Detergent enzymes explained

Detergent enzymes are biological enzymes that are used with detergents. They catalyze the reaction between stains and the water solution, thus aiding stain removal and improving efficiency.[1] Laundry detergent enzymes are the largest application of industrial enzymes.

They can be a part of both liquid and powder detergents.

History

Otto Röhm introduced the use of enzymes in detergent by using trypsin extracted from the tissues of slaughtered animals. Röhm's formula, though more successful than German household cleaning methods, was considered unstable when used with alkali and bleach. In 1959, yields were improved by microbial synthesis of proteases.[2]

Properties

Laundry enzymes must be able to function normally in a wide array of conditions: water temperatures ranging from 0 to 60 °C; alkaline and acidic environments; solutions with high ionic strength; and the presence of surfactants or oxidizing agents.[3]

Types

The five classes of enzymes found in laundry detergent include proteases, amylases, lipases, cellulases, and mannanases. They break down proteins (e.g. in blood and egg stains), starch, fats, cellulose (e.g. in vegetable puree), and mannans (e.g. in bean gum stains) respectively.[4]

Merits

Household energy savings

For stain removal, conventional household washing machines use heated water, as this increases the solubility of stains. However, heating the water to the required temperature uses a considerable amount of energy; energy usage can be reduced by using detergent enzymes which perform well in cold water, allowing low-temperature washes and removing the need for heated water.[5]

Delicate materials

Clothes made of delicate materials such as wool and silk can be damaged in high-temperature washes, and jeans and denim can fade due to their dark dyes. Low-temperature washes with detergent enzymes can prevent this damage, meaning that consumers can buy clothes from a wider range of materials without worrying about damaging them during washing.

Leather manufacturing

The leather industry was historically considered noxious due to the leather-making process. The traditional procedure involved soaking animal hides in a mixture of urine and lime to remove unwanted hairs, flesh and fat, then kneading them in dog or pigeon feces with bare feet. The subsequent discharge and refuse disposal was severely hazardous to both human health and the environment because of the high amounts of concentrated sulfide and chromium in the effluence.

This method was eventually discarded by the industry in the early 20th century following Röhm's discovery, replaced by a more eco-friendly process involving detergent enzymes. Consequently, hazardous sodium sulfide (used to remove animal hair from hides) usage is lessened by 60%, while water usage for soaking and hair cutting is lowered by 25%. Additionally, toxic pollution and emissions have been reduced by 30%. These enzymes have never completely substituted the industrial chemicals. Nevertheless, the working conditions, wastewater quality, and processing times have been greatly improved.[6]

Replacement for phosphate and synthetic surfactants

Increased legislation has led to a limit on the laundry detergent industry's use of environmentally-unfriendly synthetic surfactants and phosphate salts. In a bid to produce more environmentally-friendly products, several detergent manufacturers have increased their use of enzymes in the production process in combination with lower concentrations of the surfactants and phosphates. These biologically active enzymes include bacteria, yeast, and mushrooms,[7] which produce less chemical pollution and decompose certain toxicants.[8]

Public concerns

Damage to delicate materials

In contrast to the benefits of low-temperature washing, a study of the effects of detergent enzymes on untreated knit and woolen fabrics showed damage proportional to both soaking time and the enzyme concentration.[9]

Skin allergy and testing

Consumers' responses to detergent enzymes have varied. It is reported that some Philippine consumers who are used to laundering by hand slightly suffered from powder detergents, which mainly consisted of laundry enzyme formulations. As a result, it was thought that laundry enzymes have the potential to increase the likelihood of getting occupational type 1 allergic responses.[10] However, a large-scale skin prick test (SPT) containing 15,765 volunteers with 8 different types of detergent enzymes found that the allergy reaction is extremely rare among the public, with only 0.23% showing a reaction.[11] The issue in Filipino consumers is believed to be the rushed hand-laundering method. After various tests with several volunteers worldwide, it is found that exposure to laundry enzymes leads to neither skin allergy (Type I sensitization) nor skin erosion.

Notes and References

  1. Web site: November 8, 2021 . The role of enzymes in detergent products . American Cleaning Institute (ACI) .
  2. Leisola. Matti. Jokela. Jouni. Pastinen. Ossi. Turunen. Ossi. Schoemaker. Hans. INDUSTRIAL USE OF ENZYMES. Physiology and Maintenance. II. 2–3.
  3. Yim. Joung Han. Lee. Jun Hyuck. Koo. Bon-Hun. Kim. Jung Eun. Han. Se Jong. Do. Hackwon. Kim. Dockyu. Lee. Chang Woo. Park. Ha Ju. 2018-02-21. Crystal structure of a cold-active protease (Pro21717) from the psychrophilic bacterium, Pseudoalteromonas arctica PAMC 21717, at 1.4 Å resolution: Structural adaptations to cold and functional analysis of a laundry detergent enzyme. PLOS ONE. en. 13. 2. e0191740. 10.1371/journal.pone.0191740. 1932-6203. 5821440. 29466378. 2018PLoSO..1391740P. free.
  4. Kirk. Ole. Borchert. Torben. Fuglsang. Claus. Industrial enzyme applications. Current Opinion in Biotechnology. 1 August 2002. 13. 4. 345–351. 10.1016/s0958-1669(02)00328-2. 12323357.
  5. Web site: Enzymes in Biological Detergents – The Facts About Laundry Detergents and How They Work. Persil UK. en. 2019-05-19.
  6. Web site: From excrement to enzyme: How biotech helped clean up leather production – Rethink Tomorrow. live. https://web.archive.org/web/20180823230711/http://blog.novozymes.com:80/from-excrement-to-enzyme-how-biotech-helped-clean-up-leather-production/ . 2018-08-23 . 2019-05-19. blog.novozymes.com.
  7. Book: 2016-04-19. Waldhoff. Heinrich. Spilker. Rudiger. Handbook Of Detergents, Part C. 10.1201/9781420030334. 9780429132605.
  8. Gaubert. Alexandra. Jeudy. Jérémy. Rougemont. Blandine. Bordes. Claire. Lemoine. Jérôme. Casabianca. Hervé. Salvador. Arnaud. 2016-07-01. Identification and absolute quantification of enzymes in laundry detergents by liquid chromatography tandem mass spectrometry. Analytical and Bioanalytical Chemistry. en. 408. 17. 4669–4681. 10.1007/s00216-016-9550-8. 1618-2650. 27098933. 39950551.
  9. Friedman. Mendel. April 1971. Effect of Enzymes and Enzyme-Containing Detergent On Strength of Untreated Woolen Fabrics. Textile Research Journal. en. 41. 4. 315–318. 10.1177/004051757104100405. 0040-5175. 137326402.
  10. SARLO. K. CORMIER. E. MACKENZIE. D. SCOTT. L. January 1996. 749 Lack of type I sensitization to laundry enzymes among consumers in the Philippines. Journal of Allergy and Clinical Immunology. 97. 1. 370. 10.1016/s0091-6749(96)80967-5. 0091-6749.
  11. Sarlo. Katherine. Kirchner. Donald B.. Troyano. Esperanza. Smith. Larry A.. Carr. Gregory J.. Rodriguez. Carlos. May 2010. Assessing the risk of type 1 allergy to enzymes present in laundry and cleaning products: Evidence from the clinical data. Toxicology. 271. 3. 87–93. 10.1016/j.tox.2010.03.007. 20223268. 0300-483X.