explain how fluid leaves the capillary at the arterial end

Answer 24

Hydrostatic pressure is greater than osmotic effect which forces molecules/fluid out

Question 25

What within the bloodstream can affect the water potential?

Answer 25

Proteins

Question 26

If water moves out of the capillary, what happens to the water potential?

Answer 26

The water potential in the capillary will go down

(Proteins within bloodstream can affect the water potential)

Question 27

Water potential of blood plasma is more negative at venule end of the capillary than at arteriole end of capillary. Explain why. (2)

Answer 27

• Water has left the capillaries
• Proteins (in blood) are too large to leave capillary
  
  • Increasing conc. of blood proteins & thus water potential ↓

Question 28

What happens to excess tissue fluid?

Answer 28

It’s drained into lymphatic system

Question 29

What is swelling essentially?

Answer 29

Swelling → excess tissue fluid

Question 30

Describe the lymphatic system

Answer 30

• Network of tubes that acts like a drain
• Have a dead end

Question 31

Why does the lymphatic system tubes have dead end?

Answer 31

So pressure on them can only produce movement in one direction

Question 32

What does the lymphatic system do with the excess tissue fluid

Answer 32

• It transports excess tissue fluid and dumps it back into circulatory system
  
  • Drain their contents back into bloodstream via 2 ducts that join veins close to heart

Question 33

How is the content in lymphatic system moved?

Answer 33

By

• Hydrostatic pressure of tissue fluid that has left capillaries
• Contraction of body muscles that squeeze lymph vessels

Question 34

What do the valves in the lymph vessels ensure?

Answer 34

Fluid inside them moves away from tissues in direction of heart

Question 35

The heart consists of 2 ______ ____

Answer 35

Muscular Pumps

Question 36

What does the right side of the heart do?

Answer 36

pumps deoxygenated blood to lungs

Question 37

What does the left side of the heart do?

Answer 37

pumps oxygenated blood to whole body

Question 38

What is the functions of the atrioventricular (AV) valves?

Answer 38

Link atria to ventricles + stop blood flowing back into atria when ventricles contract

Question 39

Name and explain an adaptation of the ventricles

Answer 39

• Thicker walls than atria
• ∵ have to push blood out of heart whereas atria need to push blood a short distance → into ventricles

Question 40

Name and explain an adaptation of the left ventricle

Answer 40

• Thicker, more muscular walls than right ventricle
• ∵ needs to contact powerfully to pump blood all way round body
• (Whereas lungs are nearby right ventricle)

Question 41

What is the functions of the semi-lunar (SL) valves?

Answer 41

Link ventricles to pulmonary artery and aorta & stop blood flowing back into heart after ventricles contract

Question 42

What is the function of cords?

Answer 42

Attach AV valves to ventricles → stop them being forced up into atria when ventricles contact

Question 43

What does whether valves are closed or open depend on?

Answer 43

The relative pressure of heart chambers

Question 44

When are valves forced open?

Answer 44

Higher pressure behind valve

Question 45

When are valves forced shut?

Answer 45

Higher pressure in front of valve

Question 46

Name 3 stages in the cardiac cycle

Answer 46

1. Atrial Systole
2. Ventricular Systole
3. Diastole

Question 47

Describe Atrial Systole

Answer 47

1. Atria contract
2. ↓ volume of atria & ↑ atrial pressure increases
3. Blood is forced into the ventricles
4. Pressure in ventricles increase slightly as blood from atria is forced in

Question 48

Describe Ventricular Systole

Answer 48

1. Atria relax
2. Ventricles contract
3. ↓ their volume & ↑ ventricular pressure
4. As ventricular pressure rises above atrial pressure = AV valves close
5. Atria starts to refill and atrial pressure increases as the blood flows in
   
   • Blood returns to heart & atria fill again due to higher pressure in vena cava and pulmonary vein
6. As ventricular pressure is higher than aorta and pulmonary artery = forces open SL valves & blood is forced out into these arteries

