3.1.2 - Transport in Animals

Question 1

Features of a good transport system

Answer 1

Fluid - to carry nutrients, O2 and waste products (blood)
Pump - create pressure to push fluid around body (heart)
Exchange surface - to allow substances to leave and enter the transport system (capillaries)
Tubes or vessels - to carry fluid by mass flow
Two circuits

Question 2

Single circulatory system

Answer 2

Blood flows through the heart and travels around the whole body once before returning

Question 3

Double circulatory system

Answer 3

Involves two separate circulations
Blood is pumped from the heart to lungs and then returns
Blood then flows through the heart and is pumped out to travel all around the body before returning

Question 4

Pulmonary circuit

Answer 4

Pick up oxygen

Question 5

Systemic circuit

Answer 5

Deliver oxygen

Question 6

Why is a single circulatory system less effective

Answer 6

As blood flows through gill capillaries, overall pressure decreases
Speed of flow decreases
Blood flowing to body will have a lower pressure and flow slower

Rate at which O2 and nutrients are delivered to respiring tissue and waste removed is limited

Question 7

Why is blood pumped to the lungs at a low pressure in a double circulatory system

Answer 7

As not to damage the capillaries in the lungs

Question 8

Tissues in artery

Answer 8

Folded endothelium
Elastic fibres
Smooth muscle
Collagen fibres

Question 9

Function of artery

Answer 9

Carry blood away from heart to tissue

Question 10

Function of elastic fibres

Answer 10

Composed of elastin and provides flexibility

Recoil artery wall to maintain pressure and even out surges to give a continuous flow

Question 11

Function of smooth muscle

Answer 11

Contracts and relaxes to change diameter of lum

Question 12

Function of collagen fibres

Answer 12

Provide structural support

Question 13

Function of arterioles

Answer 13

Link arteries and capillaries

Question 14

Tissues in arteriole

Answer 14

More smooth muscle

Less elastin

Question 15

Vasoconstriction

Answer 15

When the arteriole is constricted and blood cannot enter the capillary network so is diverted to core of body
Less heat is lost from the skin

Question 16

Vasodilation

Answer 16

When the smooth muscle in the wall of an arteriole is relaxed, blood flows through into the capillary bed. More heat can be lost from the skin

Question 17

Function of capillary

Answer 17

Enable exchange of material between the blood and tissue fluid

Question 18

Structure of capillary

Answer 18

One layer of endothelium cells
Similar diameter to RBC
Leaky epithelium
No tissues

Question 19

Structure of venule

Answer 19

Endothelium

Smooth muscle

Question 20

Adaptation of capillaries

Answer 20

Larger surface area - diffusion is faster
Slow movement of blood though them (one RBC at a time) means more time for exchange of materials
Walls are single endothelial cell thick - short diffusion pathway

Question 21

Function of venules

Answer 21

Link capillaries with veins

Several venules join to form a vein

Question 22

Function of endothelium

Answer 22

Allows blood to flow easily (reduces friction to blood flow)

Question 23

Structure of veins

Answer 23

Larger lumen - allow lower pressure, reduces resistance to flow 
Endothelium 
Elastic fibres 
Smooth muscle
Collagen fibres

Question 24

Function of veins

Answer 24

Transport deoxygenated blood at a lower pressure back to heart
Enable blood flow in only one direction - valves

Question 25

What type of valves do veins have

Answer 25

The majority have one way valves

Question 26

One-way valves

Answer 26

Flaps of the inner lining of the vein

If blood starts to flow backwards (gravity), valves close

Question 27

Why does being immobile increase the risk of a blood clot

Answer 27

Many of the bigger veins run between big, active muscles in the body (arms, legs)
When the muscles contract they squeeze veins, forcing blood towards the heart

