11 Gas Exchange in Humans Flashcards

Question 1

Q

Are gas exchange systems in all animals the same?

Answer

A

NO
The surfaces where gas exchange occurs in an organism are very different and different organisms have evolved different mechanisms for getting the gases to the gas exchange surface depending on size, where they live etc.

Question 2

Q

What do gas exchange features allow?

Answer

A

These features allow the maximum amount of gases to be exchanged across the surface in the smallest amount of time

Question 3

Q

What are the 4 main features of gas exchange surfaces?

Answer

A

Large surface area
Thin walls
Good ventilation with air
Good blood supply

Question 4

Q

How is a large surface area useful?

Gas Exchange Surfaces

Answer

A

to allow faster diffusion of gases across the surface

Question 5

Q

How are thin walls useful?

Gas Exchange Surfaces

Answer

A

to ensure diffusion distances remain short

Question 6

Q

How is a good ventilation with air useful?

Gas Exchange Surfaces

Answer

A

so that diffusion gradients can be maintained

Question 7

Q

How is a good blood supply useful?

Gas Exchange Surfaces

Answer

A

to maintain a high concentration gradient so diffusion occurs faster

Question 8

Q

Name the 8 structures of the respiratory system

Answer

A

ribs
intercostal muscle
diaphragm
trachea
larynx
bronchi
bronchioles
alveoli

Question 9

Q

Ribs definition

Answer

A

bone structure that protects internal organs such as the lungs

Question 10

Q

intercostal muscle definition

Answer

A

Muscles between the ribs which control their movement causing inhalation and exhalation

Question 11

Q

Diaphragm definition

Answer

A

Sheet of connective tissue and muscle at the bottom of the thorax that helps change the volume of the thorax to allow inhalation and exhalation

Question 12

Q

Trachea definition

Answer

A

Windpipe that connects the mouth and nose to the lungs

Question 13

Q

Larynx definition

Answer

A

Also known as the voice box, when air passes across here we are able to make sounds

Question 14

Q

Bronchi definition

Answer

A

Large tubes branching off the trachea with one bronchus for each lung

Question 15

Q

Bronchioles definition

Answer

A

Bronchi split to form smaller tubes called bronchioles in the lungs connected to alveoli

Question 16

Q

Alveoli definition

Answer

A

Tiny air sacs where gas exchange takes place

Question 17

Q

Why must there be two sets of intercostal muscles?

Answer

A

Muscles are only able to pull on bones, not push on them

This means that there must be two sets of intercostal muscles; one to pull the rib cage up and another set to pull it down

Question 18

Q

Where are the external intercostal muscles found?

Answer

A

One set of intercostal muscles is found on the outside of the ribcage (the external intercostal muscles)

Question 19

Q

Where are the internal intercostal muscles found?

Answer

A

The other set is found on the inside of the rib cage (the internal intercostal muscles)

Question 20

Q

What structure surrounds the trachea and bronchi?

Answer

A

Rings of cartilage surround the trachea (and bronchi)

Question 21

Q

Why are there rings of cartilage surrounding the trachea and bronchi?

Answer

A

The function of the cartilage is to support the airways and keep them open during breathing

Question 22

Q

What would happen if the rings of cartilage were not present around the trachea and bronchi?

Answer

A

If they were not present then the sides could collapse inwards when the air pressure inside the tubes drops

Question 23

Q

What are the passages down to the lungs lined with?

Answer

A

The passages down to the lungs are lined with ciliated epithelial cells

Question 24

Q

What do cilia do?

Answer

A

these cells have tiny hairs on the end of them that beat and push mucus up the passages towards the nose and throat where it can be removed

Question 25

Q

Where is mucus made?

Answer

A

The mucus is made by special mucus-producing cells called goblet cells

Question 26

Q

What is the role of the mucus?

Answer

A

The mucus traps particles, pathogens like bacteria or viruses, and dust and prevents them getting into the lungs and damaging the cells there

Question 27

Q

Describe the role of cilia and mucus

Answer

A

The mucus is produced by goblet cells and traps bacteria, dust, particles
The cilia beat
And push the mucus away from the lungs towards the throat
3 marks

Question 28

Q

WHat is the diaphragm responsible for?

