7 - Exchange Surfaces

Question 1

Why can’t fish breathe in and out via ventilation?

Answer 1

Water is denser, more viscous and has a lower oxygen content than air, so requires too much energy to be efficiently moved by a 2-way ventilation system

Question 2

Do prokaryotes need specialised exchange surfaces?

Answer 2

No as they are small enough to get the resources they need via osmosis, diffusion etc.

Question 3

Why do larger, eukaryotic organisms need specialised exchange surfaces?

Answer 3

Because they have greater metabolisms so need more resources and have lower SA:V ratios so cannot get all of these resources via simple diffusion, osmosis etc. as the substances need to travel further to get to our internal cells

Question 4

What are 4 things all good exchange surfaces should have/be?

Answer 4

1. Large surface area 2. Thin 3. Good ventilation 4. Good blood supply

Question 5

How does having a large surface area aid exchange surfaces?

Answer 5

Allows more substances to travel across at a time, increasing exchange rate

Question 6

How does being thin aid exchange surfaces?

Answer 6

Allows substances to travel across them more quickly, increasing exchange rate

Question 7

How does having a good blood supply aid exchange surfaces?

Answer 7

Allows optimal concentration gradient to be maintained by bringing/taking away substances quickly

Question 8

How does having good ventilation aid exchange surfaces?

Answer 8

Allows a steep concentration gradient to be maintained

Question 9

Why can a single-celled organism only reach a certain size?

Answer 9

Because any larger and it’s SA:V ratio would be too small for it to support its metabolism when only transporting materials via diffusion, osmosis etc.

Question 10

What is an exotherm?

Answer 10

A cold-blooded organism

Question 11

What is an endotherm?

Answer 11

A warm-blooded animal

Question 12

Why do mammals need excellent exchange surfaces?

Answer 12

Because they have large metabolisms

Question 13

What is the exchange surface area of the lungs?

Answer 13

Around 55-57 metres squared

Question 14

What is the biological name for the mouth?

Answer 14

The buccal cavity

Question 15

What is the purpose of the nasal cavity?

Answer 15

Increases the temperature and moisture content of inhaled air. It’s hairy, mucus-secreting lining also traps pathogens and irritants

Question 16

What is the membrane on the surface of the lungs called?

Answer 16

Pleural Membrane

Question 17

What are the muscles between the ribs called?

Answer 17

Intercostal muscles

Question 18

What is the sequence of airways that air passes down?

Answer 18

Mouth/Nostril—>Buccal/nasal cavity—>Trachea—>Bronchus—>Bronchioles—>Alveoli

Question 19

Which bones protect the chest cavity?

Answer 19

The ribs

Question 20

Why does the trachea have c-shaped rings of cartilage?

Answer 20

To prevent it from collapsing due to pressure changes in the lungs

Question 21

What two types of cells is the trachea lined by?

Answer 21

Goblet and Ciliated Epithelial cells

Question 22

What is the purpose of goblet cells?

Answer 22

They secrete mucus, which traps dust and microbes

Question 23

What is the purpose of ciliated epithelial cells?

Answer 23

They are adjoining to goblet cells, and use their cilia to sweep mucus and whatever is trapped within it out into the throat

Question 24

What is the structure of the bronchi?

Answer 24

Similar to the trachea and with rings of cartilage

Question 25

Which bronchioles have cartilage?

Answer 25

Those with a diameter greater than 1mm

Question 26

What is the purpose of smooth muscle cells contained in the walls of the bronchioles?

Answer 26

To allow them to dilate and constrict

Question 27

Are ciliated cells present in the bronchioles and alveoli?

Answer 27

No

Question 28

Is gas exchange possible in the bronchioles?

Answer 28

Some, through the flattened epithelial lining

Question 29

What is the diameter of alveoli?

Answer 29

200-300 micrometers

Question 30

What are the walls of alveoli made up of?

Answer 30

Squamous epithelial cells, some collagen and elastic fibres made from elastin

Question 31

What is the purpose of the elastic tissues in alveoli?

Answer 31

They allow the alveoli to stretch when air enters, and recoil in order to help force air out

Question 32

Where is lung surfactant found?

Answer 32

Coating the inside of alveoli

Question 33

What are the 2 purposes of lung surfactant?

Answer 33

Prevent the alveoli from collapsing and help prevent water loss

Question 34

What is the purpose of external intercostal muscles?

Answer 34

When they contract, they lift the ribcage up and out (during inhalation)

Question 35

What is the purpose of internal intercostal muscles?

Answer 35

They push the ribcage downwards and inwards during forced exhalation

Question 36

What 2 steps occur during inspiration?

Answer 36

1. Intercostals contract, making ribcage move upwards and outwards 2. Around the same time, diaphragm contracts and flattens

Question 37

What effect does the movements of the diaphragm and intercostal muscles have during inspiration?

Answer 37

Increases the volume of the chest cavity, causing its pressure to become lower than atmospheric pressure, meaning air moves into the lungs

Question 38

What 2 steps occur during expiration?

Answer 38

1. The intercostal muscles relax, making the ribcage move downwards and inwards 2. The diaphragm relaxes and expands into a dome shape

Question 39

What effect does the movements of the diaphragm and intercostal muscles have during expiration?

Answer 39

They decrease the volume of the chest cavity, causing its pressure to increase to more than atmospheric pressure and, with the help of the recoil of the elastic fibres in the alveoli, forcing air out of the lungs

Question 40

What are 3 methods of measuring the volume of gas drawn into the lungs?

