Transport in Mammals (Chapter 8)

Question 1

What is the mammalian circulation system?

Answer 1

A closed double circulation consisting of a heart, blood vessels and blood

Question 2

What is the function of arteries?

Answer 2

To transport blood, swiftly and at high pressure, to the tissues, away from the heart

Question 3

What are the three layers of muscle in the walls of arteries and veins?

Answer 3

Tunica intima (an inner endothelium)
Tunica media
Tunica externa

Question 4

Describe the tunica intima

Answer 4

Very smooth, minimising friction with the moving blood

It is made up of flat cells (squamous epithelium) fitting together like jigsaw pieces

Question 5

What does the tunica media contain?

Answer 5

Smooth muscle, collagen and elastic fibres

Question 6

What does the tunica externa contain?

Answer 6

Elastic fibres and collagen fibres

Question 7

What are the distinctive characteristics of an artery wall?

Answer 7

Its strength and elasticity

Question 8

Why must artery walls be very strong?

Answer 8

To withstand the very high blood pressure of the blood leaving the heart

Question 9

How are artery walls strong?

Answer 9

They are thick

Question 10

How does the composition of the artery wall provide strength and resilience?

Answer 10

• (Nearer the heart) the tunica media contains large amounts of elastic fibres, allowing the wall to stretch as pulses of blood surge through at high pressure
• (Further from the heart) tunica media has fewer elastic fibres but more muscle fibres

Question 11

Why is the elasticity of artery walls important?

Answer 11

• It allows them to ‘give’, which reduces the likelihood that they will burst
• It allows artery walls to stretch as the high-pressure blood surges into them when the ventricles contract (reducing the pressure) and then recoil inwards as the pressure drops when the ventricles relax (giving the blood a little push)

Question 12

What are arteries called when they branch into smaller vessels?

Answer 12

Arterioles

Question 13

Describe the walls of arterioles

Answer 13

• Similar to arteries, but have a greater proportion of smooth muscle
• This muscle can contract, narrowing the diameter of the arteriole and so reducing blood flow, to help control the volume of blood flowing to different tissues at different times

Question 14

What is the function of capillaries?

Answer 14

To take blood as close as possible to all cells, allowing rapid transfer of substances between cells and blood

Question 15

What are capillary beds?

Answer 15

Networks of capillaries

Question 16

What are adaptations of capillaries?

Answer 16

Small size (approx 7μm in diameter) 
Extremely thin walls (one layer of endothelial cells)
Tiny gaps between endothelial cells

Question 17

Why is the small size of capillaries important?

Answer 17

• Allows them to bring blood as close as possible to each group of cells in the body as they are approx the same diameter as an RBC

Question 18

Why are the thin walls of capillaries important?

Answer 18

• RBCs are brought within 1μm of the cells outside the capillary, needing the oxygen

Question 19

Why are the gaps between the cells in capillary walls important?

Answer 19

• They allow some components of the blood to seep through into the spaces between the cells in all the tissues of the body, forming tissue fluid

Question 20

What is the function of veins?

Answer 20

To return blood to the heart

Question 21

What does the low blood pressure inside a vein mean for the vein?

Answer 21

• That there is no need for veins to have thick walls

- Their tunica media is much thinner than in arteries and has far fewer elastic fibres and muscle fibres

Question 22

How is blood returned to the heart if it has low blood pressure (e.g. from your legs) ?

Answer 22

• Many veins run within or close to several leg muscles, so when you tense these muscles, they squeeze inwards on the veins, temporarily raising the pressure
• Veins also contain semi lunar valves which allow blood to move towards the heart but not away, so the squeezing of muscles only squeezes it upwards

Question 23

What is plasma?

Answer 23

A pale yellow liquid in blood consisting of mainly water with other substances dissolved in it

Question 24

Give examples of solutes in blood plasma

Answer 24

Nutrients e.g. glucose
Waste products e.g. urea
Protein molecules - plasma proteins which always stay in the blood

Question 25

What is tissue fluid?

Answer 25

Leaked plasma between the cells in tissues which has leaked through the gaps in the cells of the capillary wall

Question 26

How is tissue fluid different from blood plasma?

Answer 26

• Far fewer protein molecules (too large to fit through gaps in capillary walls)
• No RBCs (but some WBCs)

Question 27

Why does plasma move out into tissue fluid at the arterial end of the capillary bed?

