Ziehl–Neelsen stain

The Ziehl-Neelsen stain, also known as the acid-fast stain, is a bacteriological staining technique used in cytopathology and microbiology to identify acid-fast bacteria under microscopy, particularly members of the Mycobacterium genus. This staining method was initially introduced by Paul Ehrlich (1854–1915) and subsequently modified by the German bacteriologists Franz Ziehl (1859–1926) and Friedrich Neelsen (1854–1898) during the late 19th century.

Microscopic visualisation of the acid-fast bacteria Mycobacterium tuberculosis (top) and Mycobacterium leprae (bottom) and background cellular material in blue using the Ziehl–Neelsen stain

The acid-fast staining method, in conjunction with auramine phenol staining, serves as the standard diagnostic tool and is widely accessible for rapidly diagnosing tuberculosis (caused by Mycobacterium tuberculosis) and other diseases caused by atypical mycobacteria, such as leprosy (caused by Mycobacterium leprae) and Mycobacterium avium-intracellulare infection (caused by Mycobacterium avium complex) in samples like sputum, gastric washing fluid, and bronchoalveolar lavage fluid. These acid-fast bacteria possess a waxy lipid-rich outer layer that contains high concentrations of mycolic acid, rendering them resistant to conventional staining techniques like the Gram stain.[1][2]

After the Ziehl-Neelsen staining procedure using carbol fuchsin, acid-fast bacteria are observable as vivid red or pink rods set against a blue or green background, depending on the specific counterstain used, such as methylene blue or malachite green, respectively. Non-acid-fast bacteria and other cellular structures will be colored by the counterstain, allowing for clear differentiation.[3]

Mycobacteria

In anatomic pathology specimens, immunohistochemistry and modifications of Ziehl–Neelsen staining (such as Fite-Faraco staining) have comparable diagnostic utility in identifying Mycobacterium. Both of them are superior to traditional Ziehl–Neelsen stain.[4]

Mycobacterium are slow-growing rod-shaped bacilli that are slightly curved or straight, and are considered to be Gram positive. Some mycobacteria are free-living saprophytes, but many are pathogens that cause disease in animals and humans. Mycobacterium bovis causes tuberculosis in cattle. Since tuberculosis can be spread to humans, milk is pasteurized to kill any of the bacteria.[5] Mycobacterium tuberculosis that causes tuberculosis (TB) in humans is an airborne bacterium that typically infects the human lungs.[6][7] Testing for TB includes blood testing, skin tests, and chest X-rays.[8] When looking at the smears for TB, it is stained using an acid-fast stain. These acid-fast organisms like Mycobacterium contain large amounts of lipid substances within their cell walls called mycolic acids. These acids resist staining by ordinary methods such as a Gram stain.[9] It can also be used to stain a few other bacteria, such as Nocardia. The reagents used for Ziehl–Neelsen staining are carbol fuchsin, acid alcohol, and methylene blue. Acid-fast bacilli are bright red after staining.

Fungi

Ziehl–Neelsen staining is a type of narrow spectrum fungal stain. Narrow spectrum fungal stains are selective, and they can help differentiate and identify fungi.[10] The results of Ziehl–Neelsen staining is variable because many fungal cell walls are not acid fast.[11] An example of a common type of acid-fast fungus that is usually stained with Ziehl–Neelsen staining is called Histoplasma (HP).[12] Histoplasma is found in soil and the feces of birds and bats.[13] Humans can contract histoplasmosis by inhalation of the fungal spores. Histoplasma enters the body and goes to the lungs where the spores turn into yeast.[14] The yeast gets into the blood stream and affects lymph nodes and other parts of the body. Usually people do not get sick from inhaling the spores, but if they do they usually have flu like symptoms.[15] Another variation on this staining method is used in mycology to differentially stain acid-fast incrustations in the cuticular hyphae of certain species of fungi in the genus Russula.[16][17] Some free endospores can be confused with small yeasts, so staining is used to identify the unknown fungi.[18] It is also useful in the identification of some protozoa, namely Cryptosporidium and Isospora. The Ziehl–Neelsen stain can also hinder diagnosis in the case of paragonimiasis because the eggs in sputum sample for ovum and parasite (O&P) can be dissolved by the stain, and is often used in this clinical setting because signs and symptoms of paragonimiasis closely resemble those of

