Benjamin Fontes, MPH, CBSP ABSA Conference, Charleston, SC October 16, 2018
OVERVIEW •REVIEW PATHOGEN ENTRY AND POSSIBLE DESTINATIONS IN HOST
•GIVE EXAMPLES OF KNOWN, PROBABLE AND POSSIBLE LAI EXPOSURE ROUTES
•PROVIDE INFORMATION FOR EXPANDED RISK AWARENESS DISCUSSION WITH THOSE EXPOSED TO BIOHAZARDS
•INSPIRED BY ABSA MEMBERS
1 LAB ACQUIRED INFECTIONS 1930 -2015 •1930 – 2015 •7,325 LAIS (SYMPTOMATIC AND ASYMPTOMATIC) •210 FATAL LAI’S • BYERS KB AND HARDING, AL. LABORATORY-ASSOCIATED INFECTIONS. 2017. IN: WOOLEY, DP, AND BYERS, KB, EDITORS, BIOLOGICAL SAFETY: PRINCIPLES AND PRACTICES, 5TH ED., WASHINGTON, DC: ASM PRESS. P. 59 – 94. • PIKE RM. 1979. LABORATORY-ASSOCIATED INFECTIONS: INCIDENCE, FATALITIES, CAUSES, AND PREVENTION. ANNU REV MICROBIOL: 33: 41 -66. • SULKIN SE, PIKE RM. SURVEY OF LABORATORY-ACQUIRED INFECTIONS. AM J PUB HLTH. 1951; 41: 769-81.
WHAT IS KNOWN ABOUT EXPOSURE ROUTES?
Facial Mucous Percutaneous Ingestion Membranes
IhltiInhalation *Con tact
*Contact involves self-inoculation through one of the known exposure routes
2 REVIEW OF LABORATORY INFECTIONS: IMPORTANT MESSAGES
•80% OF THE PUBLISHED LABORATORY ACQUIRED INFECTIONS LINKED TO AN UNKNOWN ROUTE OF EXPOSURE. •AEROSOLS MOST LIKELY ASSOCIATED WITH UNKNOWN INFECTIONS •DR. EDWARD SULKIN & DR. ROBERT PIKE
GOLDEN AGE OF BIOSAFETY (1949 – 1979)
THERE CAN BE UNNATURAL ROUTES OF EXPOSURE IN THE LABORATORY SETTING THAT ARE GENERALLY NOT SEEN IN NATURE. (SULKIN 1960)
3 Infections with unidentified route of exposure
7 Non-traditional exposure route
NON-TRADITIONAL EXPOSURE ROUTES GI Pathogens: Salmonella, Listeria, Shigella, Campylobacter, E. coli, etc.
Eye Nasal Throat Gut Cavity
Thomas, R.J., “Particle Size and Pathogenicity in the Respiratory Tract.” Virulence 4:8, 847-858; November 15, 2013.
4 NON-TRADITIONAL EXPOSURE ROUTES GI Pathogens: Salmonella, Listeria, Shigella, Campylobacter, E. coli, etc. Aerosol Nasal Throat muco- GtGut ciliary escalator
Tracheo- Aerosol bronchial Throat GtGut mucociliary escalator
NON-TRADITIONAL EXPOSURE ROUTES West Nile Virus, Yellow Fever Virus, Rabies Virus, Influenza Virus, Neisseria meningitidis, Streptococcus pneumoniae Aerosol Nasal Cranial Brain Cavity Nerves
5 NON-TRADITIONAL EXPOSURE ROUTES West Nile Virus, Yellow Fever Virus, Rabies Virus, Neisseria meningitidis, Sabia Virus, EEE, WEE, VEE AlAerosol Lower Bloo d Lung stream
Thomas, R.J., “Particle Size and Pathogenicity in the Respiratory Tract.” Virulence 4:8, 847-858; November 15, 2013. Winkler, W.G. 1973. Airborne rabies transmission in a laboratory worker. JAMA 226 (10):1219-1221. Centers for Disease Control. 1977. Rabies in a laboratory worker, New York. MMWR 26(22): 183-184
RECOGNIZED VS. UNRECOGNIZED EXPOSURES: PEOPLE REPORT WHAT THEY CAN “FEEL”
Feel splashes/splatter Feel needle sticks, lacerations, to face or skin punctures, cuts, etc.
