Agar

Agar (/ˈɡɑːr/ or /ˈɑːɡər/), or agar-agar, is a jelly-like substance consisting of polysaccharides obtained from the cell walls of some species of red algae, primarily from ogonori (Gracilaria) and "tengusa" (Gelidiaceae).[1][2]

Green tea flavored yōkan, a popular Japanese red bean jelly made from agar
A blood agar plate used to culture bacteria and diagnose infection

As found in nature, agar is a mixture of two components, the linear polysaccharide agarose and a heterogeneous mixture of smaller molecules called agaropectin.[3] It forms the supporting structure in the cell walls of certain species of algae and is released on boiling. These algae are known as agarophytes, belonging to the Rhodophyta (red algae) phylum.[4][5] The processing of food-grade agar removes the agaropectin, and the commercial product is essentially pure agarose.

Agar has been used as an ingredient in desserts throughout Asia and also as a solid substrate to contain culture media for microbiological work. Agar can be used as a laxative; an appetite suppressant; a vegan substitute for gelatin; a thickener for soups; in fruit preserves, ice cream, and other desserts; as a clarifying agent in brewing; and for sizing paper and fabrics.[6][7]

Etymology

The word "agar" comes from agar-agar, the Malay name for red algae (Gigartina, Gracilaria) from which the jelly is produced.[8] It is also known as Kanten (Japanese: 寒天) (from the phrase kan-zarashi tokoroten (寒曬心太) or “cold-exposed agar”), Japanese isinglass, China grass, Ceylon moss or Jaffna moss.[9] Gracilaria lichenoides is specifically referred to as agal-agal or Ceylon agar.[10]

History

Ogonori, the most common red algae used to make agar

Agar may have been discovered in Japan in 1658 by Mino Tarōzaemon (美濃 太郎), an innkeeper in current Fushimi-ku, Kyoto who, according to legend, was said to have discarded surplus seaweed soup (Tokoroten) and noticed that it gelled later after a winter night's freezing.[11] Over the following centuries, agar became a common gelling agent in several Southeast Asian cuisines.[12]

Agar was first subjected to chemical analysis in 1859 by the French chemist Anselme Payen, who had obtained agar from the marine algae Gelidium corneum.[13]

Beginning in the late 19th century, agar began to be used as a solid medium for growing various microbes. Agar was first described for use in microbiology in 1882 by the German microbiologist Walther Hesse, an assistant working in Robert Koch's laboratory, on the suggestion of his wife Fanny Hesse.[14][15] Agar quickly supplanted gelatin as the base of microbiological media, due to its higher melting temperature, allowing microbes to be grown at higher temperatures without the media liquefying.[16]

With its newfound use in microbiology, agar production quickly increased. This production centered on Japan, which produced most of the world's agar until World War II.[17] However, with the outbreak of World War II, many nations were forced to establish domestic agar industries in order to continue microbiological research.[17] Around the time of World War II, approximately 2,500 tons of agar were produced annually.[17] By the mid-1970s, production worldwide had increased dramatically to approximately 10,000 tons each year.[17] Since then, production of agar has fluctuated due to unstable and sometimes over-utilized seaweed populations.[18]

Composition

The structure of an agarose polymer.

Agar consists of a mixture of two polysaccharides: agarose and agaropectin, with agarose making up about 70% of the mixture.[19] Agarose is a linear polymer, made up of repeating units of agarobiose, a disaccharide made up of D-galactose and 3,6-anhydro-L-galactopyranose.[20] Agaropectin is a heterogeneous mixture of smaller molecules that occur in lesser amounts, and is made up of alternating units of D-galactose and L-galactose heavily modified with acidic side-groups, such as sulfate and pyruvate.[21][19][20]

Agar exhibits hysteresis, solidifying at about 32–40 °C (305–313 K, 90–104 °F) but melting at 85 °C (358  K, 185 °F).[22] This property lends a suitable balance between easy melting and good gel stability at relatively high temperatures. Since many scientific applications require incubation at temperatures close to human body temperature (37 °C), agar is more appropriate than other solidifying agents that melt at this temperature, such as gelatin.

Uses

Culinary

Sago at gulaman in Filipino cuisine is made from agar (gulaman), pearl sago, and sugar syrup flavored with pandan

Agar-agar is a natural vegetable gelatin counterpart. It is white and semi-translucent when sold in packages as washed and dried strips or in powdered form. It can be used to make jellies, puddings, and custards. When making jelly, it is boiled in water until the solids dissolve. Sweetener, flavoring, coloring, fruits and or vegetables are then added, and the liquid is poured into molds to be served as desserts and vegetable aspics or incorporated with other desserts such as a layer of jelly in a cake.

