Medicine:Biomedical waste

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Short description: Waste containing infectious material


Biomedical waste or hospital waste is any kind of waste containing infectious (or potentially infectious) materials generated during the treatment of humans or animals as well as during research involving biologics.[1] It may also include waste associated with the generation of biomedical waste that visually appears to be of medical or laboratory origin (e.g. packaging, unused bandages, infusion kits etc.), as well research laboratory waste containing biomolecules or organisms that are mainly restricted from environmental release. As detailed below, discarded sharps are considered biomedical waste whether they are contaminated or not, due to the possibility of being contaminated with blood and their propensity to cause injury when not properly contained and disposed. Biomedical waste is a type of biowaste.

Biomedical waste may be solid or liquid. Examples of infectious waste include discarded blood, sharps, unwanted microbiological cultures and stocks, identifiable body parts (including those as a result of amputation), other human or animal tissue, used bandages and dressings, discarded gloves, other medical supplies that may have been in contact with blood and body fluids, and laboratory waste that exhibits the characteristics described above. Waste sharps include potentially contaminated used (and unused discarded) needles, scalpels, lancets and other devices capable of penetrating skin.

Biomedical waste is generated from biological and medical sources and activities, such as the diagnosis, prevention, or treatment of diseases. Common generators (or producers) of biomedical waste include hospitals, health clinics, nursing homes, emergency medical services, medical research laboratories, offices of physicians, dentists, veterinarians, home health care and morgues or funeral homes. In healthcare facilities (i.e. hospitals, clinics, doctor's offices, veterinary hospitals and clinical laboratories), waste with these characteristics may alternatively be called medical or clinical waste.

Biomedical waste is distinct from normal trash or general waste, and differs from other types of hazardous waste, such as chemical, radioactive, universal or industrial waste. Medical facilities generate waste hazardous chemicals and radioactive materials. While such wastes are normally not infectious, they require proper disposal. Some wastes are considered multihazardous, such as tissue samples preserved in formalin.

Effects on humans

Sharpsmart Needle Container
Sharpsmart Reusable Sharps Container

Disposal of this waste is an environmental concern, as many medical wastes are classified as infectious or biohazardous and could potentially lead to the spread of infectious disease. The most common danger for humans is the infection which also affects other living organisms in the region. Daily exposure to the wastes (landfills) leads to accumulation of harmful substances or microbes in the person's body.

A 1990 report by the United States Agency for Toxic Substances and Disease Registry concluded that the general public is not likely to be adversely affected by biomedical waste generated in the traditional healthcare setting. They found, however, that biomedical waste from those settings may pose an injury and exposure risks via occupational contact with medical waste for doctors, nurses, and janitorial, laundry and refuse workers. Further, there are opportunities for the general public to come into contact with medical waste, such as needles used illicitly outside healthcare settings, or biomedical waste generated via home health care.[2]

Management

Biomedical waste must be properly managed and disposed of to protect the environment, general public and workers, especially healthcare and sanitation workers who are at risk of exposure to biomedical waste as an occupational hazard. Steps in the management of biomedical waste include generation, accumulation, handling, storage, treatment, transport and disposal.[3]

The development and implementation of a national waste management policy can improve biomedical waste management in health facilities in a country.[4]

On-site versus off-site

Two people wearing full protective clothing move a plastic trash bag into a marked spot, while their trainer watches them. their trainer.
These healthcare workers are being trained to safely handle contaminated wastes before being assigned to an outbreak of Ebola hemorrhagic fever.

Disposal occurs off-site, at a location that is different from the site of generation. Treatment may occur on-site or off-site. On-site treatment of large quantities of biomedical waste usually requires the use of relatively expensive equipment, and is generally only cost effective for very large hospitals and major universities who have the space, labour and budget to operate such equipment. Off-site treatment and disposal involves hiring of a biomedical waste disposal service (also called a truck service) whose employees are trained to collect and haul away biomedical waste in special containers (usually cardboard boxes, or reusable plastic bins) for treatment at a facility designed to handle biomedical waste.

