bio test mas transport

Question 1

What happens in the pulmonary circulatory system?

Answer 1

1. Deoxygenated blood is pumped out of the heart via the pulmonary arteries to the lungs.
2. oxygenated blood is returned to the heart via the pulmonary vein from the lungs.

Question 2

What happens in the systemic circulatory system?

Answer 2

• Oxygenated blood is pumped out of the heart via the aorta to most body tissues.
• Other blood vessels branch from the aorta to deliver blood.
• Veins collect deoxygenated blood.
• Deoxygenated blood is returned to the heart via the vena cava.

Question 3

What occurs in gas exchange?

Answer 3

• Carbon dioxide rich air moves out of the alveoli while oxygenated air moves in (ventilation).
• The oxygen diffuses into the bloodstream through simple diffusion.

Question 4

What is a double system?

Answer 4

• Blood passes through the heart twice per unit.

Question 5

How does the heart function?

Answer 5

Deoxygenated blood enters the right atrium from the vena cava. Blood moves into the right ventricle. Blood is pumped into the pulmonary artery. The pulmonary artery carries deoxygenated blood to the lungs. The blood becomes oxygenated in the lungs. Oxygenated blood leaves the lung via the pulmonary vein. Blood enters the left atrium. Blood moves into the left ventricle. Blood is pumped into the aorta, which carries oxygenated blood around the body.

Question 6

What is the purpose of the pulmonary artery?

Answer 6

To carry deoxygenated blood to the lungs.

Question 7

What is the purpose of the aorta?

Answer 7

• To carry oxygenated blood to the body.

Question 8

What is the purpose of the atrioventricular valves?

Answer 8

• Unidirectional flow of blood (prevents backflow).
• Open when the pressure is higher in the atrium than in the ventricle.

Question 9

What is the purpose of the semilunar valves?

Answer 9

• They open when the pressure is greater in the ventricles than in the blood vessels.
• Prevent backflow.

Question 10

How does haemoglobin transport oxygen?

Answer 10

1. Red blood cells contain haemoglobin, which has 4 haem groups.
2. In the capillaries in the lungs, oxygen binds to iron in haem groups, forming oxyhaemoglobin.
3. Each haemoglobin molecule can carry 4 oxygen molecules, one per haem group.
4. Oxyhaemoglobin can be transported via blood to respiring body tissues.
5. At body cells, oxygen dissociates from haemoglobin.

Question 11

What factors affect haemoglobin concentration in the blood?

Answer 11

• Oxygen concentration or partial pressure of oxygen (pO2).

Question 12

How does pO2 affect haemoglobin saturation?

Answer 12

• Higher pO2 means that haemoglobin has a high affinity for oxygen and binds with it.
• Lower pO2 means haemoglobin has a low affinity for oxygen and releases it.

Question 13

How does haemoglobin saturation change depending on how much oxygen is bound to it?

Answer 13

• When haemoglobin binds with one oxygen, it changes shape so it becomes easier to bind another oxygen.
• When haemoglobin is mainly saturated with oxygen, it is harder for more oxygen to bind.

Question 14

What is the difference between fetal haemoglobin and adult haemoglobin?

Answer 14

• The fetus needs to obtain oxygen from the mother’s blood.
• Fetal haemoglobin has a higher oxygen affinity than the adult haemoglobin found in the mother’s blood.
• This allows the oxygen to dissociate from the mother’s haemoglobin and bind to haemoglobin in the fetal blood.
• This ensures that the fetus gets enough oxygen to survive while it develops.

Question 15

How does the pressure of CO2 affect haemoglobin saturation?

Answer 15

• Higher CO2 at respiring tissues causes haemoglobin to release oxygen.
• Bohr effect decreases affinity for oxygen in haemoglobin when CO2 is present.
• This means the oxygen saturation of haemoglobin is lower for a given pCO2 when pCO2 is higher.

Question 16

Why do multicellular organisms need transport systems?

Answer 16

• Too big for simple diffusion as the diffusion distance would be too large.
• Have a higher metabolic rate.
• Large number of active cells.