Agar-agar is approximately 80% dietary fiber, so it can serve as an intestinal regulator. Its bulking quality has been behind fad diets in Asia, for example the kanten (the Japanese word for agar-agar[5]) diet. Once ingested, kanten triples in size and absorbs water. This results in the consumers feeling fuller.

Asian culinary

One use of agar in Japanese cuisine (Wagashi) is anmitsu, a dessert made of small cubes of agar jelly and served in a bowl with various fruits or other ingredients. It is also the main ingredient in mizu yōkan, another popular Japanese food. In Philippine cuisine, it is used to make the jelly bars in the various gulaman refreshments like Sago't Gulaman, Samalamig, or desserts such as buko pandan, agar flan, halo-halo, fruit cocktail jelly, and the black and red gulaman used in various fruit salads. In Vietnamese cuisine, jellies made of flavored layers of agar agar, called thạch, are a popular dessert, and are often made in ornate molds for special occasions. In Indian cuisine, agar is used for making desserts. In Burmese cuisine, a sweet jelly known as kyauk kyaw is made from agar. Agar jelly is widely used in Taiwanese bubble tea.

Other culinary

It can be used as addition to or as a replacement for pectin in jams and marmalades, as a substitute to gelatin for its superior gelling properties, and as a strengthening ingredient in souffles and custards. Another use of agar-agar is in a Russian dish ptich'ye moloko (bird's milk), a rich jellified custard (or soft meringue) used as a cake filling or chocolate-glazed as individual sweets.

Agar-agar may also be used as the gelling agent in gel clarification, a culinary technique used to clarify stocks, sauces, and other liquids. Mexico has traditional candies made out of Agar gelatin, most of them in colorful, half-circle shapes that resemble a melon or watermelon fruit slice, and commonly covered with sugar. They are known in Spanish as Dulce de Agar (Agar sweets)

Agar-agar is an allowed nonorganic/nonsynthetic additive used as a thickener, gelling agent, texturizer, moisturizer, emulsifier, flavor enhancer, and absorbent in certified organic foods.[23]

Agar plate

100mm (4") diameter Petri dishes containing agar gel for bacterial culture

An agar plate or Petri dish is used to provide a growth medium using a mix of agar and other nutrients in which microorganisms, including bacteria and fungi, can be cultured and observed under the microscope. Agar is indigestible for many organisms so that microbial growth does not affect the gel used and it remains stable. Agar is typically sold commercially as a powder that can be mixed with water and prepared similarly to gelatin before use as a growth medium. Other ingredients are added to the agar to meet the nutritional needs of the microbes. Many microbe-specific formulations are available because some microbes prefer certain environmental conditions over others. Agar is often dispensed using a sterile media dispenser.

Motility assays

As a gel, an agar or agarose medium is porous and therefore can be used to measure microorganism motility and mobility. The gel's porosity is directly related to the concentration of agarose in the medium, so various levels of effective viscosity (from the cell's "point of view") can be selected, depending on the experimental objectives.

A common identification assay involves culturing a sample of the organism deep within a block of nutrient agar. Cells will attempt to grow within the gel structure. Motile species will be able to migrate, albeit slowly, throughout the gel, and infiltration rates can then be visualized, whereas non-motile species will show growth only along the now-empty path introduced by the invasive initial sample deposition.

Another setup commonly used for measuring chemotaxis and chemokinesis utilizes the under-agarose cell migration assay, whereby a layer of agarose gel is placed between a cell population and a chemoattractant. As a concentration gradient develops from the diffusion of the chemoattractant into the gel, various cell populations requiring different stimulation levels to migrate can then be visualized over time using microphotography as they tunnel upward through the gel against gravity along the gradient.

Plant biology

Physcomitrella patens plants growing axenically in vitro on agar plates (Petri dish, 9 cm, 3½" diameter).

Research grade agar is used extensively in plant biology as it is optionally supplemented with a nutrient and/or vitamin mixture that allows for seedling germination in Petri dishes under sterile conditions (given that the seeds are sterilized as well). Nutrient and/or vitamin supplementation for Arabidopsis thaliana is standard across most experimental conditions. Murashige & Skoog (MS) nutrient mix and Gamborg's B5 vitamin mix in general are used. A 1.0% agar/0.44% MS+vitamin dH2O solution is suitable for growth media between normal growth temps.

