TOPIC 3 - EXCHANGE OF SUBSTANCES

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Created by
Megan Swisho

Cards (96)

  • Surface area to volume ratio
    • The surface area of an organism divided by its volume
    • the larger the organism, the smaller the ratio
  • Factors affecting gas exchange
    • diffusion distance
    • surface area
    • concentration gradient
    • temperature
  • Ventilation
    • Inhaling and exhaling in humans
    • controlled by diaphragm and antagonistic interaction of internal and external intercostal muscles
  • Inspiration
    • External intercostal muscles contract and internal relax
    • pushing ribs up and out
    • diaphragm contracts and flattens
    • air pressure in lungs drops below atmospheric pressure as lung volume increases
    • air moves in down pressure gradient
  • Expiration
    • External intercostal muscles relax and internal contract
    • pulling ribs down and in
    • diaphragm relaxes and domes
    • air pressure in lungs increases above atmospheric pressure as lung volume decreases
    • air forced out down pressure gradient
  • Passage of gas exchange
    :)
  • Alveoli structure

    :)
  • Why large organisms need specialised exchange surface
    :)
  • Fish gill anatomy
    :)
  • How fish gas exchange surface provides large surface area
    • Many gill filaments covered in many gill lamellae are positioned at right angles
    • creates a large surface area for efficient diffusion
  • Countercurrent flow
    • When water flows over gills in opposite direction to flow of blood in capillaries
    • equilibrium not reached 
    • diffusion gradient maintained across entire length of gill lamellae
  • Name three structures in tracheal system

    :)
  • How tracheal system provides large surface area
    :)
  • Fluid-filled tracheole ends
    • Adaptation to increase movement of gases
    • when insect flies and muscles respire anaerobically - lactate produced
    • water potential of cells lowered, so water moves from tracholes to cells by osmosis
    • gases diffuse faster in air
  • How do insects limit water loss
    :)
  • Dicotyledonous plants leaf tissues
    :)
  • Gas exchange in plants
    • Palisade mesophyll is site of photosynthesis
    • oxygen produced and carbon dioxide used creates a concentration gradient
    • oxygen diffuses through air space in spongy mesophyll and diffuse out stomata
  • Role of guard cells
    :)
  • Xerophytic plants
    • Plants adapted to survive in dry environments with limited water (e.g. marram grass/cacti)
    • structural features for efficient gas exchange but limiting water loss
  • Adaptations of xerophyte
    :)
  • Digestion
    • Process where large insoluble biological molecules are hydrolysed into smaller soluble molecules
    • so they can be absorbed across cell membranes
  • Locations of carbohydrate digestion
    :)
  • Locations of protein digestion
    :)
  • Endopeptidases
    :)
  • Exopeptidases
    :)
  • Membrane- bound dipeptidases
    • Break peptide bond between two amino acids
  • Digestion of lipids
    • Digestion by lipase (chemical)
    • emulsified by bile salts (physical)
    • lipase produced in pancreas 
    • bile salts produced in liver and stored in gall bladder
  • Lipase
    :)
  • Role of bile salts
    • Emulsify lipids to form tiny droplets and micelles
    • increases surface area for lipase action - faster hydrolysis
  • Micelles
    • Water soluble vesicles formed from fatty acids, glycerol, monoglycerides and bile salts
  • Lipid absorption
    • Micelles deliver fatty acids, glycerol and monoglycerides to epithelial cells of ileum for absorption
    • cross via simple diffusion as lipid-soluble and non-polar
  • Lipid modification
    • Smooth ER reforms monoglycerides / fatty acids into tryglycerides
    • golgi apparatus combines tryglycerides with proteins to form vesicles called chylomicrons
  • How lipids enter blood after modification
    • Chylomicrons move out of cell via exocytosis and enter lacteal
    • lymphatic vessels carry chylomicrons and deposit them in bloodstream
  • How are glucose and amino acids absorbed

    :)
  • Haemoglobin (Hb)

    :)
  • Affinity of haemoglobin
    • The ability of haemoglobin to attract / bind to oxygen
  • Saturation of haemoglobin
    • When haemoglobin is holding the maximum amount of oxygen it can hold
  • Loading / unloading of haemoglobin
    • Binding/detachment of oxygen to haemoglobin
    • also known as association and disassociation
  • Oxyhaemoglobin dissociation curve
    :)
  • Oxyhaemoglobin dissociation curve shifting left
    • Hb would have a higher affinity for oxygen
    • load more at the same partial pressure
    • becomes more saturated 
    • adaptation in low-oxygen environments
    • e.g. llamas/ in foetuses