Answer 40

1. A peak flow meter 2. A vitalograph 3. A spirometer

Question 41

What is a peak flow meter?

Answer 41

A plastic tube with an analog measuring device to record peak flow rate, which you blow into. Sharp exhalation needed.

Question 42

What is a vitalograph?

Answer 42

Essentially the same thing as a peak flow meter but with a digital data logger which produces a graph of force over time as well as ‘forced expiratory volume in 1 second’

Question 43

How does a spirometer work?

Answer 43

It is a lid bobbing on a tank of water. A person puts in a mouthpiece (whilst wearing a nose clip) attached to a tube which leads into the water. Their breathing thus causes the lid to bob up and down, and it is attached to a pen which creates a trace on a revolving drum of paper

Question 44

Why does a spirometer have a canister of soda lime?

Answer 44

To filter the CO2 from the user’s limited air supply so that they don’t suffer CO2 poisoning

Question 45

Why does a person using a spirometer wear a nose clip?

Answer 45

To ensure that the flow of air occurs only through their mouth, thus allowing for accurate readings

Question 46

What is tidal volume?

Answer 46

The amount of air which moves into and out of the lungs with each resting breath

Question 47

How much is the typical tidal volume for an adult?

Answer 47

~500cm^3, or around 15% of vital capacity

Question 48

What is vital capacity?

Answer 48

The amount of air that can be breathed in when the strongest possible exhalation is followed by the strongest possible inhalation

Question 49

What is the inspiratory reserve volume?

Answer 49

The amount of air you can breathe in over and above a normal inhalation

Question 50

What is expiratory reserve volume?

Answer 50

The extra amount of air you can force out of your lungs over and above the normal tidal volume of air you breathe out

Question 51

What is residual volume?

Answer 51

The volume of air left in your lungs when you have exhaled as hard as possible

Question 52

Can residual volume be measured directly?

Answer 52

No

Question 53

What is total lung capacity?

Answer 53

Vital capacity plus residual volume

Question 54

What is inspiratory capacity?

Answer 54

Total volume of air taken in by deepest possible inhalation following normal exhalation

Question 55

Why can’t fish breathe in and out by ventilation?

Answer 55

Because water is much denser and more viscous than air, and has a much lower oxygen content, so it saves energy for them to move water in 1 direction only

Question 56

Why do fish gills have a vivid red colour?

Answer 56

Because they contain many capillaries

Question 57

What happens when a fish opens its mouth?

Answer 57

The operculum closes over the gills, the buccal cavity expands and the opercular valve (to the outside) is closed. This means that the pressure in the mouth drops, and water rushes in

Question 58

What happens when a fish closes its mouth?

Answer 58

The cheeks move inward, causing pressure in the mouth to increase and forcing water over the gills, also causing the opercular valve and operculum to open

Question 59

Why can’t fish breathe in air?

Answer 59

Without water the gill structures collapse, meaning that their exchange surface area is not large enough to keep the fish alive.

Question 60

As well as increasing surface area, what is the secondary purpose of a fish’s lamallae?

Answer 60

To direct the flow of water in the gills

Question 61

What is the general structure of the gills in terms of gill arches, gill filaments and lamellae?

Answer 61

Cylindrical gill arch with arteries (containing deoxygenated blood) and vessels (taking oxygenated blood from the gills. These have 2 rows of gill filaments off them, which are have lamellae crossing them to increase surface area

Question 62

What, briefly, is the counter-current flow system and why is it used by fish?

Answer 62

It is where fish have blood flowing one way and water flowing the other. This is so that the concentration gradient of CO2 and oxygen is maintained throughout the gill, thus maximising the efficiency of diffusion

Question 63

What is a spiracle?

Answer 63

A small opening in the exoskeleton of an insect’s abdomen and thorax, which it uses to exchange gases with the atmosphere

Question 64

What is a spiracle sphincter?

Answer 64

The things which an insect uses to open and close its spiracles, allowing it to close them when oxygen demands are low to reduce water loss

Question 65

What are trachea (in insects)?

Answer 65

Small tubes (<1mm) which lead away from spiracles.

Question 66

How are insect spiracles kept open?

Answer 66

By spirals of the tough polysaccharide chitin

Question 67

What diameter are insect tracheoles?

Answer 67

0.6-0.8 micrometers

Question 68

What are insect tracheoles?

Answer 68

Smaller tubes which branch off from the trachea and run in between individual cells to give a very large surface area

Question 69

Do tracheoles have chitin?

Answer 69

No, in order to maximise gas permeability

Question 70

What is tracheal fluid?

Answer 70

Fluid found near the end of tracheoles. Gases can dissolve into it and then diffuse across to cells. However, it can also move out of the tracheoles by diffusion if necessary by osmosis (usually due to lactic acid buildup) to expose a greater surface area in them for diffusion to occur across.

Question 71

Apart from counter-current flow system, what is another adaption in fish which helps maximise gas exchange effectiveness?

Answer 71

The tips of their gill filaments overlap, increasing the resistance to the flow of water and slowing down water movement, helping maximise the time that diffusion can occur for

Question 72

What 2 adaptations do insects with high energy demands have to maximise gas exchange?

Answer 72

1. Some can actively pump air in and out of their body by moving their thorax and/or abdomen 2. Some have internal air sacs which can be inflated and deflated by movement of the thorax and abdomen in order to increase the volume of air which moves

Question 73

What are insect tracheoles?

Answer 73

Smaller tubes (0.4-0.6 micrometers in diameter) which branch off from trachea and run in between individual cells