A Petri dish (alternatively known as a Petri plate or cell-culture dish) is a shallow transparent lidded dish that biologists use to hold growth medium in which cells can be cultured,[1][2] originally, cells of bacteria, fungi and small mosses.[3] The container is named after its inventor, German bacteriologist Julius Richard Petri.[4][5][6] It is the most common type of culture plate. The Petri dish is one of the most common items in biology laboratories and has entered popular culture. The term is sometimes written in lower case, especially in non-technical literature.[7][8]

A glass Petri dish with culture

What was later called Petri dish was originally developed by German physician Robert Koch in his private laboratory in 1881, as a precursor method. Petri, as assistant to Koch, at Berlin University made the final modifications in 1887 as used today.

Penicillin, the first antibiotic, was discovered in 1929 when Alexander Fleming noticed that penicillium mold contaminating a bacterial culture in a Petri dish had killed the bacteria around it.

History

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The Petri dish was developed by German physician Julius Richard Petri (after whom the name is given) while working as an assistant to Robert Koch at Berlin University. Petri did not invent the culture dish himself; rather, it was a modified version of Koch's invention[9] which used an agar medium that was developed by Walther Hesse.[10] Koch had published a precursor dish in a booklet in 1881 titled "Zur Untersuchung von Pathogenen Organismen" (Methods for the Study of Pathogenic Organisms),[11] which has been known as the "Bible of Bacteriology".[12][13] He described a new bacterial culture method that used a glass slide with agar and a container (basically a Petri dish, a circular glass dish of 20 × 5 cm with matching lid) which he called feuchte Kammer ("moist chamber"). A bacterial culture was spread on the glass slide, then placed in the moist chamber with a small wet paper. Bacterial growth was easily visible.[14]

Koch publicly demonstrated his plating method at the Seventh International Medical Congress in London in August 1881. There, Louis Pasteur exclaimed, "C'est un grand progrès, Monsieur!" ("What a great progress, Sir!")[15] It was using this method that Koch discovered important pathogens of tuberculosis (Mycobacterium tuberculosis), anthrax (Bacillus anthracis), and cholera (Vibrio cholerae). For his research on tuberculosis, he was awarded the Nobel Prize in Physiology or Medicine in 1905.[16] His students also made important discoveries. Friedrich Loeffler discovered the bacteria of glanders (Burkholderia mallei) in 1882 and diphtheria (Corynebacterium diphtheriae) in 1884; and Georg Theodor August Gaffky, the bacterium of typhoid (Salmonella enterica) in 1884.[17]

Petri made changes in how the circular dish was used. It is often asserted that Petri developed a new culture plate,[18][19][20] but this is incorrect. Instead of using a separate glass slide or plate on which culture media were placed, Petri directly placed media into the glass dish, eliminating unnecessary steps such as transferring the culture media, using the wet paper, and reducing the chance of contamination.[9] He published the improved method in 1887 as "Eine kleine Modification des Koch’schen Plattenverfahrens" ("A minor modification of the plating technique of Koch").[6] Although it could have been named "Koch dish",[14] the final method was given an eponymous name Petri dish.[21]

Features and variants

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Petri dishes are usually cylindrical, mostly with diameters ranging from 30 to 200 millimetres (1.2 to 7.9 in),[22][23] and a height to diameter ratio ranging from 1:10 to 1:4.[24] Squarish versions are also available.[25][26]

Petri dishes were traditionally reusable and made of glass; often of heat-resistant borosilicate glass for proper sterilization at 120–160 °C.[22]

Since the 1960s, plastic dishes, usually disposable, are also common.[27]

The dishes are often covered with a shallow transparent lid, resembling a slightly wider version of the dish itself. The lids of glass dishes are usually loose-fitting.[22] Plastic dishes may have close-fitting covers that delay the drying of the contents.[28] Alternatively, some glass or plastic versions may have small holes around the rim, or ribs on the underside of the cover, to allow for air flow over the culture and prevent water condensation.[29]

Some Petri dishes, especially plastic ones, usually feature rings and/or slots on their lids and bases so that they are less prone to sliding off one another when stacked or sticking to a smooth surface by suction.[28]

Small dishes may have a protruding base that can be secured on a microscope stage for direct examination.[30]

Some versions may have grids printed on the bottom to help in measuring the density of cultures.[31][25][26]

A microplate is a single container with an array of flat-bottomed cavities, each being essentially a small Petri dish. It makes it possible to inoculate and grow dozens or hundreds of independent cultures of dozens of samples at the same time. Besides being much cheaper and convenient than separate dishes, the microplate is also more amenable to automated handling and inspection.