6 WHAT YOU CAN’T FEEL IS (PROBABLY) NOT REPORTED?
Ingestion Inhalation May also not feel exposure through micro-abrasions
GOLDEN AGE OF BIOSAFETY (1949 – 1979) THE LABORATORY CAN BE MORE DANGEROUS THAN NATURE DUE TO THE ABILITY TO AMPLIFY AND CONCENTRATE PATHOGENS TO LEVELS NOT SEEN IN NATURE. ALSO, THE GROWTH AND PROPAGATION OF INFECTIOUS AGENTS IN LABORATORY SETTINGS ARE CONDUCTED REPEATEDLY WITHIN THE LABORATORY AS PART OF THE RESEARCH EFFORT , ENHANCING THE POTENTIAL EXPOSURE. (LANGMUIR 1960)
7 UNKNOWN BIOHAZARDS WHY A CONSISTENT APPLICATION OF GOOD MICROBIOLOGICAL PRACTICES IS CRITICAL • NEW PATHOGENS (MIMIVIRUS) • OUTBREAK PATHOGEN STRAINS (E.COLI 0157:H7) • FIRST “REPORT” OF INFECTION IN HUMANS WITH EXISTING PATHOGEN (KEYSTONE VIRUS 2018 FLORIDA) • MORBIDITY NEWLY RECOGNIZED IN AN EXISTING MICROORGANISM (MERKEL POLYOMA VIRUS) • INTRODUCTION OF BIOHAZARDS TO LOW RISK LABS (TRANSFERRIN, MYCOPLASMA, VIRUS IN TISSUES) • VETERINARY RISKS (VET SCHOOL, CLINICS, FIELD SETTINGS – CRYPTOSPORIDIUM INFECTIONS) • NON-PATHOGENIC MICROBES ASSISTING WITH PATHOGENICITY OR SPREAD OF DISEASE (FUSOBACTERIUM NUCLEATUM) • WHEN GOOD GENES GET INTO BAD PLACES (DR. GARY FUJIMOTO)
REFERENCES
• Raoult, D. et al. The Discovery and Characterization of Mimivirus, the Largest Known Virus and Putative Pneumonia Agent. Emerging Infections. 2007;45 (1 July): 95-102. • Lednicky, J.A. et al. Keystone Virus Isolated From a Florida Teenager With Rash and Subjective Fever: Another Endemic Arbovirus in the Southeastern United States. Clinical Infectious Diseases, Brief Report. 2018; published online June 9, 2018: 1-3. • Spurgeon, M.E., Lambert P.F. Merkel Cell Polyomavirus: A Newly Discovered Human Virus with Oncogenic Potential. Virology. 2013; January 5;435(1): 118-130. • Spina, N. et al. Four Laboratory-Associated Cases of Infection with Escherichia coli O157:H7. Journal of Clinical Microbiology. 2005;43(6): 2938-2939. • Philpott, M.S. et al. A Laboratory-associated Outbreak of Cryptosporiosis. Applied Biosafety. 2015; 20(3): 130-136. • Kinross, P. et al. Cryptosporidium parvum infections in a cohort of veterinary students in Sweden. Epidemiology and Infection. 2015;143: 2748-2756. • Fardini, Y. Fusobacterium nucleatum adhesion FadA binds vascular endothelial cadherin and alters endothelial integrity. Molecular Microbiology. 2011; 82(6): 1468-1480.