Answer 27

• The blood pressure inside the capillary is enough to push fluid out into the tissue (down a pressure gradient) and there is no change in water potential as proteins remain in the capillary
• The hydrostatic pressure is greater than the difference in water potential between the blood and tissue fluid

Question 28

Why does tissue fluid move back into capillaries at the venous end of the capillary bed?

Answer 28

• Water moves from high water potential to low water potential
• Since tissue fluid lacks the high concentrations of proteins that exist in plasma, and the pressure is lower, fluid moves into the capillaries from a higher water potential to a lower water potential

Question 29

Overall, does more blood flow into or out of capillaries?

Answer 29

Out of

Question 30

What is oedema, how is it caused and how is it avoided?

Answer 30

• Oedema is the build up of tissue fluid
• If blood pressure is too high, too much fluid is forced out of capillaries and may accumulate in the tissues
• One of the main roles of arterioles is to reduce the pressure of blood that enters the arterioles, in order to avoid this

Question 31

What is the muscle of which the heart is made called?

Answer 31

Cardiac muscle

Question 32

What do the coronary arteries do?

Answer 32

They branch from the aorta and deliver oxygenated blood to the walls of the heart itself

Question 33

What is the septum?

Answer 33

A wall of muscle in the heart, separating the right chambers from the left

Question 34

What is the left AV valve called?

Answer 34

Bicuspid (mitral) valve

Question 35

What is the right AV valve called?

Answer 35

Tricuspid valve

Question 36

What is your average heart rate?

Answer 36

70 beats per minute

Question 37

What is the cardiac cycle?

Answer 37

The sequence of events that makes up one heart beat

Question 38

What are the three stages of the cardiac cycle?

Answer 38

Atrial systole
Ventricular systole
(Ventricular) diastole

Question 39

What happens during atrial systole?

Answer 39

• The muscle in both of the atrial wall contracts
• The pressure developed is not very great, because the muscular walls of the atria are only thin, but it is enough to force the blood in the atria into the ventricles through the AV valves

Question 40

Why does blood from the atria not go back into the pulmonary veins or venae cavae?

Answer 40

Because these have semi lunar valves to prevent backflow

Question 41

What is another word for white blood cells?

Answer 41

Leucocytes

Question 42

Where are WBCs made?

Answer 42

In the bone marrow

Question 43

What is different about the structure of WBCs compared to RBCs?

Answer 43

• WBCs all have a nucleus
• Most WBCs are larger than RBCs (except lymphocytes)
• WBCs are either spherical or irregular in shape, never biconcave discs

Question 44

What is the function of haemoglobin?

Answer 44

• To carry and distribute oxygen in RBCs around the body

- It loads oxygen in the lung capillaries and unloads it in the tissue capillaries

Question 45

How many oxygen molecules can each haem group carry?

Answer 45

1

Question 46

How many oxygen molecules can a haemoglobin molecule carry at one time?

Answer 46

Up to 4 (8 atoms)

Question 47

What is the equation for the reaction of Hb with O2?

Answer 47

Hb + 4O2 <==> HbO8

Question 48

What does the term ‘partial pressure’ mean?

Answer 48

Concentration

Question 49

What is a dissociation curve?

Answer 49

The percentage saturation of Hb with oxygen plotted against the partial pressure of oxygen

Question 50

What does the Hb dissociation curve show?

Answer 50

• At low partial pressures of oxygen, the % saturation of Hb is very low (the Hb has combined with only a very little oxygen)
• At high partial pressures of oxygen, the % saturation of Hb is very high (the Hb has combined with large amounts of oxygen

Question 51

Why is the Hb dissociation curve S-shaped?

Answer 51

• When an oxygen molecule combines with a haem group, the whole Hb molecule is slightly distorted
• This distortion makes it easier for a second oxygen molecule oxygen molecule to combine with the second haem group (and the third and fourth/final)
• Therefore the curve rises steeply
• In this part of the curve, a small change in partial pressure of oxygen causes a very large change in the % saturation of Hb

Question 52

What is the Bohr effect?

Answer 52

The presence of a high partial pressure of CO2 causes Hb to release oxygen

Question 53

Why is the Bohr effect useful?

Answer 53

High concentrations of CO2 are found in actively respiring tissue, which need oxygen

Question 54

What are phagocytes?

