Syllabus Edition

First teaching 2014

Last exams 2024

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Conserving Water (DP IB Biology: HL)

Revision Note

Naomi H

Author

Naomi H

Expertise

Biology

Conserving Water & the Loop of Henlé

  • Animals that live in dry environments such as deserts depend on their ability to conserve water for survival
  • Such animals often have very long loops of Henle
    • The longer the loop of Henle, the greater an animal’s ability to conserve water
      • A longer loop of Henle is able to generate steeper concentration gradients and so more water can be reabsorbed by osmosis
    • The collecting ducts of such animals are also very long
  • Animals that need to conserve water have thicker medulla regions in their kidneys to provide additional space for their long loops of Henle
  • This means that both loop of Henle length and medulla thickness can be indicators of an animal’s ability to conserve water

_loop-of-henle-length

The length of the loop of Henle differs depending on an organism’s need to conserve water; the longer the loop of Henle, the more water can be reabsorbed

medulla-thickness

The thicker the medulla region of the kidney, the more concentrated urine can become, meaning that more water is reabsorbed in animals with a thicker medulla. A thicker medulla is needed to allow space for a longer loop of Henle.

Consequences of Dehydration & Overhydration

  • If the balance of water and solutes in the body are not maintained correctly, the result may be dehydration or overhydration
  • Dehydration results if water is lost from the body and not replaced
  • e.g.
    • After excessive sweating
    • After diarrhoea
  • In dehydration the osmolarity of the body fluids rises above that of the surrounding cells, leading to cell water loss and shrinkage as water moves out of the cells by osmosis
  • Symptoms of dehydration include
    • Low volume of dark, concentrated urine
    • Not being able to sweat, leading to a reduced ability to regulate body temperature
    • A drop in blood pressure due to reduced blood volume
    • An elevated heart rate as the heart attempts to compensate for the drop in blood pressure
    • Feeling tired due to increased exposure of the tissues to metabolic waste
      • Metabolic waste is usually removed from the body by being dissolved in water and excreted in the urine; this cannot happen quickly enough if there is a lack of water available
  • Overhydration can result if there is too much water in the body fluids in relation to solutes such as sugars and salts; this can result from
    • Overconsumption of water
    • Not replacing sugars and salts after excessive sweating
    • Kidney problems
    • The side effects of certain drugs
  • In overhydration the osmolarity of the body fluids drops below that of the surrounding cells, causing water to move into the cells by osmosis
    • This leads to swelling of the body’s cells
  • Overhydration can lead to symptoms such as
    • Excessive urination as the body produces large volumes of colourless, dilute urine
    • Headaches resulting from swelling of cells in the brain
    • High blood pressure due to increased blood volume
    • Low heart rate as the heart attempts to compensate for the increase in blood pressure
    • Neurological problems due to low concentrations of important ions such as sodium ions

NOS: Curiosity about particular phenomena; investigations were carried out to determine how desert animals prevent water loss in their wastes

  • Scientists observe events, or phenomena, in the natural world, noticing when phenomena cannot be explained using existing understanding
  • When a phenomenon cannot be explained using existing knowledge, scientists come up with hypotheses that might explain such phenomena, and design investigations to allow them to test these hypotheses
  • When scientists studying desert rodents such as kangaroo rats (genus Dipodomys) noticed that they were able to survive on a diet of dry seeds with little or no separate water intake, they became curious as to how the rats’ physiology enabled them to do this
  • Analysis of the kangaroo rats’ water intake from food and their water losses due to breathing, excretion, and egestion, showed that water intake and water losses were equal
  • Studying kangaroo rat anatomy and behaviour, scientists were able to conclude that they balanced their water intake and losses by
    • Having a very long loop of Henle and a thick medulla region
    • Producing urine many times more concentrated than their body fluids
    • Producing very small quantities of urine
    • Producing very dry faeces which they then consume to reabsorb any remaining water
  • Curiosity about the extent of kangaroo rat water conservation abilities led scientists to investigate whether or not they could survive when given seawater to drink; they found that the kangaroo rats were able to fully excrete the excess salt from seawater with very little increased loss of water!

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Naomi H

Author: Naomi H

Naomi graduated from the University of Oxford with a degree in Biological Sciences. She has 8 years of classroom experience teaching Key Stage 3 up to A-Level biology, and is currently a tutor and A-Level examiner. Naomi especially enjoys creating resources that enable students to build a solid understanding of subject content, while also connecting their knowledge with biology’s exciting, real-world applications.