When using agar, within any growth medium, it is important to know that the solidification of the agar is pH-dependent. The optimal range for solidification is between 5.4 and 5.7.[24] Usually, the application of potassium hydroxide is needed to increase the pH to this range. A general guideline is about 600 µl 0.1M KOH per 250 ml GM. This entire mixture can be sterilized using the liquid cycle of an autoclave.

This medium nicely lends itself to the application of specific concentrations of phytohormones etc. to induce specific growth patterns in that one can easily prepare a solution containing the desired amount of hormone, add it to the known volume of GM, and autoclave to both sterilize and evaporate off any solvent that may have been used to dissolve the often-polar hormones. This hormone/GM solution can be spread across the surface of Petri dishes sown with germinated and/or etiolated seedlings.

Experiments with the moss Physcomitrella patens, however, have shown that choice of the gelling agent – agar or Gelrite – does influence phytohormone sensitivity of the plant cell culture.[25]

Other uses

Agar is used:

  • As an impression material in dentistry.
  • As a medium to precisely orient the tissue specimen and secure it by agar pre-embedding (especially useful for small endoscopy biopsy specimens) for histopathology processing[26]
  • To make salt bridges and gel plugs for use in electrochemistry.
  • In formicariums as a transparent substitute for sand and a source of nutrition.
  • As a natural ingredient in forming modeling clay for young children to play with.
  • As an allowed biofertilizer component in organic farming.[27]
  • As a substrate for precipitin reactions in immunology.
  • At different times as a substitute for gelatin in photographic emulsions, arrowroot in preparing silver paper and as a substitute for fish glue in resist etching.[28]
  • As an MRI elastic gel phantom to mimic tissue mechanical properties in Magnetic Resonance Elastography[29]

Gelidium agar is used primarily for bacteriological plates. Gracilaria agar is used mainly in food applications.

In 2016, AMAM, a Japanese company, developed a prototype for Agar-based commercial packaging system called Agar Plasticity, intended as a replacement for oil-based plastic packaging.[30][31]