Generation and accumulation

Biomedical waste should be collected in containers that are leak-proof and sufficiently strong to prevent breakage during handling. Containers of biomedical waste are marked with a biohazard symbol. The container, marking, and labels are often red.

Discarded sharps are usually collected in specialized boxes, often called needle boxes.

Specialized equipment is required to meet OSHA 29 CFR 1910.1450[5] and EPA 40 CFR 264.173.[6] standards of safety. Minimal recommended equipment include a fume hood and primary and secondary waste containers to capture potential overflow. Even beneath the fume hood, containers containing chemical contaminants should remain closed when not in use. An open funnel placed in the mouth of a waste container has been shown to allow significant evaporation of chemicals into the surrounding atmosphere, which is then inhaled by laboratory personnel, and contributes a primary component to the threat of completing the fire triangle. To protect the health and safety of laboratory staff as well as neighboring civilians and the environment, proper waste management equipment, such as the Burkle funnel in Europe and the ECO Funnel in the U.S., should be utilized in any department which deals with chemical waste. It is to be dumped after treatment.

Storage and handling

Storage refers to keeping the waste until it is treated on-site or transported off-site for treatment or disposal. There are many options and containers for storage. Regulatory agencies may limit the time for which waste can remain in storage. Handling is the act of moving biomedical waste between the point of generation, accumulation areas, storage locations and on-site treatment facilities. Workers who handle biomedical waste must observe standard precautions.[7]

Treatment

The goals of biomedical waste treatment are to reduce or eliminate the waste's hazards, and usually to make the waste unrecognizable. Treatment should render the waste safe for subsequent handling and disposal. There are several treatment methods that can accomplish these goals. It includes segregating the bio waste.

Biomedical waste is often incinerated. An efficient incinerator will destroy pathogens and sharps. Source materials are not recognizable in the resulting ash. Alternative thermal treatment can also include technologies such as gasification[8] and pyrolysis including energy recovery with similar waste volume reductions and pathogen destruction.  

An autoclave may also be used to treat biomedical waste. An autoclave uses steam and pressure to sterilize the waste or reduce its microbiological load to a level at which it may be safely disposed of. Many healthcare facilities routinely use an autoclave to sterilize medical supplies. If the same autoclave is used to sterilize supplies and treat biomedical waste, administrative controls must be used to prevent the waste operations from contaminating the supplies. Effective administrative controls include operator training, strict procedures, and separate times and space for processing biomedical waste.

Microwave disinfection can also be employed for treatment of Biomedical wastes. Microwave irradiation is a type of non-contact heating technologies for disinfection. Microwave chemistry is based on efficient heating of materials by microwave dielectric heating effects. When exposed to microwave frequencies, the dipoles of the water molecules present in cells re-align with the applied electric field. As the field oscillates, the dipoles attempts to realign itself with the alternating electric field and in this process, energy is lost in the form of heat through molecular friction and dielectric loss. Microwave disinfection is a recently developed technology which provides advantage over old existing technologies of autoclaves as microwave based disinfection has less cycle time, power consumption and it requires minimal usage of water and consumables as compared to autoclaves.

For liquids and small quantities, a 1–10% solution of bleach can be used to disinfect biomedical waste. Solutions of sodium hydroxide and other chemical disinfectants may also be used, depending on the waste's characteristics. Other treatment methods include heat, alkaline digesters and the use of microwaves.

For autoclaves and microwave systems, a shredder may be used as a final treatment step to render the waste unrecognizable. Some autoclaves have built in shredders.

Country-wise regulation and management

The international symbol for biological hazard.

