Biosafety Guidelines PDF
Document Details
Uploaded by UnboundBeige
2020
Marlon L. Bayot, Faten Limaiem
Tags
Summary
This document provides biosafety guidelines for various facilities handling microbiological agents. It details essential components, including risk assessment, specific measures, and staff training. The document also covers the history of biosafety, including relevant milestones and regulations.
Full Transcript
See discussions, stats, and author profiles for this publication at: https://www.researchgate.net/publication/338950394 Biosafety Guidelines Book · January 2020 CITATIONS READS 6...
See discussions, stats, and author profiles for this publication at: https://www.researchgate.net/publication/338950394 Biosafety Guidelines Book · January 2020 CITATIONS READS 6 2,964 2 authors: Marlon L. Bayot Faten Limaiem Coach MLB Consulting University of Tunis El Manar 14 PUBLICATIONS 102 CITATIONS 148 PUBLICATIONS 667 CITATIONS SEE PROFILE SEE PROFILE All content following this page was uploaded by Marlon L. Bayot on 31 January 2020. The user has requested enhancement of the downloaded file. 1/31/2020 Biosafety Guidelines - StatPearls - NCBI Bookshelf NCBI Bookshelf. A service of the National Library of Medicine, National Institutes of Health. StatPearls [Internet]. Treasure Island (FL): StatPearls Publishing; 2020 Jan-. Biosafety Guidelines Authors Marlon L. Bayot1; Faten Limaiem2. Affiliations 1 Adventist University of the Philippines - COM; Cavite State University - Dept. of Medical Technology 2 University of Tunis El Manar, Tunis Faculty of Medicine Last Update: January 31, 2019. Introduction Biosafety guidelines are a set of policies, rules, and procedures necessary to observe by personnel working in various facilities handling microbiological agents such as bacteria, viruses, parasites, fungi, prions, and other related agents and microbiological products. Institutions requiring strict adherence to these biosafety guidelines include clinical and microbiological laboratories, biomedical research facilities, teaching and training laboratories and other healthcare institutions (e.g., clinics, health centers, hospital facilities). These guidelines are intended to provide proper management and regulation of biosafety programs and practices implemented at all levels of the organization. Essential components of the biosafety guidelines contain some or all the following, depending on the facility: microbiological risk assessment and identification; specific biosafety measures, which cover the code of practice, physical plant such as laboratory design and facilities, equipment acquisition and maintenance, medical surveillance, staff training, safe handling of chemicals, with fire, radiation and electricity safety, among others. Additional components may be included such as commissioning and certification guidelines for the facilities. Biosafety guidelines must be made clear, practical and suitable for each facility and must be available for easy reference by all staff, must be reviewed, and updated regularly. While it provides guidance in the application of biosafety practices, this technical guide cannot solely ensure a safe working environment without the commitment of each person to adhere adequately to the biosafety guidelines at all times. Continuous research on biosafety can improve the development of future guidelines Etiology and Epidemiology History of Biosafety A significant milestone on biosafety initially referred to as “microbiological safety” dates back to 1908 where Winslow described a new method of examination to count bacteria present in the air A survey reviewed by Meyer and Eddie in 1941 described laboratory-acquired brucellosis which also revealed that similar infections could pose a threat to non-laboratorians.[ Later in 1947, the NIH Building 7 had the first peacetime research laboratory especially tailored for microbiological safety. These historical landmarks and breakthroughs are just a few of the more studies which untied the importance and relevance of biosafety in healthcare and research institutions. The principle and profession of biosafety have developed together with the history of the American Biological Safety Association (ABSA). As briefly described by the Federation of American Scientists, the first meeting was held in 1955 with the members of the military, as the focus addressed “The Role of Safety in the Biological Warfare Effort”. Succeeding meetings attendees included the US Centers for Disease Control and Prevention (CDC) and the National Institutes of Health (NIH), universities, laboratories, hospitals and representatives from the industries. From then, written regulations covered the shipment of