Answer 54

WBCs that destroy invading microorganisms by phagocytosis

Question 55

What are the two types of phagocytes and what do they look like?

Answer 55

Neutrophils - most common, lobed nucleus, granular cytoplasm

Monocytes - less rounded, bigger, U-shaped nucleus

Question 56

What are lymphocytes?

Answer 56

WBCs that destroy microorganisms, some by secreting antibodies which attach to and destroy the invading cells

Question 57

What do lymphocytes look like?

Answer 57

Spherical, smaller, large nucleus

Question 58

What happens during ventricular systole?

Answer 58

• The thick, muscular walls of the ventricles squeeze inwards on the blood, increasing its pressure and pushing it out of the heart
• As soon as the pressure difference in the ventricles becomes greater than the pressure in the the atria, this pressure difference pushes the AV valves shut, preventing blood going back into the atria
• The blood rushes upwards into the aorta and pulmonary artery, pushing open the semi lunar valves

Question 59

Why doesn’t the high pressure blood flow back into the low pressure ventricles during ventricular diastole?

Answer 59

Because of the semi lunar valves in the aorta/pulmonary artery, which snap shut

Question 60

What happens during diastole?

Answer 60

• The whole of the heart muscle relaxes
• Blood from the veins flows into the two atria
• Some of the blood trickles downwards into the ventricles, as the AV valves open before atrial systole and because the pressure in the ventricles is lower than the pressure in the atria

Question 61

What does myogenic mean?

Answer 61

That it naturally contracts and relaxes, it does not need to receive impulses from a nerve to make it contract

Question 62

What does a double circulation system mean?

Answer 62

That the blood travels twice through the heart for one complete circuit of the body (through the systemic and pulmonary circulations)

Question 63

What does tissue fluid do?

Answer 63

• Forms the immediate environment of each individual body cell
• Exchanges of materials between cells and the blood occur

Question 64

How much fluid from the capillaries eventually seeps back into them?

Answer 64

About 90%

Question 65

How is the remaining 10% of fluid collected and returned to the blood system?

Answer 65

By a series of tubes - lymph vessels or lymphatics

Question 66

What are lymphatics?

Answer 66

• Tiny, blind-ending vessels, which are found in almost all tissues of the body
• They contain tiny valves, which allow the tissue fluid to flow in but stop it from leaking out

Question 67

Describe the structures of the valves in the lymph vessel walls and why this is important

Answer 67

• They are wide enough to allow large protein molecules to pass through
• Very important because such molecules are too big to get into the capillaries, and so cannot be taken away by the blood

Question 68

What is the fluid inside lymphatics called?

Answer 68

Lymph

Question 69

How is lymph different from tissue fluid?

Answer 69

Similar - diff place and diff composition

• in liver, both have high conc of protein
• in small intestine, both have high conc of lipid

Question 70

What do the lymphatics join up to form?

Answer 70

Lymph vessels - these transport the lymph back to large veins beneath the collarbone - subclavian veins

Question 71

What is the movement of fluid along the lymphatics caused and controlled by?

Answer 71

Contraction of muscles around the vessels

Valves keep it going in the right direction (like veins)

Question 72

What do lymph vessels have in their walls?

Answer 72

Smooth muscle

Question 73

Is lymph flow slow or fast compared to blood flow?

Answer 73

Slow

Question 74

What are located at intervals along the lymph vessels?

Answer 74

Lymph nodes

Question 75

What do lymph nodes do?

Answer 75

Involved in protection against disease
- bacteria and other unwanted particles are removed from lymph by some types of WBCs as the lymph passes through a node, whilst other WBCs within the nodes secrete antibodies

Question 76

What is other name for RBCS?

Answer 76

Erythrocytes

Question 77

What is the main function of haemoglobin?

Answer 77

To transport oxygen from the lungs to respiring tissues

Question 78

Describe the structure of RBCs

Answer 78

• Shaped like a biconcave disc
• Very small
• Very flexible
• No nucleus, mitochondria or ER

Question 79

Why are RBCs shaped like biconcave discs?

Answer 79

• To increase the SA:vol ratio which means that oxygen can diffuse quickly into or out of the cell

Question 80

Why are RBCs very small?

