Drug pollution explained

See also: Environmental impact of pharmaceuticals and personal care products.

Drug pollution or pharmaceutical pollution is pollution of the environment with pharmaceutical drugs and their metabolites, which reach the aquatic environment (groundwater, rivers, lakes, and oceans) through wastewater. Drug pollution is therefore mainly a form of water pollution.

"Pharmaceutical pollution is now detected in waters throughout the world," said a scientist at the Cary Institute of Ecosystem Studies in Millbrook, New York. "Causes include aging infrastructure, sewage overflows and agricultural runoff. Even when wastewater makes it to sewage treatment facilities, they aren't equipped to remove pharmaceuticals."

Sources and effects

Most simply from the drugs having been cleared and excreted in the urine. The portion that comes from expired or unneeded drugs that are flushed unused down the toilet is smaller, but it is also important, especially in hospitals (where its magnitude is greater than in residential contexts). This includes drug molecules that are too small to be filtered out by existing water treatment plants. The process of upgrading existing plants to use advanced oxidation processes that are able to remove these molecules can be expensive. Drugs such as antidepressants have been found in the United States Great Lakes. Researchers from the University of Buffalo have found high traces of antidepressants in the brains of fish. Fish behavior on antidepressants have been noted to have similar impacts and reducing risk-averse behavior, and thereby reducing survival through predation.[1] [2]

Other sources include agricultural runoff (because of antibiotic use in livestock) and pharmaceutical manufacturing. Drug pollution is implicated in the sex effects of water pollution. It is a suspected a contributor (besides industrial pollution) in fish kills, amphibian dieoffs, and amphibian pathomorphology.

Pollution of water systems

In the early 1990s, pharmaceuticals were found to be present in the environment, which resulted in massive scientific research, new regulations, and public attention.[3] Also during the 1990s, it was discovered that for the synthesis of one kilogram of an active pharmaceutical compound the amount of waste produced was fifty to hundred times that one kilogram,[4] which was ending up in the environment. During the late 1990s, estrogens were discovered in wastewater. It was concluded that this was the cause of feminization of fish. This was another factor that caused greater attention to pharmaceuticals in the environment.[5] Reviews and information on pharmaceuticals present in the environment date back to at least the 1980s.[6] The majority of pharmaceuticals are intended to cause slight adverse effects for the target population.[3] Low concentrations of pharmaceuticals can have negative effects on the freshwater ecosystems.[7]

Pharmaceuticals in the environment

In the United States, Spain, Germany and the United Kingdom over 101 different pharmaceuticals were present in ground water, surface water, drinking water or tap water. Between 30 and 100 different pharmaceuticals were found present in the aforementioned waters in Thailand, Canada, Australia, India, China, South Korea, Japan, Sweden, Poland, Italy, the Netherlands, France and Brazil.

Pharmaceuticals and their effects

Groundwater pollution

Prevention

Drug pollution still remains to be a global problem, since current policy techniques are not adequate enough. Most policy approaches remain to be individualized, expensive, and reactive.[7] Biomarkers could be extremely helpful in the risk assessment of pharmaceuticals for decision making in regulations. Biomarkers could help explain if a non-target organism was exposed to a pharmaceutical and the toxicity levels of the pharmaceutical in the organism if it is present.[3]

The main action for preventing drug pollution is to incinerate unwanted pharmaceutical drugs. Burning them chemically degrades their active molecules, with few exceptions. The resulting ash can be further processed before landfilling, such as to remove and recycle any heavy metals that may be present.

There are now programs in many cities that provide collection points at places including drug stores, grocery stores, and police stations. People can bring their unwanted pharmaceuticals there for safe disposal, instead of flushing them (externalizing them to the waterways) or throwing them in the trash (externalizing them to a landfill, where they can become leachate).

Another aspect of drug pollution prevention is environmental law and regulation, although this faces the problems of enforcement costs, enforcement corruption and negligence (see below), and, where enforcement succeeds, increased costs of doing business. The lobbying of pros and cons is ongoing.