8 GOLDEN AGE OF BIOSAFETY (1949 – 1979) THE MAJORITY OF LABORATORY PROCEDURES HAVE THE POTENTIAL TO GENERATE AEROSOLS IN THE SIZE RANGE THAT CAN REMAIN SUSPENDED IN AIR AND ALSO REACH THE LOWER LUNG, WHERE THEY CAN EITHER BE INHALED AND CAUSE INFECTION OR ENTER THE BLOODSTREAM VIA THE ALVEOLI AND CAUSE INFECTION IN ANOTHER LOCATION OF THE BODY. (REITMAN AND WEDUM 1956 AND KENNEY AND SABEL 1968)
ROUTE OF EXPOSURE TREES ON FACIAL MUCOUS ON Lung (Epithelial I MEMBRANES cells, other) CRANIAL NERVES Blood (alveoli, FROM NOSE TO lymphatic system) LAT BRAIN ALATI A A Mucociliary Contact (from Escalators - Gut contaminated surfaces) INH INH
9 GOLDEN AGE OF BIOSAFETY (1949 – 1979)
FROM DR. ARNOLD G. WEDUM, CONSIDERED THE “FATHER OF BIOLOGICAL SAFETY” IN THE U.S., WE LEARN THE IMPORTANCE OF “CONFINING AEROSOLS AS CLOSE AS POSSIBLE TO THEIR POINT OF GENERATION.” (WEDUM 1960)
NASAL CAVITY TO BRAIN VIA CRANIAL NERVES
INFLUENZA A VIRUS, HERPES VIRUSES, POLIOVIRUS, PARAMYXOVIRUSES, VESICULAR STOMATITIS VIRUS,,, RABIES VIRUS, PARAINFLUENZA VIRUS, ADENOVIRUSES, JAPANESE ENCEPHALITIS VIRUS, WEST NILE VIRUS, CHIKUNGUNYA VIRUS, LACROSSE VIRUS, BUNYAVIRUSES, STREPTOCOCCUS PNEUMONIAE, NEISSERIA MENINGITIDIS, BURKHOLDERIA PSEUDOMALLEI, LISTERIA MONOCYTOGENES, LYMPHOCYTIC CHORIOMENINGITIS VIRUS, NAEGLERIA FOWLERI, EEE, VEE, WEE
• DANDO, SJS.J. ET AL , “PATHOGENS PENETRATING THE CENTRAL NERVOUS SYSTEM: INFECTION PATHWAYS AND CELLULAR AND MOLECULAR MECHANISMS OF INVASION.” 2014. CLINICAL MICROBIOLOGICAL REVIEWS, VOL. 27 NO. 4, 691-726, OCTOBER 2014 • BELOOR, J. ET AL, “SMALL INTERFERING RNA-MEDIATED CONTROL OF VIRUS REPLICATION IN CNS IS THERAPEUTIC AND ENABLES NATURAL IMMUNITY TO WEST NILE VIRUS,” 2018. CELL HOST & MICROBE, 23, 549- 556, APRIL 11, 2018. • VAN RIEL, ET AL, “THE OLFACTORY NERVE: A SHORTCUT FOR INFLUENZA AND OTHER VIRAL DISEASES INTO THE CENTRAL NERVOUS SYSTEM, JOURNAL OF PATHOLOGY; 235, 277-287, 2015.