Some plates are separated into different mediums known as biplates, triplates, and quadplates.

Uses

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A Petri dish with bacterial colonies on an agar-based growth medium
 
Axenic cell culture of the plant Physcomitrella patens on an agarplate in a Petri dish

Petri dishes are widely used in biology to cultivate microorganisms such as bacteria, yeasts, and molds. It is most suited for organisms that thrive on a solid or semisolid surface. The culture medium is often an agar plate, a layer a few mm thick of agar or agarose gel containing whatever nutrients the organism requires (such as blood, salts, carbohydrates, amino acids) and other desired ingredients (such as dyes, indicators, and medicinal drugs). The agar and other ingredients are dissolved in warm water and poured into the dish and left to cool down. Once the medium solidifies, a sample of the organism is inoculated ("plated"). The dishes are then left undisturbed for hours or days while the organism grows, possibly in an incubator. They are usually covered, or placed upside-down, to lessen the risk of contamination from airborne spores. Virus or phage cultures require that a population of bacteria be grown in the dish first, which then becomes the culture medium for the viral inoculum.

While Petri dishes are widespread in microbiological research, smaller dishes tend to be used for large-scale studies in which growing cells in Petri dishes can be relatively expensive and labor-intensive.[32][33]

Petri dishes can be used to visualize the location of contamination on surfaces, such as kitchen counters and utensils,[34] clothing, food preparation equipment, or animal and human skin.[35][36] For this application, the Petri dishes may be filled so that the culture medium protrudes slightly above the edges of the dish to make it easier to take samples on hard objects. Shallow Petri dishes prepared in this way are called Replicate Organism Detection And Counting (RODAC) plates and are available commercially.[37][38]

Petri dishes are also used for cell cultivation of isolated cells from eukaryotic organisms, such as in immunodiffusion studies, on solid agar or in a liquid medium.

Petri dishes may be used to observe the early stages of plant germination, and to grow plants asexually from isolated cells.

Petri dishes may be convenient enclosures to study the behavior of insects and other small animals.

Due to their large open surface, Petri dishes are effective containers to evaporate solvents and dry out precipitates, either at room temperature or in ovens and desiccators.

Petri dishes also make convenient temporary storage for samples, especially liquid, granular, or powdered ones, and small objects such as insects or seeds. Their transparency and flat profile allows the contents to be inspected with the naked eye, magnifying glass, or low-power microscope without removing the lid.

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The Petri dish is one of a small number of laboratory equipment items whose name entered popular culture. It is often used metaphorically, e.g. for a contained community that is being studied as if they were microorganisms in a biology experiment, or an environment where original ideas and enterprises may flourish.[7][8][39]

Unicode has a Petri dish emoji, "🧫", which has the code point U+1F9EB (HTML entity "🧫" or "🧫", UTF-8 "0xF0 0x9F 0xA7 0xAB").[40]

