| Date | November 2017 | Marks available | 1 | Reference code | 17N.2.HL.TZ0.01 |
| Level | Higher level | Paper | Paper 2 | Time zone | TZ0 / no time zone |
| Command term | Outline | Question number | 01 | Adapted from | N/A |
Question
Hypoxia is a condition in which tissues of the body are deprived of an adequate oxygen supply. A study was carried out in rats to examine the effects of continuing hypoxia on the structure of the diaphragm, and to determine whether nitric oxide is implicated in adaptation of the diaphragm to hypoxia. The diaphragm helps to supply oxygen to tissues and organs in the body by ventilating the lungs.
A group of 36 adult male rats were kept for 6 weeks in low oxygen while 36 adult male rats were kept in normal oxygen levels.
[Source: Reproduced with permission of the © ERS 2011. European Respiratory Journal June 2011, 37 (6) 1474–1481; DOI: 10.1183/09031936.00079810]
The graph shows the effect of hypoxia on the endurance of rats’ diaphragm muscle after 6 weeks. Endurance is the change in force measured as a percentage of the initial force.
[Source: Reproduced with permission of the © ERS 2011. European Respiratory Journal June 2011, 37 (6) 1474–1481; DOI: 10.1183/09031936.00079810]
The sodium–potassium pump plays a role in muscle activity. Nitric oxide may have a role in the recovery of hypoxic muscles. The production of nitric oxide can be blocked with an inhibitor of the enzyme nitric oxide synthase. The graph shows the concentration of sodium–potassium pumps in the diaphragm of control and hypoxic rats without and with nitric oxide synthase inhibitor.
[Source: Reproduced with permission of the © ERS 2011. European Respiratory Journal June 2011, 37 (6) 1474–1481; DOI: 10.1183/09031936.00079810]
Skeletal muscle contractions can take two different forms: if they are stimulated by a single action potential they take the form of a twitch and if they are stimulated by a series of action potentials the contraction is longer lasting (tetanic). The table shows the effects of hypoxia on the force of twitch and peak tetanic contraction in the diaphragm.
[Source: Reproduced with permission of the © ERS 2011. European Respiratory Journal June 2011, 37 (6) 1474–1481; DOI: 10.1183/09031936.00079810]
Outline the effect of hypoxia on body mass and erythrocyte percentage.
Using the data in the graph, deduce whether hypoxia increases or decreases the endurance of the rats’ diaphragm muscle.
Using the data presented in this question, explain the effect of hypoxia on the body.
Analyse the graph to obtain two conclusions about the concentration of sodium–potassium pumps.
Muscle fibres are stimulated to contract by the binding of acetylcholine to receptors in their membranes and the subsequent depolarization.
Suggest a reason for increasing the concentration of sodium–potassium pumps in the membranes of diaphragm muscle fibres.
Outline the effect of hypoxia on the force of contraction of the diaphragm.
Hypoxia caused a 13 % increase in the surface area to volume ratio of the diaphragm. Suggest a reason for this change.
Using all relevant data in the question, evaluate the effectiveness of the rats’ adaptation to hypoxia.
Discuss the advantages and disadvantages of using rats as models in this investigation.
Markscheme
Erythrocyte percentage increased AND body mass reduced/smaller increase in mass
a. increases endurance «in relation to the control»
b. higher force/endurance at every testing time/throughout
OR
smaller decreases in force «over time»
c. the magnitude of the difference is similar throughout the five minutes experiment/testing
d. differences are «statistically» significant
e. endurance of control is «approximately» 35 % versus endurance of hypoxia «approximately» 55 % «after 5 minutes»
Accept ±5 % for both percentages
[Max 2 Marks]
a. diaphragm more endurance/stronger/generates more force for more ventilation/inspiration
b. right ventricle mass increases to pump more blood
c. erythrocyte percentage increases to transport oxygen
d. less growth/body mass which reduces oxygen demand
Reject “loss of body mass”
The physiological reason is required for each mark
[Max 2 Marks]
a. hypoxia increases the concentration of sodium–potassium pumps
b. nitric oxide needed for/stimulates «production of» sodium-potassium pumps
c. nitric oxide synthase inhibitor reduces the concentration of pumps
OR
concentration of pumps reduced by inhibiting nitric oxide production
Award up to [1] for a conclusion on lines labelled 1 and up to [1] for a conclusion on the lines labelled 2
[Max 2 Marks]
a. resting potential restored faster
b. increases the «maximum» frequency/rate of contractions
OR
can contract again sooner
Accept shorter refractory period for mpa
Do not accept faster contraction/depolarization/ repolarization
[Max 1 Mark]
reduces «force of» twitch AND peak tetanic contraction
a. decrease in volume/atrophy/loss of cells/less muscle fibres/less tissue in the diaphragm
b. SA to volume ratio increased to make oxygen uptake into muscle/cells faster
Do not accept reduction in area of diaphragm
[Max 1 Mark]
a. not effective because body mass lost
b. effective because body mass still increases/rats still grow
c. not effective because contractions/force exerted by diaphragm decreases
d. effective because more sodium-potassium pumps so more/faster rate of diaphragm/muscle contractions
e. effective because endurance of diaphragm increases
f. effective because mass of right ventricle increases
g. effective because erythrocyte percentage increases
For each marking point the candidate must make it clear whether they are arguing for adaptation being effective or not. This can be done by giving the physiological benefit of a change, for example greater mass of right ventricle so more blood pumped.
