1 / 73

iGCSE Biology Section 2 lesson 4

iGCSE Biology Section 2 lesson 4. Content. Section 2 Structures and functions in living organisms. a) Levels of organisation b) Cell structure c) Biological molecules d) Movement of substances into and out of cells e) Nutrition f) Respiration g) Gas exchange h) Transport

friedmand
Download Presentation

iGCSE Biology Section 2 lesson 4

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. iGCSE Biology Section 2 lesson 4

  2. Content Section 2 Structures and functions in living organisms a) Levels of organisation b) Cell structure c) Biological molecules d) Movement of substances into and out of cells e) Nutrition f) Respiration g) Gas exchange h) Transport i) Excretion j) Coordination and response

  3. Content Lesson 4 f) Respiration g) Gas exchange f) Respiration 2.33 understand that the process of respiration releases energy in living organisms 2.34 describe the differences between aerobic and anaerobic respiration 2.35 write the word equation and the balanced chemical symbol equation for aerobic respiration in living organisms 2.36 write the word equation for anaerobic respiration in plants and in animals 2.37 describe experiments to investigate the evolution of carbon dioxide and heat from respiring seeds or other suitable living organisms.

  4. Content Lesson 4 f) Respiration g) Gas exchange g) Gas exchange 2.38 understand the role of diffusion in gas exchange Flowering plants 2.39 understand gas exchange (of carbon dioxide and oxygen) in relation to respiration and photosynthesis 2.40 understand that respiration continues during the day and night, but that the net exchange of carbon dioxide and oxygen depends on the intensity of light 2.41 explain how the structure of the leaf is adapted for gas exchange 2.42 describe the role of stomata in gas exchange 2.43 describe experiments to investigate the effect of light on net gas exchange from a leaf, using hydrogen-carbonate indicator Humans 2.44 describe the structure of the thorax, including the ribs, intercostal muscles, diaphragm, trachea, bronchi, bronchioles, alveoli and pleural membranes 2.45 understand the role of the intercostal muscles and the diaphragm in ventilation 2.46 explain how alveoli are adapted for gas exchange by diffusion between air in the lungs and blood in capillaries 2.47 understand the biological consequences of smoking in relation to the lungs and the circulatory system, including coronary heart disease 2.48 describe experiments to investigate the effect of exercise on breathing in humans.

  5. What is respiration? What is gaseous exchange?

  6. What is respiration? Respiration is the release of energy from the breakdown of glucose, by combining it with oxygen inside living cells. What is gaseous exchange?

  7. What is respiration? Respiration is the release of energy from the breakdown of glucose, by combining it with oxygen inside living cells. What is gaseous exchange? Gaseous exchange is the movement of gases (oxygen and carbon dioxide) into and out of an organism.

  8. Respiration – two sorts Aerobic respiration - in the presence of oxygen. Involves the complete breakdown of glucose. Provides more energy. End products in animals and plants: carbon dioxide and water

  9. Respiration – two sorts Aerobic respiration - in the presence of oxygen. Involves the complete breakdown of glucose. Provides more energy. End products in animals and plants: carbon dioxide and water Anaerobic respiration - in the absence of oxygen. Involves the incomplete breakdown of glucose. Provides less energy. End product in animals – lactic acid. End product in plants - ethanol

  10. Aerobic respiration Glucose + oxygen  carbon dioxide + water + energy

  11. Aerobic respiration Glucose + oxygen  carbon dioxide + water + energy C6H12O6 + 6O2 6CO2 + 6H2O + energy

  12. Aerobic respiration Glucose + oxygen  carbon dioxide + water + energy C6H12O6 + 6O2 6CO2 + 6H2O + energy What do you notice?

  13. Photosynthesis Light 6CO2 + 6H2O C6H12O6 + 6O2 Chlorophyll

  14. Glucose Blood capillary Muscle cell

  15. Glucose Blood capillary Glucose + Oxygen Muscle cell Glucose and oxygen diffuse from the blood into the muscle cell

  16. Glucose Deoxygenated red blood cells Blood capillary Glucose + Oxygen  Carbon dioxide + Water Muscle cell Glucose and oxygen diffuse from the blood into the muscle cell Carbon dioxide and water diffuse from the muscle cell into the blood

  17. Glucose Deoxygenated red blood cells Blood capillary Energy Glucose + Oxygen  Carbon dioxide + Water Muscle cell Glucose and oxygen diffuse from the blood into the muscle cell Carbon dioxide and water diffuse from the muscle cell into the blood Energy is used for muscle contraction

  18. Levels of Organisation A. Cells

  19. Levels of Organisation A. Cells Mitochondria - organelles inside the cell where cellular respiration takes place. They absorb glucose and oxygen, release the energy and then convert it into forms that are usable by the cell. Mitochondria are more numerous in active cells such as muscle cells.

  20. Why anaerobic respiration? If it is so inefficient compared with aerobic respiration, why do cells bother? Sometimes our muscles are working so hard that the lungs and bloodstream cannot deliver oxygen fast enough, so the muscles must respire anaerobically. This can lead to a build up of lactic acid in the muscle.

  21. Why anaerobic respiration? If it is so inefficient compared with aerobic respiration, why do cells bother? A lactic acid build-up in muscles can result in cramp, an unpleasant and often painful sensation caused by muscle contraction or over-shortening.