See also

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References

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  1. ^ R. C. Dubey (2014): A Textbook Of Biotechnology For Class-XI, 4th edition, p. 469. ISBN 978-8121924177
  2. ^ Mosby's Dental Dictionary (2nd ed.). Elsevier. 2008. Retrieved 2010-02-11.
  3. ^ Ralf Reski (1998). "Development, genetics and molecular biology of mosses" (PDF). Botanica Acta. 111: 1–15. doi:10.1111/j.1438-8677.1998.tb00670.x. Archived from the original (PDF) on 2015-09-24. Retrieved 2015-07-19.
  4. ^ Petri dish Archived 2013-10-22 at the Wayback Machine in the American Heritage Dictionary.
  5. ^ Petri, R.J. (1887). "Eine kleine Modification des Koch'schen Plattenverfahrens" [A small modification of Koch's plate method]. Centralblatt für Bakteriologie und Parasitenkunde (in German). 1: 279–80.
  6. ^ a b Petri, R.J. (1887). "Eine kleine Modification des Koch'schen Plattenverfahrens" [A small modification of Koch's plate method]. Centralblatt für Bakteriologie und Parasitenkunde (English Translation, Braus, 2020) (in German). 1: 279–80.
  7. ^ a b Gary Singer (2018): "Sonder, in the City". Quote: As a native New Yorker, I tend to think of this city as a giant petri dish, in which some of the greatest breakthroughs, inventions, and audacious ideas have been nurtured to fruition. In Angela Dews (ed.) Still, in the City: Creating Peace of Mind in the Midst of Urban Chaos, p. 40. ISBN 978-1510732346
  8. ^ a b Isabel Slone (2018): "What Does the Mall Goth Nostalgia Trend Really Mean?". Quote: "mall goth" was a style of dress that combined the hallmarks of punk, goth and metal subcultures and thrived like bacteria in the petri dish of the early 2000s. Online article in the Fashion Magazine website, May 22, 2018. Accessed on 2019-10-25.
  9. ^ a b Hufford, David C. (1988-03-01). "A Minor Modification by R. J. Petri". Laboratory Medicine. 19 (3): 169–170. doi:10.1093/labmed/19.3.169. ISSN 0007-5027.
  10. ^ Kassinger, Ruth (2019). Slime How Algae Created Us, Plague Us, and Just Might Save Us. Boston, New York: Houghton Mifflin Harcourt. p. 124.
  11. ^ Koch, Robert (2010) [1881]. Zur Untersuchung von Pathogenen Organismen. Berlin: Robert Koch-Institut. doi:10.25646/5071.
  12. ^ Booss, John; Tselis, Alex C. (2014), A history of viral infections of the central nervous system, Handbook of Clinical Neurology, vol. 123, Elsevier, pp. 3–44, doi:10.1016/b978-0-444-53488-0.00001-8, ISBN 978-0-444-53488-0, PMID 25015479, retrieved 2021-04-15
  13. ^ Hurt, Leslie (2003). "Dr. Robert Koch:: a founding father of biology". Primary Care Update for OB/GYNS. 10 (2): 73–74. doi:10.1016/S1068-607X(02)00167-1.
  14. ^ a b Shama, Gilbert (2019). "The "Petri" Dish: A Case of Simultaneous Invention in Bacteriology". Endeavour. 43 (1–2): 11–16. doi:10.1016/j.endeavour.2019.04.001. PMID 31030894. S2CID 139105012.
  15. ^ Sakula, A. (1982). "Robert Koch: centenary of the discovery of the tubercle bacillus, 1882". Thorax. 37 (4): 246–251. doi:10.1136/thx.37.4.246. PMC 459292. PMID 6180494.
  16. ^ Brock, Thomas D. (1999). Robert Koch: A Life in Medicine and Bacteriology. Washington, D.C.: American Society of Microbiology. doi:10.1128/9781555818272. ISBN 978-1-55581-143-3.
  17. ^ Weiss, Robin A. (2005). "Robert Koch: the grandfather of cloning?". Cell. 123 (4): 539–542. doi:10.1016/j.cell.2005.11.001. PMID 16286000.
  18. ^ Blevins, Steve M.; Bronze, Michael S. (2010). "Robert Koch and the 'golden age' of bacteriology". International Journal of Infectious Diseases. 14 (9): e744–751. doi:10.1016/j.ijid.2009.12.003. PMID 20413340.
  19. ^ Zhang, Shuguang (2004). "Beyond the Petri dish". Nature Biotechnology. 22 (2): 151–152. doi:10.1038/nbt0204-151. PMID 14755282. S2CID 36391864.