Question 28

Open circulation

Answer 28

Fluid isn’t always contained within vessels

Question 29

How does open circulation work in animals that don’t have a pump

Answer 29

It relies on movements of the body

Question 30

How does open circulation work in insects

Answer 30

They have muscular pumping organs - a long tube that lies under the dorsal surface of the body
Blood enters the near through pores called ostia
The heart then pumps the blood toward the heart by peristalsis. Blood then pours out into the body cavity

Question 31

Open circulation in larger, more active insects

Answer 31

They have open ended tubes attached to the heart directing the blood to more active parts of the body

Question 32

Disadvantages of open circulatory system

Answer 32

Low bp and blood flow is slow
Circulation of blood is affected by body movement or lack of
Oxygenated and deoxygenated blood will mix

Question 33

Closed circulation

Answer 33

Blood stays entirely inside vessels - gives it high pressure
It is a separate fluid, tissue fluid, that bathes the tissues and cells

Question 34

Advantages of a closed circulatory system

Answer 34

High pressure so blood flows more rapidly
More rapid delivery of oxygen and nutrients
More rapid removal of carbon dioxide and other waste
Transport is independent of body movement

Question 35

What does the right side of the heart do

Answer 35

Pump deoxygenated blood to the lungs to be oxygenated

Question 36

What does the left side of the heart do

Answer 36

Pump oxygenated blood to the rest of the body

Question 37

External features of the heart

Answer 37

Cardiac muscle
Coronary arteries
Ventricles
Atria

Question 38

Role of the coronary arteries

Answer 38

Deliver oxygenated blood from the heart. If these arteries become constricted this can cause angina or myocardial infarction

Question 39

Bicuspid

Answer 39

Left Atrioventricular valve

Question 40

Tricuspid (try before you buy)

Answer 40

Right atrioventricular valve

Question 41

Pathway of blood from vena cavae

Answer 41

Vena cava —> right atrium —> tricuspid —> right ventricle —> pulmonary artery —> lung —> pulmonary vein —> left atrium —> bicuspid —> left ventricle —> semilunar valve —> aorta —> rest of body

Question 42

Function of vena cava

Answer 42

Deoxygenated blood from the body flows through the vena cava into the right atrium

Question 43

Aorta

Answer 43

Oxygenated blood is pumped from the left ventricle through the aorta and to the body

Question 44

Pulmonary vein

Answer 44

Oxygenated blood from the lungs flow through the pulmonary vein into the left atrium

Question 45

Pulmonary artery

Answer 45

Deoxygenated blood passes from the right ventricle to the pulmonary artery to the lungs

Question 46

Atrioventricular valves

Answer 46

These valves sit between atria and ventricles and prevent blood travelling back from ventricles to atria during ventricular systole

Question 47

Tendinous cords

Answer 47

These prevent the valves from turning inside out when the ventricle walls contract

Question 48

Semilunar valves

Answer 48

These are at the base of the pulmonary artery and aorta and prevent blood travelling back to the ventricles when it’s pumped out and the ventricles are relaxed

Question 49

Ventricular septum

Answer 49

A wall of muscle separating the ventricles from each other

Question 50

Thickness of walls in the heart

Answer 50

Atria - thin
Right ventricle - thicker than atria but thinner than left ventricle
Left ventricle - v. thick (2-3x thicker than right ventricle)

Question 51

Pressure in atria

Answer 51

Low - only needs to push blood to ventricles

Question 52

Pressure in right ventricle

Answer 52

Medium - only needs to pump to lungs (nearby). Alveoli could also be damaged by high blood pressure

Question 53

Pressure in left ventricle

Answer 53

Highest - blood needs to be pumped to the whole body and needs sufficient pressure to overcome the resistance of the systemic circulation

Question 54

Cardiac muscle structure

Answer 54

Consists of fibres that branch producing cross-bridges that help to spread the stimulus around the heart
Lot of mitochondria between myofibrils so supply energy for contraction

Question 55

What do cross-bridges ensure

Answer 55

That cardiac muscle can produce a squeezing action rather than a simple reduction in length