United Kingdom

In the UK, clinical waste and the way it is to be handled is closely regulated.[9] Applicable legislation[10] includes the Environmental Protection Act 1990 (Part II), Waste Management Licensing Regulations 1994, and the Hazardous Waste Regulations (England & Wales) 2005, as well as the Special Waste Regulations in Scotland. A scandal erupted in October 2018 when it emerged that Healthcare Environment Services, which had contracts for managing clinical waste produced by the NHS in Scotland and England, was in breach of the environmental permits at four of its six sites by having more waste on site than their permit allows and storing waste inappropriately. Seventeen NHS trusts in Yorkshire terminated their contracts immediately. The company sued for compensation.[11] Amputated limbs were said to be among 350 tonnes of clinical waste stockpiled instead of incinerated in Normanton.[12] The company maintains that the problem was caused by a reduction in incineration capacity, and the re-classification of clinical waste as "offensive", which meant more needed incineration. The government's contingency plans included installing temporary storage units at hospitals, but the company say that this is more dangerous than allowing them to exceed their permitted allowances. The company still has contracts with 30 other trusts in England, and a waste disposal contract with NHS England for primary care and pharmacy.[13]

United States

In the United States, biomedical waste is usually regulated as medical waste. In 1988 the U.S. federal government passed the Medical Waste Tracking Act which allowed the EPA to establish rules for management of medical waste in some parts of the country. After the Act expired in 1991, responsibility to regulate and pass laws concerning the disposal of medical waste returned to the individual states. The states vary in their regulations from none to very strict.

In addition to on-site treatment or pickup by a biomedical waste disposal firm for off-site treatment, a mail-back disposal option allows generators of waste to return it to the manufacturer. For instance, waste medicines and equipment can be returned. The waste is shipped through the U.S. postal service. While available in all 50 U.S. states, mail-back medical waste disposal is limited by very strict postal regulations (i.e., collection containers must comply with requirements set out by the Food and Drug Administration, while shipping containers must be approved by the postal service for use).[14]

India

The Bio-medical Waste (Management and Handling) Rules, 1998 and further amendments were passed for the regulation of bio-medical waste management. On 28 March 2016 Biomedical Waste Management Rules (BMW 2016)[15] were also notified by Central Govt. Each state's Pollution Control Board or Pollution control Committee will be responsible for implementing the new legislation. New regulations affect the distribution of medical waste by medical professionals into their proper receptacles.

In India, though there are a number of different disposal methods, the situation is desultory and most are harmful rather than helpful. If body fluids are present, the material needs to be incinerated or put into an autoclave. Although this is the proper method, most medical facilities fail to follow the regulations. It is often found that biomedical waste is dumped into the ocean, where it eventually washes up on shore, or in landfills due to improper sorting or negligence when in the medical facility. Improper disposal can lead to many diseases in animals as well as humans. For example, animals, such as cows in Pondicherry, India, are consuming the infected waste and eventually, these infections can be transported to humans who consume their meat or milk. Large number of unregistered clinics and institutions also generate bio-medical waste which is not controlled.

Due to the competition to improve quality and so as to get accreditation from agencies like ISO, NABH, JCI, many private organizations have initiated proper biomedical waste disposal but still the gap is huge.

Many studies took place in Gujarat, India regarding the knowledge of workers in facilities such as hospitals, nursing homes, or home health. It was found that 26% of doctors and 43% of paramedical staff were unaware of the risks related to biomedical wastes. After extensively looking at the different facilities, many were undeveloped in the area regarding biomedical waste. The rules and regulations in India work with The Bio-medical Waste (Management and Handling) Rules from 1998, yet a large number of health care facilities were found to be sorting the waste incorrectly.

Update around 26 March 2020. The National Green Tribunal (NGT) has been stringent on the application of the BMW 2016 over the past 12 months. There are now over 200 licensed Common Bio Medical Waste Treatment and Disposal Facilities (CBWTDF) or Common Treatment Facility (CTF) in the country. The rules have been updated over the years. The training of Health Care Facility staff and the awareness of the Hazards of Bio Medical waste is still a challenge in most of the country. The compliance is being enforced through penalties and via awareness. The CTF are operational in most Tier 1 cities and Tier 2 cities of India and compliance is high today because of NGT. But lack of awareness lead to issues of improper segregation. In Tier 2 and 3 cities the general waste is also mixed with biomedical waste.

