exchange of substances

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mia

Cards (87)

  • what are features of a good gas exchange surface?
    - large surface area
    - thin for short diffusion distance
    - selectively permeable
  • how does mass transport of oxygen occur in insects?
    contraction of muscles through abdominal pumping enabling mass movements if air in and out
  • how does oxygen reach the working muscles in an insect?
    through the tracheoles
  • what is the advantage of having water at the end of the tracheoles ?
    - during high activity anaerobic respiration creates lactate which reduces the water potential of respiring cells
    - causes them to take up water during osmosis
    - the loss of water from the tracheoles will pull gas into them
  • what are spiracles?
    tiny pores in the insects exoskeleton that allow gasses to enter and leave
  • how do insects reduce water loss ?
    - small surface area to volume ratio
    - waterproof coverings
    - spiracles that can be opened and closed
  • how does the tracheal system limits the size of insects?
    - insects rely on diffusion to bring oxygen to the tissues
    - if an insect was too large it would take too long
  • what are gills made up of ?
    gill filaments
  • what increases the surface area of gills ?
    they have many gill filaments with many lamellae on them
  • how does counter current flow allow for effective gas exchange?
    - opposite flow of water and blood so there is a concentration gradient
    - equilibrium is not reached so diffusion is constantly take place
    - along the whole length of the gill
  • describe two features of a leaf that increases gas exchange?
    - spongy mesophyll contains air spaces so short diffusion pathway
    - many stomata to allow diffusion throughout the leave so shorter diffusion pathway
  • where are stomata found?
    underside of the leaf to limit evaporation and transpiration
  • what cells open and close the stomata?
    guard cells which close when water run out
  • what plants are well adapted to dry environments?
    xerophytes
  • what adaptions do xerophytes have to reduce water loss?
    - a thick waxy cuticle
    - rolling of leaves
    - stomata sunken in pits or grooves
    - a reduced surface area to volume ratio
  • how do the adaptations of xerophytes reduce water loss?
    - reduce water potential gradient
    - therefore slower diffusion of water vapour from air spaces
    - so reduced evaporation of water
  • how does a thick cuticle reduce transpiration?
    increases diffusion distance
  • name the structures involved in human gas exchange?
    trachea, lungs, bronchi, bronchioles and alveoli
  • what is the role of goblet cells in the trachea?
    produce mucus to trap microorganisms
  • why can the alveoli strech and recoil?
    because they have elastic fibres due to the protein elastin
  • what do bile salts do?
    emulsify lipids into micelles increasing their surface area
  • how are the alveoli adapted for gas exchange?
    - squamous epithelial cells that are 1 cell thick so short diffusion distance
    - capillaries run close to alveoli to maintain concentration gradient
    - contain elastic fibres so can stretch to prevent bursting and recoil which helps to repel stale air
    - many alveoli to give a large surface area
  • describe the mechanism for inhaling
    - diaphragm contracts to become flatter and moves down
    - external intercostal muscles contract and ribcage moves up and out
    - volume of thoracic cavity increases
    - pressure in thoracic cavity drops below atmospheric pressure
    - air moves into the lungs
  • describe the mechanism for expiration
    - diaphragm relaxes and is pushed up by displaced organs underneath
    - internal intercoastal muscles contract and ribcage moves down and in
    - volume of thoracic cavity decreases
    - pressure in thoracic cavity increases and rises above atmospheric pressure
    - air moves out of lungs
  • how do you find pulmonary ventilation rate?
    ventilation rate x tidal volume
  • what is the primary structure of haemoglobin?
    the order of amino acids in the polypeptide chains
  • what is the secondary structure of haemoglobin?
    the coiling of the polypeptide chains in to an alpha helix or a beta pleated sheet via hydrogen bonds
  • what is the tertiary structure of haemoglobin?
    the folding of the polypeptide chains into a specific shape with hydrogen bonding, ionic bonding and disulphide bridges
  • what is the quaternary structure of haemoglobin?
    the linking of four polypeptide chains into a spherical molecule, contains a haem group
  • what is loading?
    when haemoglobin binds to oxygen in the lungs
  • what is unloading?
    when haemoglobin releases its oxygen in the respiring tissues
  • what is a high affinity?
    - when haemoglobin takes up oxygen more easily but releases it less easily
  • what is a low affinity?
    when haemoglobin takes oxygen less easily but releases it more readily
  • what is partial pressure?
    the pressure exerted by a gas if it was in a container on its own
  • how does haemoglobin change its affinity for oxygen?
    it will change shape in the presence of certain molecules
  • what shape does the oxygen dissociation curve take?
    sigmoidal curve- s
  • why does the oxygen dissociation curve increase slowly to begin with?
    the shape of the haemoglobin molecule makes binding the first oxygen molecule difficult
  • why does the oxygen dissociation curve increases sharply after the beginning?
    - the first oxygen molecule changes shape of the quaternary structure
    - this makes binding of the other oxygens easier
  • why does the oxygen dissociation curve increases slowly at the end?
    less likely for the fourth oxygen to find a binding site
  • what is positive cooperativity?
    the increase in ease of binding the oxygen molecules