biological agents, safety training and programs, with the development of biological safety level classification International issues on biosafety and studies on the individual or group of agents became the focus in the 1980s. At present, aside from studies focusing on specific biohazard level or pathogen, https://www.ncbi.nlm.nih.gov/books/NBK537210/?report=printable 1/7 1/31/2020 Biosafety Guidelines - StatPearls - NCBI Bookshelf new strategies were developed to enhance risk assessment capacities, biosecurity, and biocontainment measures including the regulation of biosafety through national and international policies. Other industries such as in agriculture and biotechnology are now considering biosafety application. Epidemiology of Laboratory-Acquired Infections (LAIs) Laboratory-acquired infections (LAIs) were considered significant because of the high risk in the laboratory workforce relative to the public, although the exposure to infectious agents can be higher in other groups of healthcare workers. Sulkin and Pike in 1949 studied several works of literature and mail surveys with an attempt to evaluate the risk of infection associated with employment in a clinical or research laboratory. Follow-up studies and reviews led to the identification and description of hazards unique to these laboratories, which later formed a basis for the development of approaches to prevent the emergence of LAIs.[ The incidence of laboratory-acquired infections varies among institutions conducting surveys to a specific or group of laboratories and facilities. Monitoring and evaluation of LAIs are still absent for many institutions which could be caused by the difficulties in the reporting schemes and lack of accurate data interpretation. For instance, reporting of LAI is not similar to the reporting of notifiable diseases which is highly regulated for each healthcare institution across countries as implemented by their ministries of health. Laboratory-acquired infections may not always manifest as a disease entity. An example would be a person infected with tuberculosis, who could have an infection with TB bacilli but with no signs and symptoms, thus, cannot be considered as TB disease. No national and global recording and reporting of LAI is in place. Though LAI incidence is reported in several publications recently, the variables and the levels of measurement under study differ, hence, combination and comparison of such studies is not a simple task. However, the need for data collection for current LAIs should highlight the importance of improving biosafety which outweighs the above issues. LAI databases were then created to contain all recently published studies and to verify its relevant findings. While these address the need for acquiring new information, it will not replace the reporting schemes implemented by individual institutions. In 2018, Siengsanan-Lamont and Blacksell presented the results of a rapid review about LAI studies within the Asia- Pacific. Studies from 1982 to 2016 included several agents, some of these include: Shigella flexneri (Australia), Mycobacterium tuberculosis (Japan), Rickettsia typhi (South Korea), SARS-CoV (Singapore, China, Taiwan), Dengue (South Korea, Australia) and Ralstonia picketti (Taiwan) to name a few. Regarding potential risks for zoonotic diseases, viruses predominate, followed by bacteria and parasites. The importance of risk assessment and management was also emphasized, including preventive practices. Strict biosafety measures is a must for these working environments to protect themselves and the community Specimen Requirements and Procedure All specimens collected from patients require the application of biosafety measures. It starts with the instructions provided by the healthcare worker to the patient. Clear statements with explanations and step-by-step procedures are necessary, especially for patients who will collect the specimen. Healthcare workers, including laboratory staff, should be well-oriented especially when they are to collect specimens directly from patients. Personal protective equipment (PPE) must be worn at all times during the specimen collection. Universal precautions must be applied accordingly. Several procedures exist for collecting sterile and non-sterile sample specimens. Better strategies were developed recently to minimize hazards either during and after sending the specimens into the laboratory. For example, the use of the evacuated tube system (ETS) prevented the contact of the patient’s blood from the site of extraction to the phlebotomist and the external environment during venipuncture. This is much safer than the previous practice of manual transferring blood samples from the