The latest guidelines for segregation of bio-medical waste recommend the following color coding:[16]

  • Red Bag – Syringes (without needles), soiled gloves, catheters, IV tubes etc. should be all disposed of in a red colored bag, which will later be incinerated.
  • Yellow Bag – All dressings, bandages and cotton swabs with body fluids, blood bags, human anatomical waste, body parts are to be discarded in yellow bags.
  • Cardboard box with blue marking – Glass vials, ampules, other glass ware is to be discarded in a cardboard box with a blue marking/sticker.
  • White Puncture Proof Container (PPC) – Needles, sharps, blades are disposed of in a white translucent puncture proof container.
  • Black Bags – These are to be used for non-bio-medical waste. In a hospital setup, this includes stationary, vegetable and fruit peels, leftovers, packaging including that from medicines, disposable caps, disposable masks, disposable shoe-covers, disposable tea cups, cartons, sweeping dust, kitchen waste etc.

Environmental impacts

The syringe tide environmental disaster

The syringe tide environmental disaster of 1987–1988 raised awareness about medical waste as medical syringes washed ashore in Connecticut, New Jersey, and New York. The syringes endangered marine species and posed a threat to humans who visited the beach. The crises spurred scientists and lawmakers to create mechanisms, policies, and laws so that health care providers would process their bio-waste in an environmentally friendly way.[17]

Effects of medical waste on the environment

Accumulation of biomedical waste in a hospital basement.

Improper management of health care waste can have both direct and indirect health consequences for health personnel, community members and on the environment. Indirect consequences in the form of toxic emissions from inadequate burning of medical waste, or the production of millions of used syringes in a period of three to four weeks from an insufficiently well planned mass immunization campaign.

Biomedical waste is not limited to medical instruments; it includes medicine, waste stored in red biohazard bags, and materials used for patient care, such as cotton and bandaids. The most serious effect that biomedical waste has on our seas is the discharge of poisons into the waters that could then be consumed by ocean life creatures. Toxins would interject into the food chain and eventually reach humans who consume sea creatures. Human exposure to such toxins can stunt human growth development and cause birth defects.[18]

The high volume of plastic use in the medical field also poses a dangerous threat to the environment. According to North and Halden, 85% of disposable plastic materials make up all medical equipment.[19] Our current reliance on plastic materials is rooted in their unique capabilities to be lightweight, cost-effective, and durable while preserving the sterility of medical equipment. In addition to the serious health implications of releasing harmful toxins in the environment from medical waste deposits, introducing this volume of single-use plastics can catalyze the compounding health detriments caused by macro and microplastics.

Incineration of biomedical waste

See also: Incineration

Methods of biomedical waste incineration

The three type of medical waste incinerators are controlled air, excess air, and rotary kiln. Controlled air is also known as starved-air incineration, two-stage incineration, or modular combustion. This is the process of which waste is fed to a combustion chamber and combustion air begins to dry and facilitates volatilization of the waste. As a result, carbon dioxide and other excess gases are released into the atmosphere.

The second type of incineration is the excess air process. This is similar to the controlled air process, such as the waste being dried, ignited, and combusted by heat provided by the primary chamber burner. However, the main difference is that moisture and volatile components in the waste are vaporized.

In a rotary kiln, the process is similar to the two mention above, however, it is more versatile in terms of being able to mix wet and dry waste components and viewed by many waste engineers as being the most environmentally friendly.[20]

Impact on the environment

Post incineration process, toxic ash residue is produced and is often disposed at landfills. These landfills are not protected by any barrier and the residue has the potential of reaching underground water that is often exposed to human use. The combustion of plastic material releases toxic gases that escapes and joins breathable air. Human and animal exposure to such gases can cause long term breathing and health issues.[21] The rotation of toxic air does not only impact human well-being, but also of animals and plants. Air pollution caused by the incinerators depletes the ozone layer, causes crop and forest damage, and increases the effects of climate change.[22] Constant exposure to such toxins and chemicals in the air could be deemed detrimental to trees and plants and could eventually lead to extinction of certain plants in specific areas. Pollution and chemical leaks also affect the fruits of trees and would cause them to be poisonous and therefore inedible.[23]