  20. ^ Grzybowski, Andrzej; Pietrzak, Krzysztof (2014). "Robert Koch (1843-1910) and dermatology on his 171st birthday". Clinics in Dermatology. 32 (3): 448–450. doi:10.1016/j.clindermatol.2013.10.005. PMID 24887990.
  21. ^ Mahajan, Monika (2021). "Etymologia: Petri Dish". Emerging Infectious Diseases. 27 (1): 261. doi:10.3201/eid2701.ET2701. ISSN 1080-6040. PMC 7774570.
  22. ^ a b c (2019): "Product 4909050: PYREX reusable Petri dishes: complete". Fischer Scientific online catalog. Accessed on 2019-10-25.
  23. ^ (2019): "Product BRB011: Petri Dish 200 mm, borosilicate". Rogo-Sampaic online catalog. Accessed on 2019-10-25.
  24. ^ (2019): "Product BTX9302 Corning 100 x 25mm bio-agricultural Petri dishes". Fischer Scientific online catalog. Accessed on 2019-10-25.
  25. ^ a b (2019): "Item 1219C98: Square Petri dish w/ grid". Thomas Scientific online catalog. Accessed on 2019-10-25.
  26. ^ a b (2019): "Product 11708573: Gosselin Square Petri Dish". Fischer Scientific online catalog. Accessed on 2019-10-25.
  27. ^ (2019): "Product BP94S01: Corning 100 x 15mm Polystyrene Petri Dishes". Fischer Scientific online catalog. Accessed on 2019-10-25.
  28. ^ a b (2019): "Item 09-720-500: Fisherbrand disposable Petri dishes". Fischer Scientific online catalog. Accessed on 2019-10-25.
  29. ^ (2019): "Item SB93102: Corning 100x15mm Petri dish with three vents". Fischer Scientific online catalog. Accessed on 2019-10-25.
  30. ^ (2019): "Product PD1504700 MilliporeSigma PetriSlide for contamination analysis". Fischer Scientific online catalog. Accessed on 2019-10-25.
  31. ^ (2019): "Item 41044: Petri dishes made of glass with grid and cover". Assistent (Karl Hecht) online catalog. Accessed on 2019-10-25
  32. ^ Gilbert, P.M. (2010). "Substrate elasticity regulates skeletal muscle stem cell self-renewal in culture". Science. 329 (5995): 1078–81. Bibcode:2010Sci...329.1078G. doi:10.1126/science.1191035. PMC 2929271. PMID 20647425.
  33. ^ Chowdhury, F. (2010). "Soft substrates promote homogeneous self-renewal of embryonic stem cells via downregulating cell-matrix tractions". PLOS ONE. 5 (12): e15655. Bibcode:2010PLoSO...515655C. doi:10.1371/journal.pone.0015655. PMC 3001487. PMID 21179449.
  34. ^ Lemmen, Sebastian W.; Häfner, Helga; Zolldann, Dirk; Amedick, Günter; Lutticken, Rüdolf (2001). "Comparison of two sampling methods for the detection of Gram-positive and Gram-negative bacteria in the environment: Moistened swabs versus Rodac plates". International Journal of Hygiene and Environmental Health. 203 (3): 245–48. doi:10.1078/S1438-4639(04)70035-8. PMID 11279821.
  35. ^ Kasia Galazka (2015): "Here's A Gorgeous Petri Dish Handprint Of An 8-Year-Old After He Played Outside". BuzzFeed.News online article, June 9, 2015. Accessed on 2019-10-25.
  36. ^ Sonja Bäumel (2009): "Oversized petri dish". Culture of microorganisms from the artist's skin pressed onto a body-size culture plate, photographed over the span of 44 days. Part of her (In)visible membrane project. Wageningen, Germany. Accessed on 2019-10-25.
  37. ^ Scott Sutton (2007): "Microbial Surface Monitoring", p. 78. Chapter 5 of Anne Marie Dixon (ed.), Environmental Monitoring for Cleanrooms and Controlled Environments. ISBN 978-1420014853
  38. ^ Géraldine Daneau, Elie Nduwamahoro, Kristina Fissette, Patrick Rüdelsheim, Dick van Soolingen, Bouke C. de Jong, Leen Rigouts (2016): "Use of RODAC plates to measure containment of Mycobacterium tuberculosis in a Class IIB biosafety cabinet during routine operations." International Journal of Mycobacteriology, volume 5, issue 2, pp. 148–54. doi:10.1016/j.ijmyco.2016.01.003
  39. ^ "Definition of petri dish".
  40. ^ (2019): "Emoji List, v12.1". Webpage at the Unicode Consortium website. Accessed on 2019-10-25.
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