syringe to the tube. Sputum collected in a clear and transparent container will aid in efficient visualization and assessment of sputum quality which is safer than reopening the cap. These are examples where applying biosafety measures become crucial in the pre-analytical phase. https://www.ncbi.nlm.nih.gov/books/NBK537210/?report=printable 2/7 1/31/2020 Biosafety Guidelines - StatPearls - NCBI Bookshelf Diagnostic Tests Clinical laboratory scientists (medical technologists) must perform laboratory procedures both accurately and safely. PPE must be worn out while inside the premises of the laboratory and throughout the diagnostic procedure. There is a proper sequence of donning (putting on) and doffing (removing) PPE as recommended by the US Centers for Disease Prevention and Control (CDC). Generally, donning starts with gowning, wearing of a mask (or respirator), goggles (or face shield) and gloving. Doffing may be done by removing the gloves, goggles, gown, and mask followed by the proper hand washing. Pathogen-specific and risk-specific biosafety measures are shown to be more practical and cost effective. For example, low and medium-risk procedures do not need a containment facility and infrastructure which are designed only for high-risk procedures. Safe handling and processing of specimens can be conducted in biological safety cabinets (BSCs) to prevent inhalation of generated aerosols when performing a microbiological procedure. The purpose of using BSCs must be well differentiated from using fume hoods, in which the latter is only necessary for handling chemicals and not for infectious microorganisms. When dealing with specimens, keep hands away from the face and should remain inside the cabinet. Unnecessary movements inside the BSC is prohibited to prevent the changes in the flow of air. For instance, the crossing of arms during the laboratory procedure is inadvisable. Also, ensure to disinfect the BSC before use. In procedures done in the absence of a BSC, a well-ventilated area must be secured and maintained before considering it as a bench work area. When gloves become heavily contaminated, wear new gloves. Do not reuse gloves in other procedures nor soiled masks or respirators. Molecular biology laboratories perform procedures which require the use of different rooms for sample preparation, DNA extraction, amplification and sequencing, thus, the need for additional biosafety measures. Proper disposal of wastes is necessary to prevent disease transmission. Waste segregation must be appropriately employed (e.g., infectious and non-infectious waste). Waste disposal via burning may not be practical nowadays. Hence, alternative disposal mechanisms must be finalized and institutionalized in each healthcare institution. Environmental impact is always a consideration when making decisions for waste disposal. Treatment facilities (i.e., treatment plants) are used to remove contaminants before sewage gets released into the environment. Specific steps should be written on standard operating procedure manuals and work instructions intended for laboratory staff involved. Recording and reporting procedures must be free from possible contamination and should of in a clean and dedicated space. Similarly, wearing gloves when encoding via computer or when using the phone is forbidden. Because of the complexity of the laboratory work, one must be well-trained and supervised to perform biosafety measures at work, while non-authorized personnel must have restricted access to the laboratory, especially when a diagnostic test is in process. Testing Procedures The development of biosafety guidelines is part of the overall quality management systems implementation. For newly established facilities, ensure biosafety before the start of operations. Workflow inside the laboratory must facilitate an efficient means for carrying out processes by the laboratorian. Activities involving dirty areas (e.g., a specimen receipt, sample preparation, etc.) should be kept separate from the clean areas (e.g., microscopy, use of automated instrumentation, recording of results, etc.). Procedures for laboratory workflow can be tested through observation and evaluation by a designated biosafety officer, laboratory supervisor or an independent consultant who can conduct monitoring activities and provide technical assistance. For labs using BSCs, a smoke pattern test using in-house or commercial testers may be regularly performed to assess for good airflow before use. Anemometers may be used to check for air velocity. BSC certification provided by a service professional must be secured before use and continually re-certified once a year. Before performing any laboratory test, the