[Max 3 Marks]
Advantages:
a. small size
OR
easy to look after in research labs
b. short lifespan
OR
study can extend over several generations
c. can be killed «to get experimental results» if benefits of research justify it
d. «mammalian» so similarities with humans
e. fewer ethical objections than if humans are used/not ethical to subject humans to hypoxia/does not cause harm to humans
Accept any one of the advantages
Disadvantages:
f. ethical objections
OR
wrong to cause suffering to animals/rats
g. rat physiology/anatomy not same as human
Accept any one of the disadvantages
[Max 2 Marks]
Examiners report
Syllabus sections
- 22M.1.SL.TZ2.27: Pressure changes inside the thorax cause the movement of air in and out of the lung alveoli...
- 17N.2.SL.TZ0.01c: State the disease severity group that has the highest range of plasma desmosines.
-
18M.3.HL.TZ1.2b:
Calculate the total volume of air inhaled during one minute during the highest velocity of the treadmill in this test, giving the units.
- 17N.2.SL.TZ0.01f: State the relationship between diffusion capacity and urine desmosines.
- 18N.3.HL.TZ0.1c: Suggest how the total lung volume at rest would differ for a patient with emphysema.
- 19M.1.HL.TZ1.23: What is produced by type II pneumocytes? A. Epinephrine B. Elastase C. Pulmonary...
- 18M.1.SL.TZ2.28: What is the role of type II pneumocytes? A. To carry out gas exchange B. To keep the...
- 18N.2.SL.TZ0.1f: Among 75-year-old lifelong non-smokers the percentage incidence of lung cancer was 0.01 %....
- 17M.1.HL.TZ2.34: The graph shows the ventilation rate and the oxygen consumption of a subject before, during...
- 17N.2.SL.TZ0.01a: State the level of COPD that has the lowest FEV.
- 16N.1.SL.TZ0.27: What is the purpose of pulmonary surfactant? A. Promotes capillary growthB. Decreases...
- 16N.1.SL.TZ0.28: Which conditions are correct for inspiration?
- 18M.3.SL.TZ2.3b: Describe how the mean tidal volume after exercise could be determined using the graph.
- 18N.3.SL.TZ0.2c: Suggest how the total lung volume at rest would differ for a patient with emphysema.
-
18M.2.SL.TZ1.6a:
Outline the role of the parts of an alveolus in a human lung.
-
17N.2.SL.TZ0.01d:
Evaluate which of the two biomarkers would be the most useful indicator of COPD severity.
- 22M.1.SL.TZ1.27: A cell from the lungs, observed under the microscope, contains a large number of secretory...
- 18N.2.SL.TZ0.1g: State two respiratory diseases, other than lung cancer, caused by smoking.
- 18M.3.HL.TZ1.2c: Compare and contrast the effect of increasing treadmill speed on the ventilation rate and...
- 17M.3.SL.TZ1.3a: Calculate the difference in ventilation rate between resting and exercising.
-
17N.2.HL.TZ0.01c:
Using the data presented in this question, explain the effect of hypoxia on the body.
- 21N.2.SL.TZ0.2c: Outline the action taken by the diaphragm during inhalation.
- 18N.3.SL.TZ0.2b: Explain the changes in ventilation after 35 seconds.
- 18N.2.SL.TZ0.1c: Evaluate the evidence provided by the data in the graphs for smoking as a cause of lung cancer.
- 18N.3.HL.TZ0.1a: Calculate the ventilation rate at rest, giving the units.
- 17M.3.SL.TZ1.3b: Explain the change in the tidal volume during exercise.
-
21M.2.SL.TZ1.7a:
Outline the process of inhalation.
- 18M.3.HL.TZ1.2a : State the apparatus used to measure the tidal volume.
- 17M.1.SL.TZ2.27: The bacterium Neisseria gonorrhoeae causes infections related to the human reproductive...
- 17M.1.SL.TZ2.28: Where does gas exchange occur in the lungs? A. In type I pneumocytes B. In the...
- 18M.3.SL.TZ2.3c: Predict, with a reason, the effect of exercise on the rate of cell respiration.
- 18M.3.SL.TZ2.3a: Determine the ventilation rate after exercise.
- 21N.1.SL.TZ0.27: What occurs during inhalation?
-
20N.1.SL.TZ0.28:
The graph shows a spirometer trace of oxygen consumption when breathing at rest and during exercise.
[Source: Courtesy of Dr. Dafang Wang for his work at University of Utah.]
What explains the difference between the traces at regions X and Y on the graph?
A. At X, the internal intercostal muscles contract more than the external intercostal muscles.
B. At Y, the ribcage moves up and out more than at X.
C. At X, the diaphragm flattens more per breath than at Y.
D. At Y, the intercostal muscles contract more slowly than at X.
-
17N.2.HL.TZ0.01b:
Using the data in the graph, deduce whether hypoxia increases or decreases the endurance of the rats’ diaphragm muscle.
