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Urine test

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(Redirected from Urine analysis) Medical test of urine

Medical diagnostic method
Urine test
A urine sample in a sterile container

A urine test is any medical test performed on a urine specimen. The analysis of urine is a valuable diagnostic tool because its composition reflects the functioning of many body systems, particularly the kidneys and urinary system, and specimens are easy to obtain. Common urine tests include the routine urinalysis, which examines the physical, chemical, and microscopic properties of the urine; urine drug screening; and urine pregnancy testing.

Background

The value of urine for diagnostic purposes has been recognized since ancient times. Urine examination was practiced in Sumer and Babylonia as early as 4000 BC, and is described in ancient Greek and Sanskrit texts. Contemporary urine testing uses a range of methods to investigate the physical and biochemical properties of the urine. For instance, the results of the routine urinalysis can provide information about the functioning of the kidneys and urinary system; suggest the presence of a urinary tract infection (UTI); and screen for possible diabetes or liver disease, among other conditions. A urine culture can be performed to identify the bacterial species involved in a UTI. Simple point-of-care tests can detect pregnancy by identifying the presence of beta-hCG in the urine and indicate the use of recreational drugs by detecting excreted drugs or their metabolites. Analysis of abnormal cells in urine (urine cytology) can help to diagnose some cancers, and testing for organic acids or amino acids in urine can be used to screen for some genetic disorders.

Specimen collection

Example of a container used for collecting 24-hour urine samples. This particular container is free of trace metals to allow for accurate measurement of these substances in urine.

The techniques used to collect urine specimens vary based on the desired test. A random urine, meaning a specimen that is collected at any time, can be used for many tests. However, a sample collected during the first urination of the morning (first morning specimen) is preferred for tests like urinalysis and pregnancy screening because it is typically more concentrated, making the test more sensitive. Because the concentration of many substances in the urine varies throughout the day, some tests require timed urine collections, in which the patient collects all of their urine into a container for a given period of time (commonly 24 hours). A small amount of the specimen is then removed for testing. Timed collections are commonly used to measure creatinine, urea, urine protein, hormones and electrolytes.

If urine is needed for microbiological culture, it is important that the sample is not contaminated. In this case, the proper collection procedure involves cleaning the genital area, beginning to urinate into the toilet, and then filling the specimen container before completing the urination into the toilet. This is called a "midstream clean catch" collection. Research has shown many women are unsure of how to take a midstream sample or why it is needed.

If the subject is not able to urinate voluntarily, samples can be obtained using a urinary catheter or by inserting a needle through the abdomen and into the bladder (suprapubic aspiration). In infants and young children, urine can be collected into a bag attached to the genital region, but this is associated with a high risk of contamination.

Types

Some examples of urine tests include:

Chemistry

Urine dipstick used in urinalysis

Hormones

Microbiology

Two urine specimens cultured on chromogenic agar, which changes colour based on the bacterial species present

Miscellaneous

References

  1. ^ Brunzel 2018, pp. 19–22.
  2. Armstrong JA (March 2007). "Urinalysis in Western culture: a brief history". Kidney International. 71 (5): 384–387. doi:10.1038/sj.ki.5002057. PMID 17191081.
  3. ^ Queremel Milani DA, Jialal I (8 May 2022). "Urinalysis". StatPearls. PMID 32491617. Archived from the original on 5 April 2022. Retrieved 13 July 2022.
  4. ^ Turgeon 2016, p. 505.
  5. ^ Turgeon 2016, p. 216.
  6. ^ Moeller KE, Kissack JC, Atayee RS, Lee KC (May 2017). "Clinical Interpretation of Urine Drug Tests: What Clinicians Need to Know About Urine Drug Screens". Mayo Clinic Proceedings. 92 (5): 774–796. doi:10.1016/j.mayocp.2016.12.007. PMID 28325505. S2CID 21260113.
  7. McPherson & Pincus 2017, p. 479.
  8. ^ Rifai, Horvath & Wittwer 2018, p. 1697.
  9. Mundt & Shanahan 2016, p. 264.
  10. Mundt & Shanahan 2016, pp. 75–6.
  11. "Do women know how to take a urine sample?". NIHR Evidence. 11 December 2022.
  12. Glogowska M, Croxson C, Hayward G (April 2022). "Women's information needs around urine testing for urinary tract infections: a qualitative study". The British Journal of General Practice. 72 (717): e244–e251. doi:10.3399/BJGP.2021.0564. PMC 8869185. PMID 35190371.
  13. McPherson & Pincus 2017, pp. 441–3.
  14. McPherson & Pincus 2017, pp. 167–8.
  15. Turgeon 2016, p. 255.
  16. ^ Brunzel 2018, pp. 51–3.
  17. Wu X (March 2010). "Urinalysis: a review of methods and procedures". Critical Care Nursing Clinics of North America. 22 (1): 121–128. doi:10.1016/j.ccell.2009.10.012. PMID 20193886.
  18. Reddi 2014, pp. 13−4.
  19. McPherson & Pincus 2017, p. 391.
  20. Rifai, Horvath & Wittwer 2018, p. 1421.
  21. Xing J, Reynolds JP (September 2018). "Diagnostic Advances in Urine Cytology". Surgical Pathology Clinics. 11 (3): 601–610. doi:10.1016/j.path.2018.06.001. PMID 30190143. S2CID 52171396.
  22. McPherson & Pincus 2017, p. 253.

Works cited

Components and results of urine tests
Components
Chemical properties
Abnormal findings
Red blood cells
White blood cells
Proteinuria
Small molecules
Other
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