10 INGESTION •DR. THOMAS HAMM (PLEA TO NHP STAFF NOT WEARING GOGGLES: “S_IT EATERS” •NASAL LACRIMAL DUCT •MUCOCILIARY ESCALATORS •NASOPHARYNGEAL •TRACHEAL BRONCHIAL
•3 WAYS YOU CAN INGEST A PATHOGEN
ROUTE OF EXPOSURE TREES N VIA EATING, DRINKING OR O CONTACT
VIA NASAL LACRIMAL DUCT ESTI G G VIA MUCOCILLIARY ESCALATOR IN
11 INGESTION LIKELY UNRECOGNIZED •NOT COGNIZANT OF HAND TO FACE CONTACT •POOR WORK PRACTICES IN SHALLOW WATER (JIM WELCH) •LACK OF RECOGNITION OF POSSIBLE ROLE OF AEROSOLS FROM CONTAMINATION TO HOST ENTRY •CAN’T “FEEL” THE EXPOSURE •COMPETING RISKS OUTSIDE OF LAB • CDC: 48 MILLION FOODBORNE ILLNESSES ANNUALLY • MANY SELF MEDICATE AND DON’T REPORT • OVER 250 FOODBORNE PATHOGENS
ROUTE OF EXPOSURE TREES s
s Blood, Lymph u
CRANIAL NERVES - FROM NOSE TO BRAIN ial Muco embrane c c GUT (from eye, nose or M M
Fa mouth)
12 HAND TO FACE CONTACT (HFC) ARTICLE • 72% of researchers touched face at least once • High likelihood of finger, hand and wri st • Average of 2.6 HFCs/hr contamination
• HFC found “common” • Only 3 of 93 among BSL-2 lab workers researchers wore eye or face protection in • Possibly an overlooked the BSL-2lab2 lab route of exposure for unknown LAIs Johnston, J.D., et al, “The Influence of Risk Perception on Biosafety Level-2 Laboratory Workers’ Hand-To-Face Contact Behaviors,” Journal of Occupational and Environmental Hygiene, Vol. 11, pp 625-632, September 2014
ROUTE OF EXPOSURE TREES us SKIN o o (Local infections)
BLOOD STREAM
utane FACIALCCOS MUCOUS MEMBRANES Perc
13 PERCUTANEOUS EXPOSURES
Needle sticks, lacerations, punctures, bites
Unhealed wounds
Breaks in skin, cuticles, posion ivy, eczema, dermatitis
Acne, other micro-abrasions
GLOVE - LEAK RATE - FACTS Glove Leak Exam Surgical Rates Gloves Gloves
Before Use 2.5% 1.5% (FDA) After Use *21 – 35% **15.2%
**Double gloving: leak rates for inner gloves when double gloved - 1.17% (98.83% Eff ecti ve!)
*Boyle, B & Boyle, T, “Loss of Glove Integrity During Laboratory Animal Care Providers Daily Tasks,” Lenape Regional High School, Medford NJ, Science Fair Poster Presentation, 2017
**Makama, J.G. et al, “Glove Perforation Rate in Surgery: A Randomized, Controlled Study to Evaluate the Efficacy of Double Gloving,” Surgical Infections, Vol. 17 No. 4, pp 436-442, March 16, 2016
14 BIOSAFETY FOUNDATION GAME
Don’t eat, Confine Eliminate No mouth Disinfection Wear PPE Wash drink or Aerosols or work pipetting Hands smoke safely with sharps
Inhalation
Mucous Membranes
Through Skin Ingestion
HOW RESEARCHERS TYPICALLY ANSWER
Don’t eat, Confine Eliminate No mouth Disinfection Wear PPE Wash drink or Aerosols or work pipetting Hands smoke safely with sharps