Environmental waste in California

Medical waste management program

California created the Medical Waste Management Program, which regulates the generation, handling, storage, treatment, and disposal of medical waste by providing oversight for the implementation of the Medical Waste Management Act. Precautions have been taken in California which permits and inspects all medical waste offsite treatment facilities and medical waste transfer stations. In order to dispose waste, the department recommends the following process to make controlled substance waste non-retrievable. Pills containing a controlled substance are crushed before placing the residue into a pharmaceutical waste container. Controlled substance that is remaining in a syringe is wasted into a pharmaceutical waste container before disposing of the syringe in a sharps container. Expired medications should be returned through a reverse distributor.[24]

Environmentally friendly alternatives

Reusable RMW or sharps containers reduce the amount of plastic sent to landfills and CO
2
emissions.[25]

Non-incineration treatment includes four basic processes: thermal, chemical, irradiative, and biological. The main purpose of the treatment technology is to decontaminate waste by destroying pathogens. Modern technology invented mechanics that would allow medical professionals and hospitals to dispose medical waste in an environmentally friendly way; such as: autoclaving, plasma pyrolysis, gasification, chemical methods, and microwave irradiation. These alternatives are also highly versatile and can be used for all different types of waste.

An autoclave, similar to a pressure cooker, uses high-temperature steam to penetrate waste material and kill micro-organisms. Autoclave treatment has been recommended for microbiology and biotechnology waste, waste sharps, soiled and solid wastes. Microwave irradiation is based on the principle of generation of high frequency waves. These waves cause the particles within the waste material to vibrate, generating heat and killing the pathogens from within. A simple yet effective method is chemical disinfection: 1% hypochlorite can kill thriving bacteria. Plasma pyrolysis is an environment-friendly mechanism, which converts organic waste into commercially useful byproducts. The intense heat generated by the plasma enables it to dispose all types of waste including municipal solid waste, biomedical waste and hazardous waste in a safe and reliable manner.[citation needed] Gasification can offer carbon sequestration and energy generation, reducing the carbon footprint of biomedical waste treatment.[26]

Other possible solutions

Initiative from corporations and hospitals is essential to creating a healthier environment, however, there are various methods in which involves action from the general population and would contribute to a clean air environment. By creating surveillance groups within hospitals, everyone would be held accountable for misconduct and improper disposal of waste. Consequences could be implemented where individuals would be required to pay a fine, or face unpaid suspension from work. Companies and governmental organization should also initiate non-routine checkups and searches, this would place pressure on hospitals to ensure that waste is properly disposed all year round. Voluntary clean-ups would involve hospital staff in assuring that medical waste is not littered around the hospital or thrown into regular garbage bins.[27]