Manufacturing

One extreme example of drug pollution was found in India in 2009 in an area where pharmaceutical manufacturing activity is concentrated. Not all pharmaceutical manufacturing contributes to the problem. In places where environmental law and regulation are adequately enforced, the wastewater from the factories is cleaned to a safe level. But to the extent that the market rewards "looking the other way" in developing nations, whether through local corruption (bribed inspectors or regulators) or plausible deniability, such protections are circumvented. This problem belongs to everyone, because consumers in well-regulated places constitute the biggest customers of the factories that operate in the inadequately regulated or inspected places, meaning that externality is involved.

External links

Notes and References

  1. News: Antidepressants are finding their way into fish brains. The Economist. en. 2018-03-18. 2018-03-17. https://web.archive.org/web/20180317173824/https://www.economist.com/news/united-states/21736558-thats-bad-news-fish-antidepressants-are-finding-their-way-fish-brains. live.
  2. Martin. Jake M.. Saaristo. Minna. Bertram. Michael G.. Lewis. Phoebe J.. Coggan. Timothy L.. Clarke. Bradley O.. Wong. Bob B.M.. March 2017. The psychoactive pollutant fluoxetine compromises antipredator behaviour in fish. Environmental Pollution. 222. 592–599. 10.1016/j.envpol.2016.10.010. 28063712. 0269-7491.
  3. Ankley. Gerald T.. Brooks. Bryan W.. Huggett. Duane B.. Sumpter. and John P.. December 2007. Repeating History: Pharmaceuticals in the Environment. Environmental Science & Technology. en. 41. 24. 8211–8217. 10.1021/es072658j. 18200843. 2007EnST...41.8211A. 0013-936X. free.
  4. Kümmerer. Klaus. 2010-11-21. Pharmaceuticals in the Environment. Annual Review of Environment and Resources. en. 35. 1. 57–75. 10.1146/annurev-environ-052809-161223. 1543-5938. free.
  5. Larsson. D. G. Joakim. 2014-11-19. Pollution from drug manufacturing: review and perspectives. Philosophical Transactions of the Royal Society B: Biological Sciences. 369. 1656. 20130571. 10.1098/rstb.2013.0571. 25405961. 4213584. 0962-8436. free.
  6. Murray-Smith. Richard J. Coombe. Vyvyan T. Grönlund. Marie Haag. Waern. Fredrik. Baird. James A. 2012-01-13. Managing emissions of active pharmaceutical ingredients from manufacturing facilities: An environmental quality standard approach. Integrated Environmental Assessment and Management. 8. 2. 320–330. 10.1002/ieam.1268. 22057894. 11765507 . 1551-3777.
  7. Pharmaceutical Residues in Freshwater Hazards and Policy Responses. OECD Studies on Water . 13 November 2019. OECD Studies on Water, OECD Publishing. 10.1787/c936f42d-en. Paris. 9789264776333 . 23 July 2021. 27 January 2021. https://web.archive.org/web/20210127135919/https://www.oecd.org/publications/pharmaceutical-residues-in-freshwater-c936f42d-en.htm. live.
  8. Escudero. J.. Muñoz. J.L.. Morera-Herreras. T.. Hernandez. R.. Medrano. J.. Domingo-Echaburu. S.. Barceló. D.. Orive. G.. Lertxundi. U.. May 2021. Antipsychotics as environmental pollutants: An underrated threat?. Science of the Total Environment. 769. 144634. 10.1016/j.scitotenv.2020.144634. 33485196. 2021ScTEn.769n4634E. 231693580 . 0048-9697. 10261/229106. free.
  9. Yadav. Ankush. Rene. Eldon R.. Mandal. Mrinal Kanti. Dubey. Kashyap Kumar. January 2021. Threat and sustainable technological solution for antineoplastic drugs pollution: Review on a persisting global issue. Chemosphere. 263. 128285. 10.1016/j.chemosphere.2020.128285. 33297229. 2021Chmsp.263l8285Y. 225035554 . 0045-6535.
  10. Wang. Jianlong. Zhuan. Run. Chu. Libing. January 2019. The occurrence, distribution and degradation of antibiotics by ionizing radiation: An overview. Science of the Total Environment. 646. 1385–1397. 10.1016/j.scitotenv.2018.07.415. 30235624. 2019ScTEn.646.1385W. 52309095 . 0048-9697.