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Date November 2019 Marks available 4 Reference code 19N.2.HL:.tz0.8
Level Higher Level Paper Paper 2 Time zone time zone 0
Command term Describe Question number 8 Adapted from N/A

Question

Outline catabolism.

[1]
a.i.

Describe the aerobic production of ATP before electrons are passed into the electron transport chain.

[6]
a.ii.

Describe the replacement of glycogen stores during recovery from fatigue after a long-distance swim.

[4]
b.

Analyse the long-term effect of training on maximal oxygen consumption.

[5]
c.

Evaluate the implications of genetic screening in sport.

[4]
d.

Markscheme

catabolism is the breakdown of complex molecules into simpler molecules, with the release of energy ✔

a.i.

glycolysis / Krebs cycle occurs before the ETC ✔

glycolysis takes place in the muscle sarcoplasm ✔

glucose is broken down to pyruvic acid ✔

pyruvic acid enters the Krebs cycle <via conversion to acetyl-coA> in the presence of oxygen ✔

fatty acids are catabolized into acetyl-coA✔

acetyl-coA and oxaloacetic acid combine to form citric acid ✔

glycolysis: net 2 ATP resynthesized ✔

Krebs cycle takes place in the mitochondria <matrix> ✔

citric acid enters the Krebs cycle ✔

carbon dioxide is released ✔

hydrogen ions are released into the ETC ✔

Krebs cycle: 2 ATP resynthesized ✔
OR
net 4 ATP yield for glycolysis and Krebs cycle ✔

a.ii.

endurance training significantly reduces muscle/liver glycogen stores ✔

muscle glycogen recovery will be preferential over liver ✔

both muscle/liver glycogen can be replenished within 24 hours of activity ✔

to optimize on glycogen synthesis, carbohydrates should be eaten immediately and at frequent intervals <1.2 g per kg> ✔

optimal window within the first 2 hours ✔

5–12 g per kg of body weight will allow replenishment within 24 hours ✔

b.

aerobic training is likely to cause a higher VO2 max than those with no training ✔

anaerobic non-interval training is likely to have little effect on VO2 max compared to those with no training
OR
high-intensity interval training produces improvements in maximum oxygen consumption ✔

activities where individuals have trained a greater area of muscle mass are likely to have a higher VO2 max ✔

due to an increase in stroke volume/ maximal cardiac output ✔

increased oxygen carrying capacity/hemoglobin content ✔

increased capillary density in muscles ✔

increased mitochondrial density / arteriovenous difference ✔

increased maximal minute ventilation/increased muscular endurance of respiratory muscles ✔

Accept other appropriate physiological adaptations.

Award max [4] if only physiological adaptions given.

c.

Strengths:
identify potential health conditions that may be life threatening, eg sudden cardiac death ✔

identify susceptibility to injury and so reduce its risk ✔

potentially use for talent identification ✔

Limitations:
possible exclusion from sport due to predetermined factors ✔

discrimination from future employment ✔

could support the development of gene doping ✔

d.

Examiners report

[N/A]
a.i.
[N/A]
a.ii.
[N/A]
b.
[N/A]
c.
[N/A]
d.

Syllabus sections

Topic 9: Fatigue » 9.1. Fatigue » 9.1.5. Discuss recovery from fatigue after sports.
Topic 9: Fatigue » 9.1. Fatigue
Topic 9: Fatigue

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