Inhalation XX
Mucous Membranes XXXX
Through Skin Xx
Ingestion XXXX
15 MISCONCEPTIONS (OR MISINFORMATION)?
•MY GOWN WON’T PROTECT ME, I ONLY HAVE TO WORRY ABOUT SHARPS.” •I CAN’T GET INFECTED WITH SALMONELLA FROM FACIAL CONTACT •VIBRIO CHOLERAE SHOULD NOT BE CLASSIFIED AS A HUMAN PATHOGEN IN THE USA (WE CAN TREAT IT) •I’M WORKING WITH ATTENUATED VACCINIA, SO I DON’T NEED AN IMMUNIZATION. MY FIRST EXPOSURE WILL BE MY IMMUNIZATION. •I DON’T NEED EYE PROTECTION: I’M USING A BIOSAFETY CABINET; I’M ONLY WORKING WITH GI PATHOGENS; I’M ONLY WORKING WITH SMALL VOLUMES OF LIQUIDS
EXPECTED RESPONSES
Don’t eat, Confine Eliminate No mouth Disinfection Wear PPE Wash drink or Aerosols or work pipetting Hands smoke safely with sharps
Inhalation XXX X
Mucous Membranes XXXXXX
Through Skin XXXX Ingestion xX XX XX
16 FOUNDATION GAME AUGMENTED
Don’t eat, Confine Eliminate No mouth Disinfection Wear PPE Wash drink or Aerosols or work pipetting Hands smoke safely with sharps
Inhalation XXX X
Mucous Membranes X XXXXXX
Through Skin XXX X XXX Ingestion xXX XX XX
SUMMARY •ROUTES OF EXPOSURE HAVE NOT CHANGED •CONTROLLING BIOHAZARDS REMAINS THE AIM •GOOD MICROBIOLOGICAL WORK PRACTICES WILL HELP PREVENT EXPOSURES •THE IMMUNE SYSTEM IS DIVINE, EXCEPT WHEN IT’S NOT •CONSIDER THE PROBABLE, POSSIBLE AND UNRECOGNIZED EXPOSURE ROUTES IN RISK ASSESSMENT AND BIOSAFETY TRAINING (ALONG WITH THE KNOWN EXPOSURE ROUTES AND SIGNS & SYMPTOMS OF DISEASE) •ADDRESS LABORATORIAN MISCONCEPTIONS WITH FACTS
17 “WE ARE ALL THE SAME”
“Do what you can;
With what you have;
In the place that you are;
In the time that you have”
Nkosi Johnson “We Are All The Same” by James Wooten
REFERENCES
• BYERS K.B. AND HARDING L.H. 2017. LABORATORY-ASSOCIATED INFECTIONS. IN: WOOLEY, D.P., BYERS, K.B., EDITORS, BIOLOGICAL SAFETY PRINCIPLES AND PRACTICES, 5 TH ED., WASHINGTON, DC: ASM PRESS . P . 59 -94. • CENTERS FOR DISEASE CONTROL. 1977. RABIES IN A LABORATORY WORKER, NEW YORK. MMWR 26(22): 183-184 • LANGMUIR, A. D. 1960. EPIDEMIOLOGY OF AIRBORNE INFECTIONS. P 173-181. IN: MCDERMONT, W., EDITOR, CONFERENCE ON AIRBORNE INFECTION. BACTERIOLOGICAL REVIEWS (25)3: 173-382. • HEYMAN D. L., R. B. AYLWARD, AND C. WOLFF. 2004. DANGEROUS PATHOGENS IN THE LABORATORY: FROM SMALLPOX TO TODAY’S SARS SETBACKS AND TOMORROW’S POLIO-FREE WORLD. LANCET 363:1566-1568.
18 REFERENCES
• KENNEY, M.T. AND SABEL, F.L. 1968. PARTICLE SIZE DISTRIBUTION OF SERRATIA MARCESANS AEROSOLS CREATED DURING COMMON LABORATORY PROCEDURES AND SIMULATED LABORATORY ACCIDENTS. APPLIED MICROBIOLOGY (16)8: 11 46-1150. • MERMEL, L.A., S.L. JOSEPHSON, J. DEMPSEY, S. PARENTEAU, C. PERRY, AND N. MAGILL. 1997. OUTBREAK OF SHIGELLA SONNEI IN A CLINICAL MICROBIOLOGY LABORATORY. J. CLIN. MICROBIOL. 35:163-165. • MESELSON, M. ET AL, 1994, THE SVERDLOVSK ANTHRAX OUTBREAK OF 1979. SCIENCE 266(5188): 1202 – 08. • PIKE RM. 1979. LABORATORY-ASSOCIATED INFECTIONS: INCIDENCE, FATALITIES, CAUSES, AND PREVENTION. ANNU REV MICROBIOL: 33: 41 -66.