Question 56

What is blood composed of

Answer 56

Erythrocytes
Platelets
Leukocytes
Plasma

Question 57

Plasma

Answer 57

Composed of dissolved substances: 
Oxygen 
Carbon dioxide 
Glucose 
Minerals 
Amino acids 
Hormones 
Antibodies 
Plasma proteins

Question 58

Tissue fluid

Answer 58

Fluid that surrounds all cells and tissues. Between tissue fluid and cells that exchange of substances occurs

Question 59

What does tissue fluid contain

Answer 59

Plasma and dissolved substances
Neutrophils
Few proteins

Question 60

Why doesn’t tissue fluid have the same things in it as blood

Answer 60

Capillaries have small pores and not everything can fit through due to the size, therefore tissue fluid has less components than blood

Question 61

Hydrostatic pressure

Answer 61

This is the pressure that a fluid exerts when pushing against the sides of a vessel.

Question 62

When is hydrostatic pressure highest

Answer 62

The more fluid and the faster it is travelling will lead to a higher hydrostatic pressure

Question 63

Oncotic pressure

Answer 63

Pressure that solutes (e.g. plasma proteins) have when they draw water in by osmosis

Question 64

Why does oncotic pressure draw fluid from the tissue fluid into the capillaries

Answer 64

The capillaries contain large solutes

Question 65

Formation of tissue fluid

Answer 65

Hydrostatic pressure (caused by the heart) is high at the arteriole end
Greater than oncotic pressure
Leaky capillary wall allows plasma and some dissolved substances in but not RBC’s, proteins and some WBC’s (too large)
Tissue fluid surrounds body cells so exchange of gases and nutrients can occur across the plasma membrane (diffusion, facilitated diffusion and active transport)

Question 66

Why does tissue fluid return to the blood

Answer 66

Hydrostatic pressure lower at venous end and oncotic pressure is higher due to plasma proteins
Fluid returns to capillary at venous end

Question 67

Role of lymph

Answer 67

Drains excess tissue fluid out of the tissues. Lymph system rejoins blood circulation in the subclavian vein in the chest so this fluid is eventually all returned to the blood

Question 68

Lymph nodes

Answer 68

Swellings found at intervals along the lymphatic system which have an important part to play in the immune response

Question 69

Cells found in lymph

Answer 69

Lymphocytes

Question 70

Hydrostatic pressure in blood plasma

Answer 70

High

Question 71

Hydrostatic pressure in tissue fluid and lymph

Answer 71

Low

Question 72

Oncotic pressure in blood plasma

Answer 72

More negative

Question 73

Oncotic pressure in tissue fluid and lymph

Answer 73

Less negative

Question 74

Cardiac cycle

Answer 74

Atrial systole —> ventricular systole —> diastole

Question 75

Diastole

Answer 75

Muscular walls of all chambers are relaxed.
Elastic recoil causes chambers to increase in volume (lower pressure)
So blood flows into atria then ventricles (gravity)

Question 76

Atrioventricular valves in diastole

Answer 76

Open

Question 77

Semi lunar valves in diastole

Answer 77

Shut

Question 78

Atrial systole

Answer 78

Atria contract together
Ventricles are relaxed
Small increase in atrial pressure to push blood to ventricles
Ventricles stretch as they fill

Question 79

Atrioventricular valves in atrial systole

Answer 79

Open due to pressure gradient

Question 80

Semilunar valves in atrial systole

Answer 80

Shut

Question 81

Ventricular systole

Answer 81

Atria relax
Ventricles contract simultaneously
Contraction starts at apex of heart to push blood upwards
Huge increase in pressure forcing blood into aorta and pulmonary artery

Question 82

Atrioventricular valves in ventricular systole

Answer 82

Shut

Question 83

Semilunar valves in ventricular systole

Answer 83

Open

Question 84

When do the atrioventricular valves open

Answer 84

Diastole - pressure in ventricles drop below pressure in atria
Blood flowing from atria to ventricles force valves open