History

In 1882 Robert Koch discovered the etiology of tuberculosis.[19] Soon after Koch's discovery, Paul Ehrlich developed a stain for mycobacterium tuberculosis, called the alum hematoxylin stain.[20] Franz Ziehl then altered Ehrlich's staining technique by using carbolic acid as the mordant. Friedrich Neelsen kept Ziehl's choice of mordant but changed the primary stain to carbol fuchsin. Ziehl and Neelsen's modifications together have developed the Ziehl–Neelsen stain. Another acid-fast stain was developed by Joseph Kinyoun by using the Ziehl–Neelsen staining technique but removing the heating step from the procedure. This new stain from Kinyoun was named the Kinyoun stain.

Procedure

Basic steps of the Ziehl-Neelsen staining procedure

A typical AFB stain procedure involves dropping the cells in suspension onto a slide, then air drying the liquid and heat fixing the cells.[21]

Summary of acid-fast stain (Ziehl–Neelsen stain)[22]
Application ofReagentCell colour
Acid fastNon-acid fast
Primary dyeCarbol fuchsinRedRed
DecolorizerAcid alcoholRedColorless
Counter stainMethylene blue/malachite greenRedBlue

Studies have shown that an AFB stain without a culture has a poor negative predictive value. An AFB culture should be performed along with an AFB stain; this has a much higher negative predictive value.

Mechanism explanation

Mechanism of acid-fast staining in acid-fast cells and non-acid-fast cell[23][24][25]

The mechanism of action of the Ziehl-Neelsen stain is not completely understood, but it is thought to involve a chemical reaction between the acidic dyes and the cell walls of the bacteria. The acidity of the dyes causes them to bind more strongly to the cell walls of the bacteria than to other cells or tissues. This results in the selective staining of only those cells that have a high density of cell wall material, such as acid-fast bacteria.[26]

The Ziehl-Neelsen stain is a two step staining process. In the first step, the tissue is stained with a basic fuchsin solution, which stains all cells pink. In the second step, the tissue is incubated in an acid alcohol solution, which decolorizes all cells except for acid-fast cells, which retain the color and appeared as red. The mechanisms by which this color is produced are not well understood, but it is thought that the interaction of the basic fuchsin with the cell wall components of bacteria creates a new molecule that is responsible for the color.[27]

