Transport in animals

Cards (91)

  • Factors that mean that multicellular animals need transport systems
    Large size, high metabolic rate, low surface area to volume ratio, rate of diffusion is not enough, large distance between where molecules are produced and where they are needed
  • Types of circulatory system
    Single, double, open, closed
  • Features different circulatory systems have in common
    Liquid transport medium, vessels that carry the transport medium, of pumping mechanism
  • Open circulatory system
    Few blood vessels, haemocoel (Open body cavity), low pressure
  • Circulatory system in insects
    Open, haemolymph doesn't carry oxygen and carbon dioxide, haemolymph transports nitrogenous waste, body cavity split by membrane, heart extends along length of thorax and abdomen
  • Disadvantages of open circulatory systems
    No steep diffusion gradients, amount of fluid flowing to a tissue can't be changed
  • Closed circulatory system
    Blood enclosed in vessels, blood returns directly to the heart, substances leave and enter through walls of blood vessels
  • Examples of organisms with closed circulatory systems
    Echinoderms, cephalopod molluscs, mammals
  • Single circulatory system
    When the blood travels once through the heart for each complete circulation of the body
  • How a single circulatory system works
    Oxygen and carbon dioxide diffuse through set of capillaries, substances exchanged through other capillaries to organ systems
  • Disadvantages of single circulatory system
    Low blood pressure, low speed
  • Circulatory system in fish
    Single circulatory system, countercurrent gaseous exchange system, body weight supported by water so can be active without efficiency
  • Double circulatory system
    The blood travels twice through the heart for each circuit of the body
  • Two circuits in the double circulatory system
    Heart to lungs, heart to body
  • Advantages of doubl circulatory system
    High pressure, fast flow of blood
  • Examples of blood vessels (Types)
    Arteries, arterioles, capillaries, veins, venules
  • Function of arteries
    To carry oxygenated blood away from th heart to tissues in the body
  • Structure of arteries
    Elastic fibres, smooth muscle, collagen, order of layers from smallest to largest is lumen endothelium elastic muscle tough outer
  • Role of elastin fibres in blood vessels
    Stretching and recoiling, flexibility
  • Role of smooth muscle in blood vessels
    Contracts or relaxes to change the size of the lumen
  • Role of collagen in the blood vessels
    To provide structural support, to maintain the shape and volume of the vessel
  • Role of endothelium in the blood vessels

    Smooth so blood flows over it
  • Function of arterioles
    To link arteries and capillaries
  • Structure of arterioles

    More smooth muscle, less elastin
  • Why do arterioles constrict and dilate?
    To control the flow of blood to organs and capillary beds
  • Function of capillaries
    To link arterioles to venules
  • Structure of capillaries
    Narrow lumen to squeeze oxygen out of red blood cells, gaps between endothelial cells in capillary wall,
  • Adaptations of capillaries
    Large surface area, cross sectional area smaller than that of arterioles so slower blood flow, thin cell wall
  • Function of veins
    To carry deoxygenated blood from the cells of the body towards the heart
  • Structure of veins
    Lots of collagen, little elastic fibre, wide lumen, valves, smooth endothelium, sequence of layers is lumen endothelium elastic muscle tough
  • Function of venules
    To link capillaries with veins
  • Structure of venules
    Thin walls, little smooth muscle
  • Disadvantage to structure of veins
    Low pressure when having to work against gravity
  • Adaptations to structure of veins
    Valves, bigger veins run between active muscles, breathing movement during of chest act as a pump
  • How tissue fluid is formed
    Plasma proteins in capillaries decrease water potential, water moves into capillaries by oncotic pressure, blood still under pressure due to hydrostatic pressure, hydrostatic pressure greater than oncotic pressure so fluid squeezed out of capillaries, fluid fills spaces between cells
  • Oncotic pressure
    Tendency of water to move into blood by osmosis
  • Hydrostatic pressure
    The pressure from the surge of blood every time the heart contracts
  • Differences between composition of blood and tissue fluid
    No red blood cells, no plasma proteins
  • How tissue fluid gets back into blood vessels
    Hydrostatic pressure falls, oncotic pressure is greater than hydrostatic pressure, water moves back into the capillaries by osmosis
  • Lymph
    Liquid that leaves the blood vessels and drains into the lymph capillaries