See also

References

  1. Singh, Z.; Bhalwar, R.; Jayaram, J.; Tilak, V. W. (April 2001). "An Introduction to Essentials of Bio-Medical Waste Management". Medical Journal, Armed Forces India 57 (2): 144–147. doi:10.1016/S0377-1237(01)80136-2. ISSN 0377-1237. PMID 27407320. 
  2. Lichtveld, M. Y.; Rodenbeck, S. E.; Lybarger, J. A. (1992). "The findings of the Agency for Toxic Substances and Disease Registry Medical Waste Tracking Act report". Environmental Health Perspectives 98: 243–250. doi:10.1289/ehp.9298243. PMID 1486856. 
  3. U.S. Congress, Office of Technology Assessment, Finding the Rx for Managing Medical Wastes, OTA-O-459 (Washington, DC: U.S. Government Printing Office, September 1990)
  4. Ezirim, Idoteyin; Agbo, Francis (2018). "Role of National Policy in Improving Health Care Waste Management in Nigeria". Journal of Health and Pollution 8 (19): 180913. doi:10.5696/2156-9614-8.19.180913. PMID 30524872. 
  5. "National Research Council Recommendations Concerning Chemical Hygiene in Laboratories". United States Department of Labor. http://www.osha.gov/pls/oshaweb/owadisp.show_document?p_table=standards&p_id=10107. 
  6. "Guidance on Closed Containers". Environmental Protection Agency. http://ehs.ucr.edu/waste/Closed%20Container%20Signed%20Document%201203091.pdf. 
  7. "Standard precautions in health care". WHO. https://www.who.int/csr/resources/publications/standardprecautions/en/. 
  8. "Medical Waste: Turn Your Problem Into Opportunity" (in en-US). 2019-06-19. https://terragon.net/pharos-blog/medical-waste/. 
  9. "Hazardous waste". https://www.gov.uk/healthcare-waste. 
  10. NetRegs - Current legislation lists
  11. "NHS waste firm to sue health trusts over terminated contracts". BBC. 7 November 2018. https://www.bbc.co.uk/news/uk-scotland-46121693. 
  12. "Fresh allegations of illegally stored clinical waste at 15 more sites". Press Association. 16 October 2018. https://www.aol.co.uk/news/2018/10/16/fresh-allegations-of-illegally-stored-clinical-waste-at-15-more/?guccounter=1. 
  13. "Officials admitted clinical waste incineration shortage". Health Service Journal. 12 October 2018. https://www.hsj.co.uk/quality-and-performance/exclusive-officials-admitted-clinical-waste-incineration-shortage/7023567.article. 
  14. MacArthur, Adam (2018-06-04). "Medical Waste Disposal – The Definitive Guide". https://www.medprodisposal.com/biohazard-waste-disposal-guide. Retrieved 27 October 2019. 
  15. "BMW Act and Process". https://earthron.com/bmw-act-and-process. 
  16. "::: Central Pollution Control Board ::: >> Programme/Projects > Waste > Bio-Medical Waste". http://cpcb.nic.in/Bio_medical.php. 
  17. "Bio Waste and Our Oceans". 2017-01-27. http://www.securewaste.com/2017/01/bio-waste-oceans/. 
  18. "Bio Waste and Our Oceans". 2017-01-27. http://www.securewaste.com/2017/01/bio-waste-oceans/. 
  19. North, Emily J.; Halden, Rolf U. (2013). "Plastics and environmental health: the road ahead". Reviews on Environmental Health 28 (1): 1–8. doi:10.1515/reveh-2012-0030. ISSN 2191-0308. PMID 23337043. 
  20. "Medical Waste Incineration". https://www3.epa.gov/ttnchie1/ap42/ch02/final/c02s03.pdf. 
  21. "Respiratory health outcomes and air pollution in the Eastern Mediterranean Region: a systematic review". Reviews on Environmental Health 31 (2): 259–280. 2016. doi:10.1515/reveh-2015-0076. PMID 27101544. 
  22. "Air quality, health impacts and burden of disease due to air pollution (PM10, PM2.5, NO2 and O3): Application of AirQ+ model to the Camp de Tarragona County (Catalonia, Spain)". Sci Total Environ 703: 135538. 10 February 2020. doi:10.1016/j.scitotenv.2019.135538. PMID 31759725. Bibcode2020ScTEn.703m5538R.  Epub 2019 Nov 18.
  23. "Negative Impacts of Incineration-based Waste-to-Energy Technology" (in en-CA). http://www.alternative-energy-news.info/negative-impacts-waste-to-energy/. 
  24. "Medical Waste Management Act". https://www.cdph.ca.gov/programs/ceh/drsem/cdph%20document%20library/emb/medicalwaste/medicalwastemanagementact.pdf. 
  25. "Sharpsmart: 90% Decrease in CO2 Emissions". 2017-08-17. https://www.danielshealth.com/knowledge-center/sharpsmart-90-decrease-co2-emissions. 
  26. "Medical & Bio-Hazard" (in en-US). https://terragon.net/markets/medical-bio-hazard/. 
  27. "Bio Waste and Our/everybody's Oceans". 2017-01-27. http://www.securewaste.com/2017/01/bio-waste-oceans/.