REFERENCES
• PHILLIPS, G.B. 1965. “CAUSAL FACTORS IN MICROBIOLOGICAL LABORATORY ACCIDENTS AND INFECTIONS.” FORT DETRICK, FREDERICK, MD, MISC. PUBL. 2. AD 615-012N, (NATIONAL TECHNICAL INFORMATION SERVICE, SPRINGFIELD, VA.) IN HARDING, A.L. AND BYERS, K.B. 2006. LABORATORY-ASSOCIATED INFECTION,” P. 53- 77. IN FLEMING, D.O. AND HUNT, D.L. (ED.), BIOLOGICAL SAFETY: PRINCIPLES AND PRACTICES, ASM PRESS, WASHINGTON, DC. • REITMAN, M. AND WEDUM A.G. 1956. MICROBIOLOGICAL SAFETY. PUBLIC HEALTH REPORTS. (71)7: 659-665. • SKINHOLJ, P . 1974 . OCCUPATIONAL RISKS IN DANISH CLINICAL CHEMIC AL LABORATORIES. II INFECTIONS. SCAND J CLIN LAB INVEST 33:27-29. • SULKIN SE, PIKE RM. SURVEY OF LABORATORY-ACQUIRED INFECTIONS. AM J PUB HLTH. 1951; 41: 769-81.
19 REFERENCES • SULKIN, S.E. 1960. LABORATORY-ACQUIRED INFECTIONS. P 203-209. IN: MCDERMONT, W., EDITOR, CONFERENCE ON AIRBORNE INFECTION. BACTERIOLOGICAL REVIEWS (25)3: 173-382. • THOMAS, R.J., “PARTICLE SIZE AND PATHOGENICITY IN THE RESPIRATORY TRACT.” VIRULENCE 4:8, 847-858; NOVEMBER 15, 2013. • WEDUM, A.G. 1960. CONTROL OF LABORATORY AIRBORNE INFECTION. P 210-216. IN: MCDERMONT, W., EDITOR, CONFERENCE ON AIRBORNE INFECTION. BACTERIOLOGICAL REVIEWS (25)3: 173-382. WINKLER, W.G. 1973. AIRBORNE RABIES TRANSMISSION IN A LABORATORY WORKER. JAMA 226 (10):1219-1221.
20 Overview of a few Laboratory Acquired Infections (LAIs)
Benjamin Fontes, CBSP, MPH – Yale University EHS
Pathogen Exposure Notable Factors Risk Assessment or Reference Route impact Risk Management failures Salmonella U SO NASS, IBOA, PWP 1, 2, 3, 4, 5, 6 typhimurium ING Salmonella U SO, F NASS, IBOA, PWP 1, 2, 3, 4, 5, 6 typhimurium ING Salmonella U SO NASS, IBOA, PWP 1, 2, 3, 4, 5, 6 typhimurium ING Lassa Fever virus U SI, F NASS, IBOA, PWP 1, 2, 3, 4, 5, 6 AER-L Rabies virus U F PWP 1, 2, 3, 4, 5, 6 AER-L AER-MM Rabies virus U F PWP 1, 2, 3, 4, 5, 6 AER-L AER-MM Neisseria U F NASS, PWP, NIMM 1, 2, 3, 4, 5, 6 meningitidis AER-L Yersinia pestis U F NASS, PWP 1, 2, 3, 4, 5, 6 (attenuated) AER-L Sabia virus U SI NASS, PWP 1, 2, 3, 4, 5, 6 AER-L Samonella typhi U SO, F IBOA, PWP 2, 3, 4 and ING TERR??? S. agona Hepatitis B virus U F PWP, NIMM 2, 3, 4, 5 SK Bacillus cereus U SI NASS, IBOA, PWP 1, 2, 3, 4 SK Shigella sonnei U SI NASS, IBOA, PWP 1, 2, 3, 4, 6 ING SARS-CoV U SO, F IBOA, PWP 1, 2, 3, 4, 5, 6 AER-L Macacine U F NASS, PWP 1, 3, 4, 5 Herpesvirus 1 MM (B-virus) Dengue virus SK PWP 2, 3, 4
Vaccinia virus U NASS, PWP, NIMM 2, 3, 4 VA SK Vaccinia virus U NASS, PWP, NIMM 1, 2, 3, 4, 5 PA MM Vaccinia virus U NASS, PWP, NIMM 1, 3, 4 VA SK Shigella ING SI IBOA, PWP 1, 2, 3 dysenteriae TERR SO HIV SK IBOA, PWP 2, 3, 4
HIV & SK Multiple IBOA, PWP 2, 4, 5 Hepatitis C virus F Borrelia U PWP 2, 4 burgdorferi SK Francisella U NASS, PWP 1, 2, 3, 4, 5 tularensis AER-L Brucella U NASS, IBOA, PWP 1, 2, 3, 4, 5 Melitensis AER-L Cryptosporidium U NASS, PWP 1, 2, 3, 4, 5, 6 parvum MM AER-MM AER-L
TABLE Legend AER-L aerosol exposure to lung 1 pathogen AER-MM aerosol exposure to mucous membranes 2 procedures ING ingestion 3 personnel MM mucous membranes (splash, hand contact) 4 practices (work practices) SK percutaneous, skin 5 protective equipment (personal protective equipment U unknown route of exposure and engineering controls) TERR terrorism 6 place (facility design)