Modifications

See also

References

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  2. Shingadia, Delane; Burgner, David (2008-01-01), Taussig, Lynn M.; Landau, Louis I. (eds.), "Chapter 39 - Mycobacterial Infections", Pediatric Respiratory Medicine (Second Edition), Philadelphia: Mosby, pp. 597–614, doi:10.1016/b978-032304048-8.50043-8, ISBN 978-0-323-04048-8, retrieved 2023-07-28
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  4. Crothers, Jessica W; Laga, Alvaro C; Solomon, Isaac H (2021). "Clinical Performance of Mycobacterial Immunohistochemistry in Anatomic Pathology Specimens". American Journal of Clinical Pathology. 155 (1): 97–105. doi:10.1093/ajcp/aqaa119. ISSN 0002-9173. PMID 32915191.
  5. Sandman, Kathleen; Willey, Joanne; Wood, Dorothy (2020). Prescott's Microbiology (11 ed.). New York, NY: McGraw-Hill Higher Education. p. 541. ISBN 978-1260211887.
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  7. Centers for Disease Control and Prevention. How TB Spreads. March 11, 2016. https://www.cdc.gov/tb/topic/basics/howtbspreads.htm
  8. Centers for Disease Control and Prevention. Testing & Diagnosis. March 11, 2016. https://www.cdc.gov/tb/topic/testing/default.htm
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  10. Veerappan, R; Miller, LE; Sosinski, C; Youngberg, GA (3 November 2006). "Narrow-spectrum staining pattern of Pityrosporum". Journal of Cutaneous Pathology. 33 (11): 731–734. doi:10.1111/j.1600-0560.2006.00537.x. PMID 17083692. S2CID 39812297.
  11. Haque, A. (2010). Special Stains Use in Fungal Infections. Connection: 187-194
  12. Rajeshwari, M.; Xess, I.; Sharma, M. C.; Jain, D. (2017). "Acid-Fastness of Histoplasma in Surgical Pathology Practice". Journal of Pathology and Translational Medicine. 51 (5): 482–487. doi:10.4132/jptm.2017.07.11. PMC 5611531. PMID 28934824.
  13. Centers for Disease Control and Prevention. Histoplasmosis. August 13, 2018. https://www.cdc.gov/fungal/diseases/histoplasmosis/index.html.
  14. Centers for Disease Control and Prevention. Sources of Histoplasmosis. February 11, 2019. https://www.cdc.gov/fungal/diseases/histoplasmosis/causes.html
  15. Centers for Disease Control and Prevention. Symptoms of Histoplasmosis. August 13, 2018. https://www.cdc.gov/fungal/diseases/histoplasmosis/symptoms.html
  16. Romagnesi, H. (1967). Les Russules d'Europe et d'Afrique du Nord. Bordas. ISBN 0-934454-87-6.
  17. Largent, D; D Johnson; R Watling (1977). How to identify fungi to genus III: microscopic features. Mad River Press. p. 25. ISBN 0-916422-09-7.
  18. Youngberg, George A.; Wallen, Ellen D. B.; Giorgadze, Tamar A. (November 2003). "Narrow-spectrum histochemical staining of fungi". Archives of Pathology & Laboratory Medicine. 127 (11): 1529–30. doi:10.5858/2003-127-1529-NHSOF. PMID 14567744.
  19. DiNardo, Andrew R.; Lange, Christoph; Mandalakas, Anna M. (1 May 2016). "Editorial Commentary: 1, 2, 3 (Years) … and You're Out: The End of a 123-year Historic Era". Clinical Infectious Diseases. 62 (9): 1089–1091. doi:10.1093/cid/ciw041. PMID 26839384.
  20. Singhal, Ritu; Myneedu, Vithal Prasad (March 2015). "Microscopy as a diagnostic tool in pulmonary tuberculosis". International Journal of Mycobacteriology. 4 (1): 1–6. doi:10.1016/j.ijmyco.2014.12.006. PMID 26655191.
  21. Leboffe, Michael J.; Pierce, Burton E. (2019). Microbiology Laboratory Theory & Application Essentials. Morton Publishing. p. 179. ISBN 9781640430327.
  22. Acid-Fast Stain- Principle, Procedure, Interpretation and Examples. May 8, 2015 by Sagar Aryal
  23. "Online Microbiology Notes". Online Microbiology Notes. Retrieved 2017-11-29.
  24. "Home – microbeonline". microbeonline.com. Retrieved 2017-11-29.
  25. Kumar, Surinder (2012). Textbook of Microbiology. p. 315.
  26. Ahmed, Gehan Mohammed; Mohammed, Ali Seed Ahmed; Taha, Albadawi Abdulbagi; Almatroudi, Ahmad; Allemailem, Khaled S.; Babiker, Ali Yousif; Alsammani, Mohamed Alkhatim (2019-03-24). "Comparison of the Microwave-Heated Ziehl-Neelsen Stain and Conventional Ziehl-Neelsen Method in the Detection of Acid-Fast Bacilli in Lymph Node Biopsies". Open Access Macedonian Journal of Medical Sciences. 7 (6): 903–907. doi:10.3889/oamjms.2019.215. ISSN 1857-9655. PMID 30976331. S2CID 108292027.
  27. Sharma, Dr Anubhav (2022-10-01). "Ziehl-Neelsen Stain-Ziehl-Neelsen Staining Method - Microbiology". Witfire. Retrieved 2022-10-03.
  28. Ellis, RC; LA Zabrowarny. (1993). "Safer staining method for acid fast bacilli". Journal of Clinical Pathology. 46 (6): 559–560. doi:10.1136/jcp.46.6.559. PMC 501296. PMID 7687254.

Bibliography

  • "Microbiology with Diseases by Body System", Robert W. Bauman, 2009, Pearson Education, Inc.
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