provision of required training on biosafety to the laboratory workforce is vital, either as a focused training program or as part of the training curriculum for certain laboratory procedure. https://www.ncbi.nlm.nih.gov/books/NBK537210/?report=printable 3/7 1/31/2020 Biosafety Guidelines - StatPearls - NCBI Bookshelf Laboratory managers, section heads and supervisors should receive biosafety training as well, including topics on risk management and biosafety program implementation. Effective supportive supervision of laboratory staff working in any facility is a key factor for sustained implementation of quality laboratory services.The integration of the monitoring of biosafety practices with monitoring of laboratory processes should proceed based on set criteria or standards. Certain indicators which indirectly assess the overall biosafety may include the presence of an updated procedure manual and work instructions, a list of trained staff with regular competency or proficiency tests, with regular quality control and maintenance of laboratory equipment. Regular medical consultation for staff can early detect the risk of infection. Moreover, the presence of laboratory signage such as a biohazard symbol to recommended sites of the facility, with a well-organized mechanism for disposal of wastes can significantly minimize the risk of accidents and incidents both inside and outside the laboratory. Laboratory accreditation and certification may also aid in ensuring that biosafety measures get implemented in accordance with the written guidelines. Interfering Factors Several factors impede the application of laboratory-acquired biosafety measures within the facility. These may include, but not limited to: The absence of a technical document containing specific biosafety guidelines Poor biosafety skills (for example, on spills management) because of lack of training The continuous presence of laboratory hazards and increased risk due to the lack or inadequate of risk assessment and management Use of substandard laboratory supplies Poor equipment maintenance Biosafety guidelines are more likely to be poorly implemented in facilities because of: Poorly written guidelines, including the adoption of generic, nonspecific procedures Unclear roles and responsibilities for each staff involved Lack of review and updating process of existing guide Poor dissemination and access to such guidelines Results, Reporting, Critical Findings Results of testing procedures done for biosafety checks must be recorded, consolidated and interpreted regularly (i.e., daily, weekly, monthly, quarterly, or as applicable). The results may show a trend which may signal a need either for equipment maintenance, or replacement. Frequent incidents associated with a particular process may demonstrate a need to have a review and modification of the procedure. Involved staff should willingly report accidents inside the laboratory. Laboratorian should not be afraid to report such events as these may become a future source of infection. Baseline data and critical findings encountered relative to implementing biosafety guidelines can improve existing practices and limit risks from all personnel. Clinical Significance Ensuring quality and biologically safe work environment fosters good and effective delivery of laboratory and clinical services for patients. While performing complex laboratory procedures, staff can work with a certain level of confidence they won’t contract an infection or disease. The spread of infectious agents from facilities to other healthcare worker, patients and from the community is preventable with the application of biosafety practices. Quality control and Lab Safety https://www.ncbi.nlm.nih.gov/books/NBK537210/?report=printable 4/7 1/31/2020 Biosafety Guidelines - StatPearls - NCBI Bookshelf Biosafety monitoring can be part of quality control measures and quality assurance program in the laboratory or any healthcare institution. It must be an important component of competency tests for staff and must be an essential element of organizational plans and goals. Enhancing Healthcare Team Outcomes Biosafety, as implemented in laboratories and related facilities, supports the aims and principles of infection control, as implemented in hospitals and clinics. Likewise, adherence to biosafety guidelines takes a collaborative approach from all professionals including non-laboratory healthcare personnel. Respirator fit testing, for example, can be carried out at regular intervals (i.e., once a year), in partnership with the infection control committee (ICC) or an infection control nurse of a hospital facility. Production laboratories may seek the advice of laboratory