  22. Why anaerobic respiration? If it is so inefficient compared with aerobic respiration, why do cells bother? In order to break down the lactic acid the body needs more oxygen  OXYGEN DEBT

  23. Why anaerobic respiration? If it is so inefficient compared with aerobic respiration, why do cells bother?

  24. Anaerobic respiration in plants

  25. Anaerobic respiration in plants Glucose  ethanol + carbon dioxide + energy

  26. Anaerobic respiration in plants Glucose  ethanol + carbon dioxide + energy C6H12O6 2C2H5OH + 2CO2

  27. Anaerobic respiration in plants Glucose  ethanol + carbon dioxide + energy C6H12O6 2C2H5OH + 2CO2 In plants, anaerobic respiration (respiration without oxygen) is known as fermentation. This process is commonly used to our advantage in the production of beer and ales, and wine.

  28. Aerobic v Anaerobic

  29. Aerobic v Anaerobic

  30. Aerobic v Anaerobic

  31. Aerobic v Anaerobic

  32. Content Lesson 4 f) Respiration g) Gas exchange g) Gas exchange 2.38 understand the role of diffusion in gas exchange Flowering plants 2.39 understand gas exchange (of carbon dioxide and oxygen) in relation to respiration and photosynthesis 2.40 understand that respiration continues during the day and night, but that the net exchange of carbon dioxide and oxygen depends on the intensity of light 2.41 explain how the structure of the leaf is adapted for gas exchange 2.42 describe the role of stomata in gas exchange 2.43 describe experiments to investigate the effect of light on net gas exchange from a leaf, using hydrogen-carbonate indicator Humans 2.44 describe the structure of the thorax, including the ribs, intercostal muscles, diaphragm, trachea, bronchi, bronchioles, alveoli and pleural membranes 2.45 understand the role of the intercostal muscles and the diaphragm in ventilation 2.46 explain how alveoli are adapted for gas exchange by diffusion between air in the lungs and blood in capillaries 2.47 understand the biological consequences of smoking in relation to the lungs and the circulatory system, including coronary heart disease 2.48 describe experiments to investigate the effect of exercise on breathing in humans.

  33. What is respiration? Respiration is the release of energy from the breakdown of glucose, by combining it with oxygen inside living cells. What is gaseous exchange? Gaseous exchange is the movement of gases (oxygen and carbon dioxide) into and out of an organism.

  34. What is gaseous exchange? Gaseous exchange is the movement of gases (oxygen and carbon dioxide) into and out of an organism. Gaseous exchange is brought about by the actions of the breathing system (also referred to in some textbooks as the respiratory system)

  35. The Breathing System

  36. The Breathing System Trachea – surrounded by rings of cartilage to stop it collapsing

  37. The Breathing System Trachea – surrounded by rings of cartilage to stop it collapsing Ribs – these protect the contents of the thorax. There are 12 pairs of ribs in both men and women.

  38. The Breathing System Trachea – surrounded by rings of cartilage to stop it collapsing Ribs – these protect the contents of the thorax. There are 12 pairs of ribs in both men and women. Rib muscles - the intercostals. Raise and lower the rib cage

  39. The Breathing System Trachea – surrounded by rings of cartilage to stop it collapsing Ribs – these protect the contents of the thorax. There are 12 pairs of ribs in both men and women. Left lung Rib muscles - the intercostals. Raise and lower the rib cage

  40. The Breathing System Trachea – surrounded by rings of cartilage to stop it collapsing Ribs – these protect the contents of the thorax. There are 12 pairs of ribs in both men and women. Left lung Rib muscles - the intercostals. Raise and lower the rib cage Diaphragm – a sheet of muscle used in the mechanism of breathing

  41. The Breathing System Trachea – surrounded by rings of cartilage to stop it collapsing Ribs – these protect the contents of the thorax. There are 12 pairs of ribs in both men and women. Left lung Rib muscles - the intercostals. Raise and lower the rib cage Right bronchus – a branch of the trachea Diaphragm – a sheet of muscle used in the mechanism of breathing

  42. The Breathing System Trachea – surrounded by rings of cartilage to stop it collapsing Ribs – these protect the contents of the thorax. There are 12 pairs of ribs in both men and women. Left lung Rib muscles - the intercostals. Raise and lower the rib cage Bronchiole - a smaller branch of the bronchus Right bronchus – a branch of the trachea Diaphragm – a sheet of muscle used in the mechanism of breathing

  43. The Breathing System Trachea – surrounded by rings of cartilage to stop it collapsing Ribs – these protect the contents of the thorax. There are 12 pairs of ribs in both men and women. Left lung Rib muscles - the intercostals. Raise and lower the rib cage Bronchiole - a smaller branch of the bronchus Right bronchus – a branch of the trachea Alveoli - clusters of grape-like air sacs where gas exchange takes place Diaphragm – a sheet of muscle used in the mechanism of breathing

  44. The Breathing System Trachea – surrounded by rings of cartilage to stop it collapsing Ribs – these protect the contents of the thorax. There are 12 pairs of ribs in both men and women. Left lung Rib muscles - the intercostals. Raise and lower the rib cage Bronchiole - a smaller branch of the bronchus Right bronchus – a branch of the trachea Alveoli - clusters of grape-like air sacs where gas exchange takes place Diaphragm – a sheet of muscle used in the mechanism of breathing

  45. Alveolus (plural alveoli) Where oxygen and carbon dioxide move between the lungs and the blood stream.

  46. Bronchiole Alveolus There are millions of alveoli in each lung, very close to blood capillaries

  47. Bronchiole Alveolus 1 1. Deoxygenated blood flow from the tissues, rich in carbon dioxide

  48. Bronchiole Alveolus 2 2. Carbon dioxide diffuses out of the blood stream into the alveoli, and then into the bronchiole

  49. Bronchiole Alveolus 3 3. Oxygen diffuses from the bronchiole into the alveoli and then into the red blood cells.

  50. Bronchiole 4 Alveolus 4. Oxygenated blood now leaves the alveoli and carries oxygen to the tissues.

More Related