Question 49

Describe Diastole

Answer 49

1. Ventricles relax and their pressure decreases
2. SL valves close as ventricular pressure drops below pressure in pulmonary artery and aorta
3. AV valves open as the ventricular pressures drops below atrial pressure
4. Blood starts to refill the ventricles
   
   • Allows blood to flow passively (without being pushed by atrial contraction) into ventricles from atria
5. Pressure increases slightly
6. Whole process then repeats

Question 50

When does the blood start flowing into the aorta? Explain why you have chosen that point.

Answer 50

At point A, ventricles are contracting (and AV valves are shut) forcing blood into the aorta

Question 51

Why is ventricular volume decreasing at point B?

Answer 51

Ventricles are contracting, reducing the volume of the chamber

Question 52

Are the semi-lunar valves open or closed at point C? Explain why.

Answer 52

Closed. The ventricles are relaxed and refilling, so the pressure is higher in pulmonary artery and aorta, forcing the SL valves closed.

Question 53

Why is the pressure higher in the left ventricle than the right (and in the aorta compared to the pulmonary artery)?

Answer 53

The left ventricle has a thicker wall than the right ventricle so it contracts more forcefully

Question 54

How is the cardiac cycle controlled?

Answer 54

By electrical activity

Question 55

Describe how the cardiac cycle is controlled by electrical activity

Answer 55

1. SAN generates waves of electrical activity across atrial walls causing atria to contract
2. Non-conducting tissue prevents waves of electrical activity from being passed directly from atria to ventricles
3. ∴ Waves of electrical activity go to ventricles via AVN
4. Delay at AVN allows atria to completely empty before ventricles contract
5. AVN sends waves of electrical activity down the bundles of His (on apex)
6. Purkinje tissue carries waves of electrical activity into muscular walls of ventricles
7. Ventricles contract from the bottom upwards

Question 56

State the formula for calculating cardiac output

Answer 56

Cardiac output = heart rate x stroke volume

[(Blood out per minute) = beats per minute x blood pumped in 1 beat]

Question 57

What does ‘P’ represent on the ECG (electrocardiogram)?

Answer 57

Atrial systole

Question 58

What letters represent ventricular systole on the ECG (electrocardiogram)?

Answer 58

QRS

Question 59

What letter represent diastole on the ECG (electrocardiogram)?

Answer 59

T

Question 60

Name 2 substances which are at a higher concentration in the blood at the arteriole end of the capillary than the venule end (1)

Answer 60

Glucose and oxygen

Question 61

Explain how fluid may be returned to the blood (3)

Answer 61

• The lymph vessels return the fluid to the blood
• Re-absorbtion by osmosis
• Proteins are retained in the blood capillary

Question 62

Suggest an explanation for the link between high blood pressure and the accumulation of tissue fluid (3)

Answer 62

1. High blood pressure = high hydrostatic pressure in capillaries ∴ forces out more fluid from capillary → accumulation of tissue fluid around cells
2. High blood pressure at venule end of capillary may reduce amount of fluid reabsorbed
3. Lymph system would not be able to drain all excess tissue fluid rapidly enough

Question 63

Suggest why tissue fluid accumulates more in the ankles and feet than in other parts of the body (2)

Answer 63

• Gravity would cause tissue fluid to accumulate in the ankles and feet
• Fewer lymph vessels in these areas

Question 64

Explain why a lack of protein in the diet causes swelling (3)

Answer 64

• Less protein in diet = less protein in blood
• Water potential of blood too high
• Water in tissue not drawn back into capillaries by osmosis
• Tissue fluid = stays in tissues = swelling

Question 65

Describe how veins being thin/having a large lumen help the blood flow at low blood pressure (2)

Answer 65

• Walls of veins are thin so can be compressed
• Large lumen/smooth lining to provide less resistance to flow