Question 17

What is a closed system?

Answer 17

• Blood is contained in blood vessels.

Question 18

Why do the ventricles have thicker walls than the atria?

Answer 18

• The atria only need enough pressure to pump blood a distance into the ventricles.
• The ventricles need a lot of pressure to pump blood a long distance.

Question 19

Why is the left ventricle wall thicker than the right ventricle wall?

Answer 19

• The right ventricle only pumps to the lungs but the left ventricle pumps to the body.

Question 20

What are the stages of the cardiac cycle?

Answer 20

• The cardiac cycle is the sequence of contraction and relaxation of the cardiac muscle in the walls of the heart: atrial systole, ventricular systole, and diastole.

Question 21

What happens in atrial systole?

Answer 21

• The ventricles relax and the atria contract.
• This increases the atrial pressure.
• The atrioventricular valves open.
• Blood flows into the ventricles.

Question 22

What happens in ventricular systole?

Answer 22

• The ventricles contract and the atria relax.
• The ventricular pressure increases.
• The semi-lunar valves open and the atrioventricular valves close.
• Blood flows into the arteries.

Question 23

What happens in diastole?

Answer 23

• The ventricles and atria relax.
• The semi-lunar valves close.
• Blood flows passively into the atria.

Question 24

What is cardiac output?

Answer 24

• The volume of blood pumped by one ventricle of the heart in one minute.

Question 25

How do you calculate the cardiac output?

Answer 25

- Measure the heart rate. - Measure the stroke volume (volume of blood pumped by the left ventricle during systole). - Calculate the cardiac output: heart rate x stroke volume.

Question 26

How are arteries adapted for blood flow?

Answer 26

- Collagen provides strength to prevent the vessel from bruising and maintains shape. - Elastic fibres contain elastin that lets them stretch and recoil to minimise changes in pressure. - Thick smooth muscle layer contracts/relaxes to control blood flow.

Question 27

What do arteries do?

Answer 27

Carry blood at high pressure away from the heart.

Question 28

What are arterioles?

Answer 28

Arterioles are smaller than arteries but with a comparatively larger lumen. Their walls have more smooth muscle and less elastin as they do not need to withstand such high pressures.

Question 29

What are vasoconstriction and vasodilation?

Answer 29

1. Vasoconstriction - Smooth muscle contracts, constricting the blood vessels and decreasing blood flow. 2. Vasodilation - Smooth muscle relaxes, dilating the blood vessels and increasing blood flow.

Question 30

What are capillaries?

Answer 30

- Capillaries form extensive networks between arterioles and venules, providing an area between blood and tissues where exchange of substances like gases and nutrients can occur.

Question 31

What are the adaptations of capillaries?

Answer 31

- Lumen is very narrow, allowing for blood cells to be close to body cells. - Walls are thin, allowing substances to be exchanged across a short distance by diffusion. - Highly branched, providing a large surface area for diffusion.

Question 32

What are veins?

Answer 32

- Vessels that carry blood to the heart at low pressures.

Question 33

What are the adaptations of veins?

Answer 33

- Collagen provides strength to prevent the vessel from bursting and maintaining vessel shape. - Little smooth muscle and elastic fibre are needed due to low pressure. - Valves to prevent the backflow of blood.

Question 34

What are venules?

Answer 34

- Venules are smaller than veins. They have very thin walls and very little smooth muscle. Both venules and veins have valves.

Question 35

What does blood consist of?

Answer 35

- Plasma. - Red blood cells. - White blood cells. - Platelets (clotting).

Question 36

What are the functions of blood?

Answer 36

- Transports oxygen and carbon dioxide. - Transports nutrients from digestion. - Transports waste for excretion. - Transports hormones. - Transports food from storage. - Transports clotting factors.

Question 37

What is tissue fluid?

Answer 37

- Tissue fluid fills spaces between cells. It is the site of diffusion between blood and body cells.

Question 38

What is the composition of tissue fluid?