Answer

A

it is ultimately responsible for controlling ventilation in the lungs

Question 29

Q

What happens during inhalation?

Answer

A

external intercostal muscles contract (pulls ribs)
ribcage moves up and out
diaphragm contracts and flattens
volume of thorax increases
air pressure inside thorax decreases relative to outside the body
air is drawn in

Question 30

Q

What happens during exhalation?

Answer

A

external intercostal muscles relax
ribcage moves down and in
diaphragm relaxes and becomes dome-shaped
volume of thorax decreases
air pressure inside thorax increases relative to outside the body
air is forced out

Question 31

Q

In what way do the the intercostal muscles work together?

Answer

A

The external and internal intercostal muscles work as antagonistic pairs (meaning they work in different directions to each other)

Question 32

Q

What happens when we need to increase the rate of gas exchange? What is this called

Answer

A

When we need to increase the rate of gas exchange (for example during strenuous activity) the internal intercostal muscles will also work to pull the ribs down and in to decrease the volume of the thorax more, forcing air out more forcefully and quickly – this is called forced exhalation

Question 33

Q

Why is forced exhalation needed?

Answer

A

There is a greater need to rid the body of increased levels of carbon dioxide produced during strenuous activity and to inhale more oxygen

This allows a greater volume of gases to be exchanged

Question 34

Q

Does inspired and expired air have a different amount of gases? Why?

Answer

A

YES
Air that is breathed in and air that is breathed out has different amounts of gases in it due to exchanges that take place in the alveoli

Question 35

Q

How much oxygen does atmospheric air have?

Answer

A

Atmospheric air contains around 20 – 21% oxygen

Question 36

Q

How much oxygen from atmospheric air do we absorb? How much do we exhale?

Answer

A

we only absorb around 4 – 5%, breathing out air containing around 16% oxygen

Question 37

Q

How much CO2 does atmospheric air have?

Answer

A

Normal carbon dioxide content of air is around 0.04%

Question 38

Q

How much CO2 is in expired air?

Answer

A

As carbon dioxide diffuses into the alveoli from the blood, we breathe out air containing around 4% carbon dioxide

Question 39

Q

What other substance, apart from O2 and CO2, do we expire?

Answer

A

The air we breathe out contains more water vapour than when we breathe it in

Question 40

Q

What is also different about expired air, apart from its gas content?

Answer

A

the temperature of exhaled air is higher than inhaled air

Question 41

Q

Why is the oxygen content in expired and inspired air different?

Answer

A

oxygen is removed from blood by respiring cells so blood returning to lungs has a lower oxygen concentration than the air in the alveoli which means oxygen diffuses into the blood in the lungs

Question 42

Q

Why is the carbon dioxide content in expired and inspired air different?

Answer

A

carbon dioxide is produced by respiration and diffuses into blood from respiring cells: the blood transports the carbon dioxide to the lungs where it diffuses into the alveoli as it in a higher concentration in the blood than in the air in the alveoli

Question 43

Q

Why is the water vapour content in expired and inspired air different?

Answer

A

water evaporates from the moist lining of the alveoli into the expired air as a result of the warmth of the body

Question 44

Q

Why is the nitrogen content in expired and inspired air different?

Answer

A

THERE IS NO DIFFERENCE -78%

nitrogen gas is very stable and so cannot be used by the body, for this reason its concentration does not change in inspired or expired air

Question 45

Q

What substance can be used to test for CO2?

Answer

A

Limewater

Question 46

Q

Using a setup of two test tubes, containing limewater and connected by rubber tubing, how could you test the content of CO2 in expired air?

Answer

A

When we breathe in, the air is drawn through boiling tube A

When we breathe out, the air is blown into boiling tube B

Question 47

Q

What change in the limewater would you see during this experiment?
(Using Limewater to Test for CO2 in Exhaled Air)

Answer

A

Lime water is clear but becomes cloudy (or milky) when carbon dioxide is bubbled through it
The lime water in boiling tube A will remain clear, but the limewater in boiling tube B will become cloudy

Question 48

Q

What does this experiment show us?

