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First teaching 2014

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Kidney Failure & Urinalysis (DP IB Biology: HL)

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Naomi H

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Naomi H

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Treatment of Kidney Failure

  • Kidney failure can occur in one or both kidneys for a variety of reasons, such as
    • Physical damage from an injury
    • High blood pressure
    • Diabetes
    • Overuse of certain drugs (e.g. aspirin)
    • Infection
  • Kidney failure is dangerous and can be fatal within a relatively short time period
    • Humans can survive with one functioning kidney
  • If the kidneys fail urea is not excreted; this leads to a build-up of urea in the blood which can become toxic at high concentrations
  • Kidney failure can also lead to disruption in the balance of water and solutes in the blood
    • This can lead to problems relating to osmosis and cell damage as well as more specific problems relating to excess quantities of certain mineral ions
  • There are two forms of treatment for kidney failure
    • Dialysis
      • Toxins, metabolic waste products and excess substances are removed from the blood by diffusion through a dialysis membrane
    • Kidney transplant
      • The non-functioning kidneys are replaced with a functioning kidney from a donor
      • Note that the non-functioning kidneys are usually left in place while the new kidney is attached to the blood supply elsewhere in the abdomen

Treatment options for total kidney failure

If both kidneys fail it can be fatal, but there are treatment options.

Haemodialysis

  • Dialysis is a process used to separate small and large molecules with a partially permeable membrane
  • Haemodialysis, also spelled hemodialysis, is a form of dialysis treatment that needs to be carried out several times a week and that requires a dialysis machine
    • Another form of dialysis is known as peritoneal dialysis and involves use of the patient’s own internal membranes rather than a machine
  • Blood flows via a tube from the patient to the dialysis machine
  • Inside the dialysis machine partially permeable dialysis membranes separate the patient's blood from dialysis fluid
  • Small molecules such as urea and salts can fit through pores in the dialysis membrane so exchange of substances can take place
    • The dialysis fluid contains no urea, so there is always a urea diffusion gradient causing urea to diffuse out of the blood and into the fluid
    • The dialysis fluid contains a salt concentration similar to the ideal blood concentration, so diffusion of salts across the membrane only occurs when there is an imbalance
      • If the blood is too high in salts they will diffuse out of the blood and if the blood is too low in salts they will diffuse in
    • The fluid contains a glucose concentration equal to normal blood sugar levels, preventing the outward diffusion of glucose across the membrane when blood glucose levels are normal
      • If blood sugar levels are elevated the glucose will diffuse out of the blood into the fluid
  • The blood and fluid flow in opposite directions to ensure a concentration gradient along the whole length of the membrane
  • The fluid in the machine is also continually refreshed so that concentration gradients are maintained between the dialysis fluids and the blood
    • This means that each time blood circulates through the machine some more of the urea it contains passes into the dialysis fluid, until almost all of it is removed
    • Each haemodialysis session takes 3-4 hours to complete
  • Patients are given a drug that prevents the formation of blood clots during dialysis
    • Such drugs are known as anticoagulants
How dialysis works
Haemodialysis involves passing blood through a dialysis machine, which enables removal of toxic urea and a rebalancing of water and solutes.

Kidney transplant

  • An alternative to potentially restricting dialysis treatments is to have a kidney transplant
  • This involves taking a single, healthy kidney from a donor and transplanting it into a patient with kidney failure
  • Kidney transplants are considered to be a better long term solution to kidney failure than dialysis
    • The patient has more freedom as they no longer need to have dialysis several times a week
    • Patients often feel ill after dialysis and again as toxins start to accumulate a few days later; a transplant enables a patient to be healthy for an extended period
    • Diet can be much less restricted than it needs to be when a patient is on dialysis
  • There are still some risks associated with kidney transplants
    • Donors won’t have the same antigens on their cell surface membranes as the patient so there will be some immune response to the new kidney
    • Immunosuppressant drugs need to be taken for the rest of a patient’s life to reduce the risk of organ rejection; these can leave the patient vulnerable to infections
    • A kidney will often be rejected over time, so a new kidney transplant is often needed after several years
    • There are not enough donors to cope with the demand, and waiting lists are long

Urinalysis

  • Analysing the composition of urine by carrying out urinalysis can tell us a great deal about the health of an individual; urine contains
    • The products of metabolism
    • Molecules that are present in the blood in high concentrations and that fit through the membranes in the glomerulus and Bowman's capsule
    • Drugs that may have been taken into the body
  • Urinalysis shows up any deviations from normal urine composition, aiding with medical diagnoses or detecting drug use
  • Tests that can be carried out during urinalysis include
    • pH testing
      • The pH of urine may influence the development of kidney stones
      • Test strips containing indicator chemicals may change colour when dipped in a urine sample
    • Testing for glucose concentration
      • High glucose levels in the urine can be a sign of diabetes
      • Test strips similar to those used in pH testing can change colour to indicate the glucose concentration of a urine sample
    • Testing for the presence of proteins
      • In normal circumstances proteins are too large to filter through from the glomerulus, so if they are present in the urine this can be a sign of high blood pressure, kidney damage, or diabetes
    • Drugs testing
      • Drugs can be tested for using monoclonal antibodies which bind to specific drugs due to their complementary structure, showing up as a line on a test strip
        • This kind of test works in a similar way to the lateral flow tests or rapid antigen tests that you may have come across when testing for COVID19
      • This is important when testing for e.g. doping in sport
    • Testing for the presence of white blood cells
      • This can be a sign of infection in the urinary tract
    • Pregnancy testing
      • The hormones that circulate in the blood during pregnancy can be detected in the urine using complementary monoclonal antibodies
  • An example of a type of urinalysis that involves a test strip and the use of monoclonal antibodies is the pregnancy test
    • Pregnancy testing sticks contain antibodies that are specific to human chorionic gonadotropin (hCG), a hormone produced during pregnancy
Pregnancy testing stick 1
Pregnancy testing stick 2
Monoclonal antibodies are used to detect the presence of the hormone hCG in the urine of pregnant women.

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Naomi H

Author: Naomi H

Expertise: Biology

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.