NASS no awareness of signs and symptoms LAI laboratory acquired infection NIMM no immunization F fatal LAI PWP poor work practices SI secondary infection of others in lab or building IBOA infected by others actions SO secondary infection of others outside the institution
Quick Overview of the 6 P’s of Risk Assessment and Risk Management
1-Pathogen Policy that requires registration for possession, use, storage and transfer of biohazards and regulated biological materials including human pathogens. The PI and the IBC must conduct a formal risk assessment of the proposed research with biohazards and a review also of the standard operating procedures developed to work safely with the biohazard. 2-Procedures Identify all of the proposed procedures, supplies and equipment that will be used in the protocol and ensure that this is part of the risk assessment review and assignment of the final biocontainment level and SOPs created for the work. All procedures and all work locations, including animal experiments must be part of this review. Evaluation of sharps risks, aerosol risks, splash and splatter containment, etc. and the commensurate containment needed is part of this process. 3-Personnel A medical surveillance review is required to determine what pre- and post-exposure prophylaxis may be indicated, a review of the signs and symptoms of disease caused by the biohazard and all clinical manifestations must be completed with all involved in the project (researchers to animal handlers, etc.) The PI and IBC must also ensure that all involved have relevant work experience, training, education, awareness and comfort for the proposed research. If needed a competency work practice evaluation should be conducted. Researchers must be reminded to not work with breaks in the skin, to have changes in their health evaluated and to report any potentially related symptoms or illnesses to Occupational Health.
4-Practices The work practices that will be used as part of the SOP to work safely and contain the pathogen must be developed, reviewed and approved by the IBC. These SOPs should be part of the institution’s overall Biosafety Manual to create a site-specific biosafety manual. Some registration forms can guide the PI to develop site-specific work practices. 5-Protective Equipment This part of the Risk Management side of Biorisk Management involves personal protective clothing and equipment and the use of engineering controls. Individuals require training on the use of both. Both must be evaluated to ensure that they are present, adequate, in good condition and used appropriately. 6-Place Facility or lab design is the final part of the Risk Management side and this is the required evaluation by the IBC and Biosafety Officer to ensure that all work locations are appropriate for the proposed research. High traffic areas, large open areas, directional airflow and labs that open directly to public access corridors are some of the factors that must be critically evaluated to ensure that the proposed research will not lead to high risk situations for those performing the work and those outside the lab.