Answer 80

• Capillaries can be only 7μm wide, still allow RBCs to squeeze through them, so bringing oxygen as close as possible to cells which require it
• No Hb molecule is far from the CSM and the Hb molecule can therefore quickly exchange oxygen with the fluid outside the cell

Question 81

Why are RBCs very flexible?

Answer 81

• Some capillaries are even narrower than diameter of RBC

- Therefore the cells are able to deform so that they can pass through these vessels (bc of cytoskeleton)

Question 82

Why do RBCs have no nucleus, mitochondria or ER?

Answer 82

• The lack of these organelles means more room for Hb, maximising the amount of oxygen which can be carried by each RBC

Question 83

Describe the reaction which is catalysed by carbonic anhydrase and the reaction that follows

Answer 83

• CO2 + H2O <=> H2CO3

- H2CO3 <=> H+ + HCO3- (the carbonic acid dissociates)

Question 84

How does CO2 cause the release of oxygen (Bohr effect)?

Answer 84

• Hb readily combines with the H+ ions (formed from the second reaction - dissociation of carbonic acid) forming haemoglobinic acid (HHb)
• In doing so, it releases the oxygen which it is carrying
• The Hb ‘mops up’ the H+ ions which are formed when CO2 dissolves and dissociates

Question 85

How does Hb help to maintain the pH of the blood close to neutral?

Answer 85

• A high conc of H+ ions means a low pH - if the H+ ions were left in solution, the blood would be very acidic
• By removing the H+ ions from solution, haemoglobin helps to maintain the pH of the blood close to neutral
• It is acting as a buffer

Question 86

How does CO2 conc affect the saturation of haemoglobin with oxygen curve?

Answer 86

• A high conc means a lower curve

Question 87

How is CO2 carried in the blood (3 ways)?

Answer 87

1) As hydrogencarbonate ions (HCO3-) formed by the dissociation of carbonic acid in the cytoplasm of RBCs which diffuse out of the RBC into the blood plasma, where they are carried in solution (85%)
2) As CO2 molecules carried in solution (5%)
3) As carbaminohaemoglobin by combining directly with the terminal amine groups of some of the Hb molecules (10%)

Question 88

What is the significance of the oxygen dissociation curves of adult oxyhaemoglobin at different carbon dioxide concentrations (the Bohr effect)?

Answer 88

• At low partial pressures of oxygen, where oxygen is
  needed e.g. in active tissues, Hb will release oxygen
• At high partial pressures of oxygen e.g. in lung capillaries, where oxygen is not needed (but needs to be taken up by the Hb), Hb will not release oxygen, and will instead take it up

Question 89

What happens when blood reaches the lungs?

Answer 89

• The relatively low conc of CO2 in the alveoli compared with that in the blood, causes CO2 to diffuse from the blood into the air in the alveoli, stimulating the CO2 of carbaminohaemoglobin to leave the RBC, and HCO3- and H+ ions to recombine to form CO2 molecules once more
• This leave the Hb molecules free to combine with oxygen, ready to begin another circuit of the body

Question 90

What happens to the partial pressure of oxygen at high altitudes?

Answer 90

• At a height of about 6500m air pressure is much less
• Therefore the partial pressure of oxygen in the air drops from 20kPa at sea level to 10kPa and in the alveoli from 13 to 5.3

Question 91

What does high altitude mean for Hb?

Answer 91

• Haemoglobin becomes less saturated (about 70%) in the lungs and less oxygen will be carried around the body - the person mat begin to feel breathless and ill

Question 92

What happens if someone suddenly changes altitudes?

Answer 92

• They could develop altitude sickness with symptoms of an increase in the rate and depth of breathing and a general feeling of dizziness and weakness
• Can become more serious: arterioles in the brain dilate, increasing the amount of blood flowing into the capillaries, so that fluid begins to leak from the capillaries into the brain tissues - this can cause disorientation
• Fluid may also leak into the lungs, preventing them from functioning properly

Question 93

What happens if someone gradually acclimatises to high altitude over a few months?

Answer 93

• The number of RBCs in the blood increases from making up about 40-50% of the blood to as much as 50-70%
• This increases the amount of Hb in their blood so more blood can be carried around the body

Question 94

What adaptions do people who live permanently at high altitudes show?

Answer 94

1) Broad chests - providing larger lung capacities
2) Larger heart - especially on the right side which pumps blood to the lungs
3) More Hb in their blood than usual

Question 95

What is the largest artery in the heart?

