Transport in Animals

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Created by
Sienna Nicholls

Cards (34)

  • Types of circulatory system
    • Open= blood can diffuse out of vessels e.g. insects
    • Closed= blood confined to vessels e.g. fish, mammals
    • Single= blood passes through pump once per circuit of the body
    • Double= blood passes through heart twice per circuit of the body
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  • Reasons why multicellular organisms require transport systems
    • Large size (small surface area to volume ratio), subsequently high metabolic rates
    • Demand for oxygen is high, so need a specialised system to ensure a strong supply to all respiring tissues
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  • Relate the structure of veins to their function
    • Thin walls due to lower pressure
    • Require valves to ensure blood doesn’t flow backwards
    • Have less muscular and elastic tissue as they don’t have to control blood flow
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  • Relate the structure of arteries to their function
    • Thick, muscular walls to handle high pressure without tearing
    • Elastic tissue allows recoil to prevent pressure surges
    • Narrow lumen to maintain pressure
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  • Relate the structure of capillaries to their function
    • Walls only one cell thick; short diffusion pathway
    • Very narrow, so can permeate tissues and red blood cells can lie flat against the wall, effectively delivering oxygen to tissues
    • Numerous and highly branched, providing a large surface area
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  • Relate the structure of arterioles and venules to their function
    • Branch off arteries and veins in order to feed blood into capillaries
    • Smaller than arteries and veins so that the change in pressure is more gradual as blood passes through increasingly small vessels
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  • Types of pressure influencing formation of tissue fluid
    • Hydrostatic pressure= higher at arterial end of capillary than venous end
    • Oncotic pressure= changing water potential of the capillaries as water moves out, induced by proteins in the plasma
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  • How tissue fluid is formed
    As blood is pumped through increasingly small vessels, hydrostatic pressure is greater than oncotic pressure, so fluid moves out of the capillaries. It then exchanges substances with the cells
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  • Tissue fluid
    A watery substance containing glucose, amino acids, oxygen, and other nutrients. It supplies these to the cells, while also removing any waste materials
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  • What happens during cardiac diastole
    The heart is relaxed. Blood enters the atria, increasing the pressure and pushing open the atrioventricular valves. This allows blood to flow into the ventricles. Pressure in the heart is lower than in the arteries, so semilunar valves remain closed
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  • Differences between tissue fluid, blood, and lymph
    • Tissue fluid is formed from blood, but does not contain red blood cells, platelets, and various other solutes usually present in blood
    • After tissue fluid has bathed cells it becomes lymph, and therefore this contains less oxygen and nutrients and more waste products
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  • What happens during atrial systole
    The atria contract, pushing any remaining blood into the ventricles
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  • What happens during ventricular systole
    The ventricles contract. The pressure increases, closing the
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  • Explain how the heart contracts
    1. SAN initiates and spreads impulse across the atria, so they contract
    2. AVN receives, delays, and then conveys the impulse down the bundle of His
    3. Impulse travels into the Purkinje fibres which branch across the ventricles, so they contract from the bottom up
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  • Cardiac output = heart rate x stroke volume
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  • Myogenic
    The heart’s contraction is initiated from within the muscle itself, rather than by nerve impulses
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  • Ventricular systole
    1. The ventricles contract
    2. The pressure increases, closing the atrioventricular valves to prevent backflow, and opening the semilunar valves
    3. Blood flows into the arteries
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  • An electrocardiogram (ECG) is a graph showing the amount of electrical activity in the heart during the cardiac cycle
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  • Types of abnormal activity seen on an ECG
    • Tachycardia= fast heartbeat (over 100bpm)
    • Bradycardia= slow heartbeat (under 60bpm)
    • Fibrillation= irregular, fast heartbeat
    • Ectopic= early or extra heartbeats
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  • Describe the role of haemoglobin
    1. Present in red blood cells
    2. Oxygen molecules bind to the haem groups and are carried around the body, then released where they are needed in respiring tissues
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  • How does partial pressure of oxygen affect oxygen-haemoglobin binding?
    1. As partial pressure of oxygen increases, the affinity of haemoglobin for oxygen also increases, so oxygen binds tightly to haemoglobin
    2. When partial pressure is low, oxygen is released from haemoglobin
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  • As partial pressure of oxygen increases
    The affinity of haemoglobin for oxygen also increases, so oxygen binds tightly to haemoglobin
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  • Role of carbonic anhydrase in the Bohr effect
    • Present in red blood cells
    • Converts carbon dioxide to carbonic acid, which dissociates to produce H+ ions
    • Combines with haemoglobin to form haemoglobinic acid
    • Encourages oxygen to dissociate from haemoglobin
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  • As partial pressure of carbon dioxide increases
    The conditions become acidic causing haemoglobin to change shape
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  • When partial pressure is low
    Oxygen is released from haemoglobin
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  • What does SAN mean?
    Sino atrial node
  • What does AVN mean?
    Atrio - ventricular node
  • How does foetal haemoglobin differ from adult haemoglobin?
    The partIla pressure of oxygen is low by the time it reaches the foetus, therefore foetal haemoglobin has a higher affinity for oxygen than adult. Allows both mother’s and child‘s oxygen need to be met.
  • The chlorine shift: the intake of chloride ions across a red blood cell membrane. This repolarises the cell after bicarbonate ions have diffused out.
  • The role of bicarbonate ions (HCO3-) in gas exchange is to buffer the pH of the blood
  • The Bohr effect: The Bohr effect is the tendency of electrons to move from a higher energy level to a lower energy level.
  • Describe the Bohr effect: As partial pressure of carbon dioxide increases the conditions become acidic causing haemoglobin to change shape. The affinity of haemoglobin for oxygen decreases, so oxygen is released from the haemoglobin
  • What do oxyhaemoglobin dissociation curves show?
    The relationship between oxygen saturation and partial pressure of oxygen in the blood. curves further to the left show the haemoglobin has a high affinity for oxygen.
  • Is foetal haemoglobin has higher oxygen affinity than maternal?
    Yes.