Question 85

When do the atrioventricular valves close

Answer 85

Ventricular systole - pressure in the ventricles rises above pressure in atria due to contraction

Question 86

When do the semilunar valves open

Answer 86

Ventricular systole - when ventricular pressure rises above atrial pressure

Question 87

When do the semilunar valves close

Answer 87

Diastole - ventricular pressure drops below the pressure in the major arteries

Question 88

Where is the pressure highest in the blood vessels

Answer 88

Aorta
Artery 
Arteriole 
Capillary 
Venule
Vein

Question 89

Why does blood pressure fluctuate in the aorta

Answer 89

Due to rhythmical contractions of cardiac muscle in the left ventricle
The troughs are caused by relaxation

Question 90

Why does pressure drop the further from the heart

Answer 90

The total cross-sectional area of the blood vessels further away from the heart gets larger as does the volume
Resistance to flow

Question 91

Why is heart muscle myogenic

Answer 91

It can initiate its own contraction

Question 92

What happens when the contractions of the chambers are not synchronised

Answer 92

This could cause inefficient pumping (fibrillation) so the heart needs a mechanism that coordinates heart contraction

Question 93

Initiation and control of the heartbeat

Answer 93

SAN (found at the top of the right atrium) - initiates a wave of excitation
Wave of excitation quickly spreads over walls of both atria (travels quicker on left, atria contract simultaneously - atrial systole)
Wave of excitation passes through AVN, delays impulse
Carried away from the AVN, down the bundle of His and down the purkyne fibres
Spreads out over walls of ventricles to apex

Question 94

Why does the AVN delay the wave of excitation

Answer 94

Allow the atria to finish contacting so the blood can fill the ventricles before they begin to contract
Maximising amount of blood pumped out

Question 95

Why do the ventricles contract from the base upwards

Answer 95

So the blood can be pushed up towards the major arteries

Question 96

ECG

Answer 96

Electrocardiograms - monitor the electrical activity of the heart

Question 97

What can ECG traces indicate

Answer 97

When part of the heart muscle is not healthy and therefore can be used to be diagnosed to diagnose heart problems

Question 98

How do ECG’s work

Answer 98

Attaching a number of sensors to the skin. The sensors picks up electrical excitation created by the heart and convert this into a trace

Question 99

Parts of ECG traces

Answer 99

P wave
QRS complex
T wave

Question 100

What do the P waves show

Answer 100

Atrial stimulation

Question 101

What does the QRS complex show

Answer 101

Ventricular stimulation

Question 102

What does T waves show

Answer 102

Diastole

Question 103

Tachycardia

Answer 103

High heart rate

Question 104

Bradycardia

Answer 104

Slow heart rate

Question 105

Atrial fibrillation

Answer 105

No clear P waves

Atria beating more frequently than ventricles

Question 106

Ectopic heart beat

Answer 106

Extra ventricular systole

Patient feels as if a heart beat has been missed

Question 107

The haem group has a high affinity for …

Answer 107

Oxygen

Question 108

Partial pressure

Answer 108

Relative pressure a gas contributes to a mixture of gases

Question 109

Transport of oxygen

Answer 109

Hb has a high affinity for O2 and binds reversibly with oxygen to give oxyhaemoglobin
Dissociates when the pO2 is low e.g. respiring tissues

Question 110

When does haemoglobin dissociate with oxygen

Answer 110

When the partial pressure of oxygen is low. Oxygen then dissolves in plasma and moves out of the capillaries as tissue fluid
RBC’s cannot leave capillaries

Question 111

Why is there low saturation of haemoglobin at low oxygen tensions

Answer 111

When haemoglobin isn’t bound to O2 haem groups in centre of molecules
More difficult for the O2 molecule to reach the haem group

Question 112

What happens when O2 tension rises

Answer 112

Diffusion gradient in haemoglobin increases
Eventually O2 molecule enters and associates with haem group
Causes conformational change, allowing haemoglobin to associate with three more O2 molecules easier
Curve levels off as haemoglobin reaches 100% saturation