Answer 38

- Has the same composition as plasma but: - No red blood cells. - Fewer proteins. - Fewer white blood cells.

Question 39

How is tissue fluid formed at the arteriole end of capillaries?

Answer 39

1. A high hydrostatic pressure, exerted by the force of the heart pumping, forces fluid out of capillaries. 2. This forms tissue fluid surrounding body cells.

Question 40

How is tissue fluid formed at the venule end of capillaries?

Answer 40

1. The hydrostatic pressure is lower. 2. Proteins in the blood exert a high oncotic pressure (osmotic pressure) in capillaries. 3. The water potential is lower in capillaries than in tissue fluid due to fluid loss. 4. Some tissue fluid moves back into the capillaries by osmosis.

Question 41

What is lymph?

Answer 41

- Lymph is the fluid that flows around the lymphatic system via lymph vessels.

Question 42

What is the composition of lymph?

Answer 42

- Same as tissue fluid but: - Less oxygen and nutrients. - More fatty acids. - More white blood cells.

Question 43

How is lymph formed and transported?

Answer 43

- Some tissue fluid doesn't re-enter capillaries from tissue fluid. - This fluid instead drains into lymph vessels (lymph capillaries), forming lymph. - Lymph is transported through lymph vessels by muscle contractions. - Lymph is passed through lymph nodes to filter pathogens. - The lymph is eventually returned to the blood.

Question 44

Why do organisms need transport systems?

Answer 44

- Because they are multicellular with a low surface area to volume ratio. - Diffusion is too slow to meet their metabolic needs. - Substances must be moved long distances.

Question 45

What is xylem tissue?

Answer 45

- Xylem tissue transports water and mineral ions around plants, and it also provides structural support. - Made up of xylem vessels.

Question 46

What are the adaptations of xylem tissue?

Answer 46

- Elongated hollow tubes without end walls. - They lack organelles. - Their walls are thicker with lignin for support. - They have non-lignified pits that allow for the movement of water and other ions in and out of vessels.

Question 47

What is phloem tissue?

Answer 47

- Phloem tissue transports sugars and amino acids around plants, and it is mostly made up of sieve tube elements and companion cells.

Question 48

What are the adaptations of sieve tube elements?

Answer 48

- They are connected end-to-end to form sieve tubes. - They have sieve plates with pores at their ends to allow the flow of sugars and amino acids. - They lack nuclei and most organelles. - They only have a thin layer of cytoplasm.

Question 49

What are the adaptations of companion cells?

Answer 49

- They are connected to sieve tube elements through pores (plasmodesmata). - The cytoplasm contains a large nucleus and many mitochondria that release energy for the active transport of substances through the sieve tube elements, and many ribosomes for protein synthesis.

Question 50

How does water move through a plant?

Answer 50

- Water enters a plant's root hair cells via osmosis. - It moves through the cell cytoplasm or cell walls towards the xylem. - The xylem transports water from the roots up to the leaves. - Water is used for photosynthesis. - Some water evaporates from leaf cells by transpiration and diffuses out of the plant.

Question 51

What is cohesion-tension theory?

Answer 51

- Explains how water moves up towards the xylem against gravity.

Question 52

How does the cohesion-tension theory work?

Answer 52

1. Cohesion - Hydrogen bonding causes water molecules to stick together and move as one continuous column. 2. Adhesion - Hydrogen bonding between polar water molecules and non-polar cellulose pulls water upwards through the xylem. 3. Transpiration - Evaporation of water at the leaves creates the transpiration pull, and this tension is transmitted down the whole water column due to cohesion.

Question 53

What is transpiration?

Answer 53

- The evaporation of water from aerial parts of plants, especially the leaves.

Question 54

How does transpiration work?

Answer 54

- Water evaporates from the moist surfaces of mesophyll cells. - Stomata open so they can absorb carbon dioxide for photosynthesis. - This provides a pathway for water vapour loss through open stomata. - Water vapour moves down a water potential gradient from spaces in the leaf into the atmosphere.