-
19M.3.SL.TZ2.3c:
Outline how ventilation rate could have been monitored in this study.
-
17N.2.SL.TZ0.01g:
Other studies on pulmonary diseases have shown a wide variety of results. Apart from age, sex and severity of COPD, list two other factors that may explain the inconsistent results between studies.
- 18M.3.SL.TZ2.3d: Identify a muscle responsible for increasing the volume of the chest cavity.
- 17M.1.SL.TZ1.21: Cladograms can be created by comparing DNA or protein sequences. The cladogram on the left is...
- 21M.1.HL.TZ1.21: Which process results in the exchange of gases across the membrane of pneumocytes? A. Active...
-
17N.2.SL.TZ0.01e:
Elastin is also an important component of other tissues such as arteries and ligaments. Evaluate how these other sources of elastin could affect the interpretation of the biomarker as an indicator of COPD.
- 21M.1.SL.TZ2.27: Which is an adaptation to increase rates of gas exchange in the lung? A. Small surface...
- 18N.3.HL.TZ0.1d: Outline the function of pneumocytes in the lungs.
- 19M.3.SL.TZ2.3b: Compare and contrast the effect of increasing exercise intensity at sea level and at an...
-
17N.2.SL.TZ0.01b:
Explain how a low FEV can be used to indicate emphysema.
- 17N.2.HL.TZ0.01e.i: Outline the effect of hypoxia on the force of contraction of the diaphragm.
-
17N.2.HL.TZ0.01f:
Using all relevant data in the question, evaluate the effectiveness of the rats’ adaptation to hypoxia.
- 17M.2.HL.TZ1.1f.ii: Suggest a reason for the greater expression of the gene for the urea transporter after an...
- 19M.1.SL.TZ2.26: In premature babies born earlier than the 30th week of pregnancy, type II pneumocytes are...
-
21M.2.SL.TZ1.7b:
Explain the process of gas exchange taking place in the alveoli.
- 17N.1.HL.TZ0.23: Which type of cell is specialized to facilitate gas exchange? A. Type I pneumocytes B. Type...
- 18M.2.HL.TZ2.6b: Outline how ventilation in humans ensures a supply of oxygen.
- 17M.2.SL.TZ1.1c: Estimate how much smaller drilled oysters raised in seawater at a high CO2 concentration were...
-
17N.2.HL.TZ0.01e.ii:
Hypoxia caused a 13 % increase in the surface area to volume ratio of the diaphragm. Suggest a reason for this change.
- 18M.1.SL.TZ1.28: How are the insides of alveoli prevented from sticking together?
- 18N.2.SL.TZ0.1a: Calculate the change in the percentage of the male population that smoked from 1950 to 2000.
- 18N.2.SL.TZ0.1d: Describe the relationship between the incidence of lung cancer and stopping smoking.
- 18N.2.SL.TZ0.1b: Compare and contrast the trends in smoking behaviour between males and females between 1950...
- 18N.2.SL.TZ0.1e: Explain evidence from the data in the table that could be used to persuade a smoker to give...
- 18N.2.HL.TZ0.6c: Adult humans may absorb more than five hundred litres of oxygen per day. Explain how gas...
- 18N.3.HL.TZ0.1b: Explain the changes in ventilation after 35 seconds.
- 18N.3.SL.TZ0.2a: Calculate the ventilation rate at rest, giving the units.
- 19M.2.SL.TZ1.4a: Outline the functions of type I and type II pneumocytes.
-
17N.2.HL.TZ0.01d.ii:
Muscle fibres are stimulated to contract by the binding of acetylcholine to receptors in their membranes and the subsequent depolarization.
Suggest a reason for increasing the concentration of sodium–potassium pumps in the membranes of diaphragm muscle fibres.
-
17N.2.HL.TZ0.01g:
Discuss the advantages and disadvantages of using rats as models in this investigation.
- 19M.2.SL.TZ1.4b: Explain how gases are exchanged between the air in the alveolus and the blood in the...
- 19M.2.HL.TZ1.6a: Outline the process of inspiration in humans.
- 19M.3.SL.TZ2.3a: State one other variable that should have been controlled in this study.
- 19N.2.SL.TZ0.6c: Explain how ventilation and lung structure contribute to passive gas exchange.
- 21N.2.HL.TZ0.4c: Outline the action taken by the diaphragm during inhalation.
- 16N.2.SL.TZ0.6c: Describe what happens in alveoli.
- 19N.1.HL.TZ0.23: Which factors could cause emphysema? I. Air pollution II. Genetic predisposition III....
-
17N.2.HL.TZ0.01d.i:
Analyse the graph to obtain two conclusions about the concentration of sodium–potassium pumps.
-
17N.2.SL.TZ0.01h:
Discuss whether measurements of desmosine concentration would be useful for monitoring changes in the health of a patient.
- 21M.1.SL.TZ2.28: Where in the body are type I pneumocytes found? A. Alveoli B. Nephrons C. Capillaries D....