staff in the application of biosafety measures when handling certain infectious agents or products. Clinicians may work with laboratory professionals, nurses, pharmacists, sanitary officers, among others, in coming up with organizational strategies as part of the healthcare-associated infection program in hospitals and medical facilities.From its current scope, biosafety has expanded to research facilities such as in animal research. International conferences from various institutions still exist which concentrate on sharing of best practices and harmonization of biosafety guidelines at the regional, national and global scale. Biosafety has been an emerging concern for occupational health. Educational intervention on biosafety is highly essential so that staff can be fully equipped with the correct knowledge of biosafety principles and can be able to demonstrate or enhance proper biosafety skills for all healthcare workers. Therefore, the best practices for healthcare, research, and other institutions would always require a team commitment and cooperation to achieve a “safe and secure” workplace and community. Questions To access free multiple choice questions on this topic, click here. References 1. Kimman TG, Smit E, Klein MR. Evidence-based biosafety: a review of the principles and effectiveness of microbiological containment measures. Clin. Microbiol. Rev. 2008 Jul;21(3):403-25. [PMC free article: PMC2493080] [PubMed: 18625678] 2. Winslow CE. A NEW METHOD OF ENUMERATING BACTERIA IN AIR. Science. 1908 Jul 03;28(705):28- 31. [PubMed: 17834254] 3. Yagupsky P, Baron EJ. Laboratory exposures to brucellae and implications for bioterrorism. Emerging Infect. Dis. 2005 Aug;11(8):1180-5. [PMC free article: PMC3320509] [PubMed: 16102304] 4. Bayot ML, King KC. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Jan 11, 2019. Biohazard Levels. [PubMed: 30570972] 5. SULKIN SE. Laboratory-acquired infections. Bacteriol Rev. 1961 Sep;25:203-9. [PMC free article: PMC441093] [PubMed: 13918299] 6. Sewell DL. Laboratory-associated infections and biosafety. Clin. Microbiol. Rev. 1995 Jul;8(3):389-405. [PMC free article: PMC174631] [PubMed: 7553572] 7. Siengsanan-Lamont J, Blacksell SD. A Review of Laboratory-Acquired Infections in the Asia-Pacific: Understanding Risk and the Need for Improved Biosafety for Veterinary and Zoonotic Diseases. Trop Med Infect Dis. 2018 Mar 26;3(2) [PMC free article: PMC6073996] [PubMed: 30274433] 8. Cornwell-Smith N. Personal protective equipment for employees. BMJ. 1992 Aug 22;305(6851):474-5. [PMC free article: PMC1882546] [PubMed: 1392972] 9. Hersi M, Stevens A, Quach P, Hamel C, Thavorn K, Garritty C, Skidmore B, Vallenas C, Norris SL, Egger M, Eremin S, Ferri M, Shindo N, Moher D. Effectiveness of Personal Protective Equipment for Healthcare Workers Caring for Patients with Filovirus Disease: A Rapid Review. PLoS ONE. 2015;10(10):e0140290. [PMC free article: PMC4599797] [PubMed: 26451847] 10. Broussard IM, Kahwaji CI. StatPearls [Internet]. StatPearls Publishing; Treasure Island (FL): Mar 16, 2019. https://www.ncbi.nlm.nih.gov/books/NBK537210/?report=printable 5/7 1/31/2020 Biosafety Guidelines - StatPearls - NCBI Bookshelf Universal Precautions. [PubMed: 29262198] 11. Ialongo C, Bernardini S. Phlebotomy, a bridge between laboratory and patient. Biochem Med (Zagreb). 2016;26(1):17-33. [PMC free article: PMC4783087] [PubMed: 26981016] 12. Fujii C, Ishii H, Takanishi A. Safe venepuncture techniques using a vacuum tube system. Int J Nurs Pract. 2013 Sep;19 Suppl 3:11-9. [PubMed: 24090293] 13. Karinja MN, Esterhuizen TM, Friedrich SO, Diacon AH. Sputum volume predicts sputum mycobacterial load during the first 2 weeks of antituberculosis treatment. J. Clin. Microbiol. 2015 Apr;53(4):1087-91. [PMC free article: PMC4365216] [PubMed: 25552362] 14. Simundic AM, Lippi G. Preanalytical phase--a continuous challenge for laboratory professionals. Biochem Med (Zagreb). 2012;22(2):145-9. [PMC free article: PMC4062337] [PubMed: 22838180] 15. Sewunet T, Kebede W, Wondafrash B, Workalemau B, Abebe G. Survey of safety practices among hospital laboratories in Oromia Regional State, Ethiopia. Ethiop J Health Sci. 2014 Oct;24(4):307-10. [PMC free article: PMC4248029] [PubMed: 25489194] 16. Kruse RH, Puckett WH, Richardson JH. Biological safety cabinetry. Clin. Microbiol. Rev. 1991 Apr;4(2):207- 41. [PMC free article: PMC358192] [PubMed: 2070345] 17. Beilby J. Diagnostic molecular biology. Clin Biochem Rev. 2006 Feb;27(1):3-4. [PMC free article: PMC1390793] [PubMed: 16886042] 18. Askarian M, Motazedian N, Palenik CJ. Clinical laboratory waste management in Shiraz, Iran. Waste Manag Res. 2012 Jun;30(6):631-4. [PubMed: 21987412] 19. Singh Z, Bhalwar R, Jayaram J, Tilak VW. AN INTRODUCTION TO ESSENTIALS OF BIO-MEDICAL WASTE MANAGEMENT. Med J Armed Forces India. 