Using Limewater to Test for CO2 in Exhaled Air

Answer

A

This shows us that the percentage of carbon dioxide in exhaled air is higher than in inhaled air

Question 49

Q

What is the effect of exercise on breathing?

Answer

A

Exercise increases the frequency and depth of breathing

Question 50

Q

How can you Investigate the Effect of Exercise on Breathing?

Answer

A

This can be investigated by counting the breaths taken during one minute at rest and measuring average chest expansion over 5 breaths using a tape measure held around the chest
Exercise for a set time (at least 3 minutes)
Immediately after exercising, count the breaths taken in one minute and measure the average chest expansion over 5 breaths

Question 51

Q

What will be the results of this experiment? (Investigating the Effect of Exercise on Breathing)

Answer

A

Following exercise, the number of breaths per minute will have increased and the chest expansion will also have increased

Question 52

Q

Why does frequency and depth of breathing increase when exercising?

Answer

A

This is because muscles are working harder and aerobically respiring more and they need more oxygen to be delivered to them (and carbon dioxide removed) to keep up with the energy demand

Question 53

Q

What happens if, during exercise, the muscles cannot receive enough nutrients?

Answer

A

If they cannot meet the energy demand they will also respire anaerobically, producing lactic acid

Question 54

Q

Why does lactic acid need to be removed?

Answer

A

After exercise has finished, the lactic acid that has built up in muscles needs to be removed as it lowers the pH of cells and can denature enzymes catalysing cell reactions

Question 55

Q

How can lactic acid be removed?

Answer

A

It can only be removed by combining it with oxygen – this is known as ‘repaying the oxygen debt’

Question 56

Q

How can the time taken for a person to repay their oxygen debt be investigated?

Answer

A

This can be tested by seeing how long it takes after exercise for the breathing rate and depth to return to normal – the longer it takes, the more lactic acid produced during exercise and the greater the oxygen debt that needs to be repaid

Question 57

Q

What increases in amount during exercise?

Answer

A

As respiration rates increase, more carbon dioxide is produced and enters the blood

Question 58

Q

Why is carbon dioxide harmful?

Answer

A

Carbon dioxide is an acidic gas in solution and so it can affect the working of enzymes in the cells and needs to be removed as quickly as possible

Question 59

Q

How are high carbon dioxide levels detected?

Answer

A

As blood flows through the brain, the increase in carbon dioxide concentration stimulates receptor cells

Question 60

Q

What happens once the receptor cells have detected the high levels of CO2?

Answer

A

These send impulses to the muscles of the lungs, causing them to contract faster and more strongly

Question 61

Q

What does the lungs contracting faster and stronger do to CO2 levels?

Answer

A

This causes the frequency and depth of breathing to increase until the carbon dioxide concentration of the blood has lowered sufficiently

Question 62

Q

Respiration definition

Answer

A

Respiration is a chemical process that involves the breakdown of nutrient molecules (specifically glucose) in order to release the energy stored within the bonds of these molecules

Question 63

Q

In what two ways can respiration take place and what does this mean?

Answer

A

Respiration can take place with oxygen (aerobically) or without oxygen (anaerobically

Question 64

Q

Why is aerobic respiration more effective than anaerobic respiration?

Answer

A

Much less energy is released for each glucose molecule broken down anaerobically compared to the energy released when it is broken down aerobically

Answer 65

A

Respiration occurs in all living cells. Most of the chemical reactions in aerobic respiration take place in the mitochondria

Answer 66

A

Contract muscle
Synthesise proteins
Cell division (to make new cells)
Grow
Enable active transport to take place
Allow nerve impulses to be generated
Maintain a constant internal body temperature

Answer 67

A

Respiration is a series of reactions that are controlled by enzymes

Answer 68

A

Aerobic respiration requires oxygen and is defined as the chemical reactions in cells that use oxygen to break down nutrient molecules to release energy

Answer 69

A

YES

It is the complete breakdown of glucose to release a relatively large amount of energy for use in cell processes