Question 55

How does light intensity affect the transpiration rate?

Answer 55

- At high light intensities, the stomata open for maximum CO2 absorption for photosynthesis, increasing the transpiration rate.

Question 56

How does temperature affect the transpiration rate?

Answer 56

- At high temperatures, evaporation of water molecules is faster due to higher kinetic energy, increasing the transpiration rate.

Question 57

How does humidity affect the transpiration rate?

Answer 57

- Low humidity increases the water vapour gradient between the leaf and atmosphere, increasing the transpiration rate.

Question 58

How does wind speed affect the transpiration rate?

Answer 58

- High wind speeds increase the water vapour gradient between the leaf and atmosphere, increasing the transpiration rate.

Question 59

How do you use a potometer?

Answer 59

1. Cut the shoot underwater at a slant to increase the surface area for water uptake. 2. Assemble the potometer with the shoot submerged in water. 3. Keep the capillary tube end of the potometer submerged throughout the experiment. 4. Check that the apparatus is air-tight. 5. Dry the leaves and give the shoot time to acclimate. 6. Shut the tap from an air bubble and record its position. 7. Measure the distance the air bubble moves at the time taken. 8. Change one variable at a time and keep everything else constant.

Question 60

How can you calculate the rate of transpiration using a potometer?

Answer 60

1. Calculate the cross-sectional area of the capillary tube (πr²). 2. Calculate the volume of water uptake by multiplying the cross-sectional area by the distance the air bubble traveled. 3. Rate of transpiration = volume of water uptake/time taken.

Question 61

What is translocation?

Answer 61

- The mass flow of solutes, sucrose and amino acids, from one part of a plant to another part of the plant.

Question 62

What are the features of translocation?

Answer 62

- Requires energy. - Transports substances from sources to sinks. - The substances are transported through the phloem. - Water provides the medium in which these substances dissolve.

Question 63

How do you calculate the volume of water uptake?

Answer 63

By multiplying the cross-sectional area by the distance the air bubble traveled.

Question 64

What is the rate of transpiration?

Answer 64

Volume of water uptake divided by time taken.

Question 65

What are the features of translocation?

Answer 65

- Requires energy - Transports substances from sources to sinks - The substances are transported through the phloem - Water provides the medium in which these substances dissolve for transport - Maintains a concentration gradient using enzymes.

Question 66

What is the mass flow hypothesis?

Answer 66

- Sucrose is actively loaded from the source cell to the companion cell - Sucrose then diffuses into the sieve tube elements via numerous plasmodesmata This lowers the water potential in the sieve tube element -Water moves by osmosis down its water potential gradient from the xylem to the sieve tube element increases the hydrostatic pressure in the sieve tube element - Water moves down the sieve tube from higher hydrostatic pressure at source to lower hydrostatic pressure at sink - Sucrose solution moves down a pressure gradient from a high to a low hydrostatic pressure in a process called mass flow - Sucrose moves from the sieve tube elements to the sink cells this increases the water potential in the sieve tube elements - Water leaves the sieve tube elements by osmosis and reduces the hydrostatic pressure in the sieve tube element and maintains the pressure gradient

Question 67

What is evidence for the mass flow hypothesis?

Answer 67

1. The stem bulges with fluid containing more sugar above sections where a ring of bark should be removed. This shows that the removal of phloem prevents the downward flow of sugars. 2. Radioactive isotopes of carbon in the form of CO2 that are supplied to a leaf are incorporated into organic substances and can be traced around the plant. This shows that organic substances move from source to sink. 3. Sap fed on by aphids flows out of the stem more quickly at the top of the stem. This shows that there is a pressure gradient in the phloem. 4. Translocation stops when inhibitors that prevent ATP synthesis are added to the phloem. This shows that some aspect of translocation requires energy.

Question 68

What is some evidence against the mass flow hypothesis?

Answer 68

- Sugars do not just move to sinks with the highest water potential. - The pressure gradient wouldn't be high enough for a sufficient rate of flow through sieve plates, especially through large trees.