2001 Apr;57(2):144-7. [PMC free article: PMC4925840] [PubMed: 27407320] 20. Armbruster DA. Hazardous waste disposal and the clinical laboratory. Clin Lab Manage Rev. 1990 May- Jun;4(3):160-6. [PubMed: 10104718] 21. Ezzelle J, Rodriguez-Chavez IR, Darden JM, Stirewalt M, Kunwar N, Hitchcock R, Walter T, D'Souza MP. Guidelines on good clinical laboratory practice: bridging operations between research and clinical research laboratories. J Pharm Biomed Anal. 2008 Jan 07;46(1):18-29. [PMC free article: PMC2213906] [PubMed: 18037599] 22. Newsom SW. A test system for the biological safety cabinet. J. Clin. Pathol. 1974 Jul;27(7):585-9. [PMC free article: PMC475402] [PubMed: 4214380] 23. Whistler T, Kaewpan A, Blacksell SD. A Biological Safety Cabinet Certification Program: Experiences in Southeast Asia. Appl Biosaf. 2016 Sep;21(3):121-127. [PMC free article: PMC5053331] [PubMed: 27721674] 24. Heiby J. Quality assurance and supervision systems. QA Brief. 1998 Jun;7(1):1-3. [PubMed: 12294098] 25. Rim KT, Lim CH. Biologically hazardous agents at work and efforts to protect workers' health: a review of recent reports. Saf Health Work. 2014 Jun;5(2):43-52. [PMC free article: PMC4147232] [PubMed: 25180133] 26. Baldwin CL, Runkle RS. Biohazards symbol: development of a biological hazards warning signal. Science. 1967 Oct 13;158(3798):264-5. [PubMed: 6053882] 27. Karim N, Choe CK. Laboratory accidents--a matter of attitude. Malays J Pathol. 2000 Dec;22(2):85-9. [PubMed: 16329540] 28. Bennett A, Parks S. Microbial aerosol generation during laboratory accidents and subsequent risk assessment. J. Appl. Microbiol. 2006 Apr;100(4):658-63. [PubMed: 16553720] 29. Mehta Y, Gupta A, Todi S, Myatra S, Samaddar DP, Patil V, Bhattacharya PK, Ramasubban S. Guidelines for prevention of hospital acquired infections. Indian J Crit Care Med. 2014 Mar;18(3):149-63. [PMC free article: PMC3963198] [PubMed: 24701065] 30. Murphy DC. Designing a respirator fit testing program. AAOHN J. 1992 Nov;40(11):545-8. [PubMed: 1489480] 31. Or P, Chung J, Wong T. A novel approach to fit testing the N95 respirator in real time in a clinical setting. Int J Nurs Pract. 2016 Feb;22(1):22-30. [PubMed: 24828795] 32. Collins DE, Reuter JD, Rush HG, Villano JS. Viral Vector Biosafety in Laboratory Animal Research. Comp. Med. 2017 Jun 01;67(3):215-221. [PMC free article: PMC5482513] [PubMed: 28662750] 33. Thelaus J, Lindberg A, Thisted Lambertz S, Byström M, Forsman M, Lindmark H, Knutsson R, Båverud V, https://www.ncbi.nlm.nih.gov/books/NBK537210/?report=printable 6/7 View publication stats 1/31/2020 Biosafety Guidelines - StatPearls - NCBI Bookshelf Bråve A, Jureen P, Lundin Zumpe A, Melefors Ö. Network Experiences from a Cross-Sector Biosafety Level-3 Laboratory Collaboration: A Swedish Forum for Biopreparedness Diagnostics. Health Secur. 2017 Jul/Aug;15(4):384-391. [PMC free article: PMC5576262] [PubMed: 28805472] 34. Bakanidze L, Imnadze P, Perkins D. Biosafety and biosecurity as essential pillars of international health security and cross-cutting elements of biological nonproliferation. BMC Public Health. 2010 Dec 03;10 Suppl 1:S12. [PMC free article: PMC3005572] [PubMed: 21143822] 35. Dyson MC, Carpenter CB, Colby LA. Institutional Oversight of Occupational Health and Safety for Research Programs Involving Biohazards. Comp. Med. 2017 Jun 01;67(3):192-202. [PMC free article: PMC5482511] [PubMed: 28662748] 36. Ritterson R, Casagrande R. Basic Scholarship in Biosafety Is Critically Needed To Reduce Risk of Laboratory Accidents. mSphere. 2017 Mar-Apr;2(2) [PMC free article: PMC5371692] [PubMed: 28405626] 37. Jonsson CB, Cole KS, Roy CJ, Perlin DS, Byrne G., members of the RBL-NBL Directors Network. Challenges and Practices in Building and Implementing Biosafety and Biosecurity Programs to Enable Basic and Translational Research with Select Agents. J Bioterror Biodef. 2013 Apr 29;Suppl 3(15):12634. [PMC free article: PMC4041738] [PubMed: 24900945] 38. Emery RJ, Rios J, Patlovich SJ. Thinking Outside the Box: Biosafety's Role in Protecting Non-Laboratory Workers from Exposure to Infectious Disease. Appl Biosaf. 2015 Sep 01;20(3):128-129. [PMC free article: PMC5621754] [PubMed: 28966562] Copyright © 2020, StatPearls Publishing LLC. This book is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits use, duplication, adaptation, distribution, and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, a link is provided to the Creative Commons license, and any changes made are indicated. Bookshelf ID: NBK537210 PMID: 30725895 https://www.ncbi.nlm.nih.gov/books/NBK537210/?report=printable 7/7