See also

References

  1. Shimamura, Natsu (August 4, 2010). "Agar". The Tokyo Foundation. Retrieved 19 December 2016.
  2. Oxford Dictionary of English (2 ed.). 2005.
  3. Williams, Peter W.; Phillips, Glyn O. Agar is made from seaweed and it is attracted to bacteria. (2000). "Chapter 2: Agar". Handbook of hydrocolloids. Cambridge: Woodhead. p. 91. ISBN 1-85573-501-6.
  4. Edward Balfour (1871). Cyclopædia of India and of eastern and southern Asia, commercial, industrial and scientific: products of the mineral, vegetable and animal kingdoms, useful arts and manufactures. Scottish and Adelphi Presses. p. 50. agar.
  5. Alan Davidson (2006). The Oxford Companion to Food. Oxford University Press. ISBN 978-0-19-280681-9.
  6. "Showing Food Agar". The Metabolomics Innovation Centre (TMIC). Archived from the original on 2021-05-09.
  7. Edward Green Balfour (1857). Cyclopaedia of India and of Eastern and Southern Asia, commercial, industrial and scientific... printed at the Scottish Press. p. 13.
  8. Balfour, Edward. (1885). The cyclopædia of India and of eastern and southern Asia: commercial, industrial and scientific, products of the mineral, vegetable, and animal kingdoms, useful arts and manufactures. B. Quaritch. p. 71.
  9. Agar-Agar Archived 2011-09-03 at the Wayback Machine at Agar-Agar.org
  10. "Agar-Agar". Botanical.com. Retrieved 22 January 2017.
  11. Mary Jo Zimbro; David A. Power; Sharon M. Miller; George E. Wilson; Julie A. Johnson (eds.). Difco & BBL Manual (PDF) (2nd ed.). Becton Dickinson and Company. p. 6. Archived from the original (PDF) on 2012-06-06. Retrieved 2013-07-17.
  12. Hopley, David (2010). Encyclopedia of Modern Coral Reefs: Structure, Form and Process. Springer Science & Business Media. p. 31. ISBN 9789048126385.
  13. Payen, Anselme (1859) "Sur la gélose et le nids de salangane" (On agar and swiftlet nests), Comptes rendus …, 49 : 521–530, appended remarks 530–532.
  14. Robert Koch (10 April 1882) "Die Aetiologie der Tuberculose" (The etiology of tuberculosis), Berliner Klinische Wochenschrift (Berlin Clinical Weekly), 19 : 221–230. From p. 225: "Die Tuberkelbacillen lassen sich auch noch auf anderen Nährsubstraten kultiviren, wenn letztere ähnliche Eigenschaften wie das erstarrte Blutserum besitzen. So wachsen sie beispielsweise auf einer mit Agar-Agar bereiteten, bei Blutwärme hart bleibenden Gallerte, welche einen Zusatz von Fleischinfus und Pepton erhalten hat." (The tubercule bacilli can also be cultivated on other media, if the latter have properties similar to those of congealed blood serum. Thus they grow, for example, on a gelatinous mass which was prepared with agar-agar, which remains solid at blood temperature, and which has received a supplement of meat broth and peptone.)
  15. Smith, A. (November 1, 2005). "History of the Agar Plate". Laboratory News. Archived from the original on October 14, 2012. Retrieved November 3, 2012.
  16. Hesse, W. (1992). Translated by Gröschel, D.H.M. "Walther and Angelina Hesse–Early Contributors to Bacteriology" (PDF). ASM News. 58 (8): 425–428. Archived from the original (PDF) on 30 June 2017. Retrieved 22 January 2017.
  17. Lobban, Christopher S.; Wynne, Michael James (1981). The Biology of Seaweeds. University of California Press. pp. 734–735. ISBN 9780520045859.
  18. Ewen Callaway (8 December 2015). "Lab staple agar hit by seaweed shortage". Nature. Nature News. 528 (7581): 171–172. Bibcode:2015Natur.528..171C. doi:10.1038/528171a. PMID 26659158.
  19. "III: Properties, Manufacture, and Application of Seaweed Polysaccharides – Agar, Carageenan, and Algin". Training manual on Gracilaria culture and seaweed processing in China. Food and Agriculture Organization, United Nations. August 1990. Retrieved 2011-04-27.
  20. Rafael Armisen; Fernando Galatas (1987). "Chapter 1 – Production, Properties and Uses of Agar". In McHugh DJ (ed.). Production and Utilization of Products from Commercial Seaweeds. Food and Agriculture Organization, United Nations. ISBN 92-5-102612-2.
  21. Agar Archived October 16, 2007, at the Wayback Machine at lsbu.ac.uk Water Structure and Science
  22. "All About Agar". Sciencebuddies.org. Archived from the original on 3 June 2011. Retrieved 2011-04-27.
  23. Agar-agar Review Sheet Archived 2015-06-20 at the Wayback Machine, USDA Organic Materials Review, April 1995.
  24. Kim, Se-Kwon (2011). Handbook of marine macroalgae : biotechnology and applied phycology (1st imp. ed.). Hoboken, NJ: John Wiley & Sons Inc. ISBN 9780470979181.
  25. Birgit Hadeler; Sirkka Scholz; Ralf Reski (1995). "Gelrite and agar differently influence cytokinin-sensitivity of a moss". Journal of Plant Physiology. 146 (3): 369–371. doi:10.1016/s0176-1617(11)82071-7.
  26. Yadav, Lokenddra; Thomas, Sarega; Kini, Usha (February 2015). "Improvised double-embedding technique of minute biopsies: A mega boon to histopathology laboratory". Indian Journal of Pathology and Microbiology. 58 (1): 12–6. doi:10.4103/0377-4929.151156. PMID 25673584.
  27. Integrated Organic Farming Handbook, H. Panda, Asia Pacific Business Press Inc., Oct 4, 2013
  28. Walker, Ernie (June 1986). "Black-and-White Photographic Chemistry" (PDF). NASA Technical Reports Server. Archived (PDF) from the original on 2022-10-09.
  29. McIlvain, Grace; Ganji, Elahe; Cooper, Catherine; Killian, Megan L.; Ogunnaike, Babatunde A.; Johnson, Curtis L. (September 2019). "Reliable preparation of agarose phantoms for use in quantitative magnetic resonance elastography". Journal of the Mechanical Behavior of Biomedical Materials. 97: 65–73. doi:10.1016/j.jmbbm.2019.05.001. PMC 6699912. PMID 31100487.
  30. "New Seaweed-Based Material Could Replace Plastic Packaging". Good Magazine. 2016-03-09. Retrieved 2016-04-03.
  31. "Design Looks Ahead". Fast Company. 26 January 2016. Retrieved 2016-04-03.
  • The dictionary definition of agar at Wiktionary
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