Answer 70

A

It produces carbon dioxide and water as well as releasing useful cellular energy

Answer 71

A

C6H12O6 + 6O2 –> 6CO2 + 6H2O

Answer 72

A

We can investigate aerobic respiration in living organisms by measuring the amount of oxygen that they take from the air
This is done by measuring the change in volume in an enclosed tube containing the organisms

Answer 73

A

However, as they respire the organisms release carbon dioxide, which increases the gas volume
The carbon dioxide must therefore be removed from the tube using a chemical

Answer 74

A

soda lime or sodium hydroxide

Answer 75

A

Any small organisms can be used in the apparatus, including seeds or arthropods

Answer 76

A

The apparatus is known as a respirometer

Answer 77

A

The apparatus consists of two tubes, one containing the living organisms and the other with glass beads to act as a control

Answer 78

A

Once the apparatus has been set up, the movement of the coloured liquid towards the insect will give a measure of the volume of oxygen taken up by the insect for respiration

Answer 79

A

The reduction of volume in the tube increases pressure causing the coloured liquid to move

Answer 80

A

The distance moved by the liquid in a given time is measured will provide the volume of oxygen taken in by the insect per minute

Answer 81

A

A control is a duplicate experiment set up with the condition being investigated having been removed or neutralised in some way.

Answer 82

A

As they are not alive, they will definitely not be respiring. If the volume of oxygen decreases in the tube with the glass beads during the course of the experiment, then we know that the condition being investigated (respiration in living organisms) is not the cause of it.

Answer 83

A

A control helps to make your experiment valid.

Answer 84

A

To investigate the effect of temperature on the rate of respiration of germinating seeds the respirometer can be set up and the tubes submerged in a series of water baths set at different temperatures, eg 10℃, 15℃, 20℃, 25℃, 30°C

Answer 85

A

The seeds should be kept in the water bath for 15 minutes before the start of the experiment to ensure they have acclimated to the temperature

Answer 86

A

As respiration is an enzyme controlled reaction, it is unlikely to work faster beyond around 40℃ as the enzymes will denature

Answer 87

A

Anaerobic respiration does not require oxygen and is defined as the chemical reactions in cells that break down nutrient molecules to release energy without using oxygen

Answer 88

A

NO

It is the incomplete breakdown of glucose and releases a relatively small amount of energy for use in cell processes

Answer 89

A

It produces different breakdown products depending on the type of organism it is taking place in

Answer 90

A

Anaerobic respiration mainly takes place in muscle cells during vigorous exercise

Answer 91

A

When we exercise vigorously, our muscles have a higher demand for energy than when we are resting or exercising normally. Our bodies can only deliver so much oxygen to our muscle cells for aerobic respiration

Answer 92

A

as much glucose as possible is broken down with oxygen, and some glucose is broken down without it, producing lactic acid instead

Answer 93

A

There is still energy stored within the bonds of lactic acid molecules that the cell could use; for this reason, less energy is released when glucose is broken down anaerobically

Answer 94

A

glucose —> lactic acid

Answer 95

A

Lactic acid builds up in muscle cells and lowers the pH of the cells (making them more acidic)

Answer 96

A

This could denature the enzymes in cells so it needs to be removed

Answer 97

A

Cells excrete lactic acid into the blood

Answer 98

A

When blood passes through the liver, lactic acid is taken up into liver cells where it is oxidised, producing carbon dioxide and water

Answer 99

A

Lactic acid reacts with oxygen – this is actually aerobic respiration with lactic acid as the nutrient molecule instead of glucose

Answer 100

A

So the waste products of lactic acid oxidation are carbon dioxide and water

Answer 101

A

This is the reason we continue to breath heavily and our heart rate remains high even after finishing exercise – we need to transport the lactic acid from our muscles to the liver, and continue getting larger amounts of oxygen into the blood to oxidise the lactic acid
This is known as ‘repaying the oxygen debt’

Answer 102

A

We take advantage of the products of anaerobic respiration in yeast by using it in bread making (where the carbon dioxide produced helps dough to rise) and in brewing (where the ethanol produced makes beer)

Answer 103

A

glucose —> alcohol + carbon dioxide

Answer 104

A

C6H12O6 —> 2C2H5OH + 2CO2

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11 Gas Exchange in Humans Flashcards

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