Question 113

Why does fetal haemoglobin have a higher affinity than adult haemoglobin

Answer 113

It must be able to associate with O2 in an environment where the oxygen tension is low enough to make adult haemoglobin release O2

Question 114

What happens when O2 tension in placenta is low

Answer 114

Fetal haemoglobin binds to oxygen from surrounding fluid
Refuces O2 tension in placenta, more O2 diffuses from the mothers blood fluid into the placenta
Reduces O2 within mother’s blood, making maternal haemoglobin dissociate

Question 115

How does artery wall adapted to maintain pressure

Answer 115

Smooth muscle constricts to narrow lumen

Recoil pushes blood and maintains small lumen

Question 116

How is CO2 transported around the body

Answer 116

5% - dissolved in plasma
10% - combines with haemoglobin (carbominohaemoglobin)
85% - transported in hydrogencarbonate ions

Question 117

Formation of hydrogen carbonate ions

Answer 117

CO2 and H2O (carbonic anhydrase) —> carbonic acid

Question 118

What happens to HCO3- after they diffuse out of RBCs and dissolves to be carried into lungs

Answer 118

Chloride shift to maintain neutral charge

Question 119

Haemoglobinic acid

Answer 119

Formed when further H+ are taken out of solution by associating with haemoglobin

Question 120

What happens when pH drops in the RBC

Answer 120

Haemoglobin molecules change shape slightly and dissociate more readily from O2

Question 121

Why does increased CO2 reduce affinity of haemoglobin for O2

Answer 121

CO2 converts to HCO3-
Releases H+, lowers pH of cytoplasm
Alters tertiary structure of haemoglobin and reduces affinity

Question 122

Bohr effect

Answer 122

Increases CO2 conc. reduces haemoglobin affinity for O2
Actively repairing tissues produce more CO2 so more O2 is needed
More carbonic acid, more H+ in cytoplasm

Question 123

Bohr shift

Answer 123

Refers to the fact that O2 dissociation curve shifts down and to the right as CO2 conc increases

Question 124

Lymph

Answer 124

Excess tissue fluid that is not returned to the blood vessel

Question 125

What causes the ‘lub dub’ sound

Answer 125

Closing of the AV valves

Question 126

How do blood vessels maintain pressure

Answer 126

Narrow folded lumen in artery
Elastic fibres recoil
Smooth muscle contracts to constrict vessels

Question 127

How do blood vessels withstand pressure

Answer 127

Collagen provides structural support

Elastic fibres stretch

Question 128

Why do we form adult haemoglobin

Answer 128

So the conc. gradient is maintained if the baby has a child

Fetal haemoglobin will not readily dissociate to release O2 for actively respiring tissues

Question 129

What happens to H+ ions after H2CO3 dissociates

Answer 129

H+ ions build up in RBC, pH decreases
Affects 3’ structure
Affinity for O2 decreased
Oxyhaemoglobin dissociates into Hb and O2

Question 130

Haemoglobinic acid

Answer 130

Unsaturated Hb binds with H+

Restores pH

Question 131

HbO8

Answer 131

Saturated haemoglobin
4 haem groups -> each bind to an O2 molecule
Releases 4 O2 —> taken to plasma then respiring tissues

Question 132

Disadvantage of haemoglobin not having membrane bound organelles

Answer 132

Limited life span (cannot undergo mitosis)
Limited respiration
No protein synthesis

Question 133

Why don’t erythrocytes use any of the oxygen it is transporting

Answer 133

Erythrocytes lack mitochondria so do not respire aerobically
Moved by mass flow so needs less ATP for metabolic processes

Question 134

Why does blood off load more oxygen to actively respiring tissues than to resting tissues

Answer 134

More CO2
Lowered affinity of Hb for O2
Dissociation of carbonic acid
More oxygen released at same pO2

Question 135

Calculating cardiac output

Answer 135

Heart rate * stroke volume