Answer 95

The aorta - it branches to the head and then arches over downwards for the main flow towards the body

Question 96

What is the other main artery in the heart?

Answer 96

The pulmonary artery

Question 97

What are the two large veins that bring back blood from the head and from the body?

Answer 97

The venae cavae

Question 98

What are the other main veins in the heart?

Answer 98

The pulmonary veins - bringing blood back from the right and left lungs

Question 99

Why are the walls of the ventricles much thicker than the walls of the atria?

Answer 99

Because the ventricles need to develop much more force when they contract
- their contraction has to push the blood out of the heart and around the body

Question 100

Why is the wall of the right ventricle thinner?

Answer 100

• The force produced must be relatively small, because the blood goes only to the lungs, which are very close to the heart
• If too high a pressure was developed, tissue fluid would accumulate in the lungs, hampering gas exchange

Question 101

Why is the wall of the left ventricle thicker?

Answer 101

• It has to develop sufficient force to supply blood to the rest of the body organs
• For most of the organs, most of the time, the high pressures that the left ventricle is capable of producing would be too great and arterioles help to reduce this pressure before blood flows into the capillaries
• However, during vigorous exercise, when muscles are working hard, the arterioles supplying blood to them dilate, increasing blood flow
• The left ventricle must be able to develop enough force to ensure that there is still sufficient blood reaching other organs, especially the brain
• Kidneys require high pressure blood all the time, to carry out ultrafiltration

Question 102

Why does the heart have its own built in controlling and coordinating system?

Answer 102

• The individual heart muscle cells cannot be allowed to contract at their own natural rhythms
• If they did, parts of the heart would contract out of sequence with other parts, the cardiac cycle would become disordered and the heart would stop working as a pump

Question 103

Where is the cardiac cycle initiated?

Answer 103

In a specialised patch of muscle in the wall of the right atrium - the sinoatrial node (SAN or pacemaker)

Question 104

How does the SAN initiate the cardiac cycle?

Answer 104

• The muscle cells of the SAN set the rhythm for all the other cardiac muscle cells - their natural rhythm is slightly faster than that of the rest of the heart muscle
• Each time the muscles of the SAN contract, they set up a wave of electrical activity which spreads out rapidly over the whole of the atrial walls
• The cardiac muscle in the atrial walls responds to this excitation wave by contracting, at the same rhythm as the SAN
• Therefore, all the muscle in both atria contracts almost simultaneously

Question 105

What is the delay in the contraction of the ventricles after the contraction of the atria cause by?

Answer 105

• A feature of the heart that briefly delays the excitation wave in its passage from the atria to the ventricles
• There is a band of fibres between the atria and ventricles which does not conduct the excitation wave
• Therefore, as the wave spreads out from the SAN over the atrial walls, it cannot pass into the ventricle walls - the only route is via a patch of conducting fibres, situated in the septum, known as the atrioventricular node (AVN)

Question 106

What does the AVN do?

Answer 106

• It picks up the excitation wave as it spreads across the atria and, after a delay of about 0.1s, passes it on to a bunch of conducting fibres called the Purkyne tissue, which runs down the septum between the ventricles
• This transmits the excitation wave very rapidly down to the base of the septum, from where it spreads outwards and upwards through the ventricle walls
• As it does so, it causes the cardiac muscle in these walls to contract, from the bottom up, so squeezing blood upwards and into the arteries

Question 107

What is fibrillation?

Answer 107

When the heart wall simply flutters rather than contracting and then relaxing as a whole caused by the excitation wave becoming chaotic

Question 108

Describe pressure in atrial systole

Answer 108

The pressure of the blood is higher in the atrium than in the ventricle, and so forces the atrioventricular valve open

Question 109

Describe pressure in ventricular systole

Answer 109

The pressure of the blood is higher in the ventricle than in the atrium

Question 110

Describe pressure in ventricular diastole

Answer 110

The pressure of the blood in the arteries is higher than in the ventricles

Question 111

What is hydrostatic pressure?

Answer 111

The pressure that the blood is exerting on all of the blood vessels

Question 112

Why is the hydrostatic pressure lower further from the heart?

Answer 112

• Loss of fluid/blood plasma from the capillaries
• Capillary bed has a large volume overall, therefore lower pressure
• Reduced resistance to blood flow as there are more, smaller vessels