Pathogen LAI Reference Salmonella https://www.cdc.gov/salmonella/2011/lab-exposure-1-17-2012.html typhimurium (CDC https://www.cdc.gov/salmonella/typhimurium-labs-06-14/index.html MMWR) 2011, 2014, https://www.cdc.gov/salmonella/typhimurium-07-17/index.html 2017 Lassa Fever virus http://www.nytimes.com/2004/02/21/nyregion/jordi-casals-ariet-who-found-lassa-virus-dies-at-92.html Rabies virus 1973 Winkler WG, Fashinell TR, Leffingwell L, et al. Airborne rabies transmission in a laboratory worker. JAMA. 1973;226:1219-21. Rabies virus 1977 Centers for Disease Control and Prevention. Rabies in a laboratory worker, New York. MMWR Morb Mortal Wkly Rep. 1977;26:183-4. Neisseria meningitidis http://www.sciencemag.org/news/2012/05/death-california-researcher-spurs-investigation 2012 https://www.cdc.gov/mmwr/preview/mmwrhtml/mm6335a2.htm Yersinia pestis 2009 https://www.cdc.gov/mmwr/preview/mmwrhtml/mm6007a1.htm
Sabia virus 1994 https://www.aiha.org/get-involved/VolunteerGroups/LabHSCommittee/Pages/Sabia-Virus-in-Centrifuge- Incident.aspx http://www.nytimes.com/1994/12/13/science/yale-accepts-blame-for-safety-lapses-linked-to-lab-accident.html
Salmonella agona, https://www.ncbi.nlm.nih.gov/pmc/articles/PMC273903/ Salmonella typhi, 1980 Hepatitis B virus, 1985 Personal communication in Clinical Chemistry laboratory
Bacillus cereus, 2011 http://www.sciencemag.org/news/2011/09/updated-university-chicago-microbiologist-infected-possible-lab- accident https://sites.google.com/site/bioterrorbible/lab-accidents/bio-lab-accidents- 2011?tmpl=%2Fsystem%2Fapp%2Ftemplates%2Fprint%2F&showPrintDialog=1 Shigella sonnei, 1996 http://jcm.asm.org/content/35/12/3163.full.pdf
SARS-CoV, 2003, 2004 http://www.who.int/csr/don/2004_04_30/en/ http://www.nytimes.com/2004/04/26/world/new-cases-identified-in-china-s-sars-outbreak.html http://www.cidrap.umn.edu/news-perspective/2003/12/taiwanese-sars-researcher-infected http://www.nejm.org/doi/full/10.1056/NEJMoa032565 Macacine Herpesvirus https://www.cdc.gov/mmwr/preview/mmwrhtml/00056008.htm 1, 1997 Dengue infection, 2014 https://my.absa.org/LAI
Vaccinia virus, CT VA https://www.cdc.gov/mmwr/preview/mmwrhtml/mm5715a3.htm Hospital, 2005 Vaccinia virus, PA, 2004 https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3291406/
Vaccinia virus, VA, https://www.cdc.gov/mmwr/preview/mmwrhtml/mm5829a1.htm 2008
Shigella dysenteriae, https://jamanetwork.com/journals/jama/fullarticle/417894 1996 HIV needlestick 1988 http://www.nytimes.com/1997/12/18/nyregion/yale-must-pay-12.2-million-to-a-physician-who-got-hiv.html
HIV/Hepatitis C virus https://www.ahcmedia.com/articles/20911-the-needlestick-that-changed-her-life 1998, 1990 https://www.ahcmedia.com/articles/58948-double-deadly-needlestick-transmits-hiv-and-hcv http://www.nejm.org/doi/full/10.1056/NEJM199703273361304 Borrelia burgdorferi Personal communication, bite of infected nymph tick 1996 Brucella abortus, 2006 http://www.cidrap.umn.edu/news-perspective/2007/07/cdc-suspends-work-texas-am-biodefense-lab http://www.cidrap.umn.edu/news-perspective/2007/09/cdc-details-problems-texas-am-biodefense-lab Cryptosporidium https://absaconference.org/wp-content/uploads/2016/10/ABSA2016_Session17_Philpott.pdf parvum, 2011 Francisella tularensis http://www.cidrap.umn.edu/news-perspective/2005/04/inquiry-leaves-boston-tularemia-mystery-unsolved http://massspectrometryconsortium.arizona.edu/sites/default/files/Boston_Univerity_Tularemia_report_2005.pdf