Last data update: Oct 07, 2024. (Total: 47845 publications since 2009)
Records 1-6 (of 6 Records) |
Query Trace: de Beer L[original query] |
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Evaluation of emissions and exposures at workplaces using desktop 3-dimensional printers
Stefaniak AB , Johnson AR , du Preez S , Hammond DR , Wells JR , Ham JE , LeBouf RF , Menchaca KW , Martin SBJr , Duling MG , Bowers LN , Knepp AK , Su FC , de Beer DJ , du Plessis JL . J Chem Health Saf 2019 26 (2) 19-30 There is a paucity of data on additive manufacturing process emissions and personal exposures in real-world workplaces. Hence, we evaluated atmospheres in four workplaces utilizing desktop "3-dimensional" (3-d) printers [fused filament fabrication (FFF) and sheer] for production, prototyping, or research. Airborne particle diameter and number concentration and total volatile organic compound concentrations were measured using real-time instruments. Airborne particles and volatile organic compounds were collected using time-integrated sampling techniques for off-line analysis. Personal exposures for metals and volatile organic compounds were measured in the breathing zone of operators. All 3-d printers that were monitored released ultrafine and fine particles and organic vapors into workplace air. Particle number-based emission rates (#/min) ranged from 9.4 times 109 to 4.4 times 1011 (n = 9 samples) for FFF 3-d printers and from 1.9 to 3.8 times 109 (n = 2 samples) for a sheer 3-d printer. The large variability in emission rate values reflected variability from the printers as well as differences in printer design, operating conditions, and feedstock materials among printers. A custom-built ventilated enclosure evaluated at one facility was capable of reducing particle number and total organic chemical concentrations by 99.7% and 53.2%, respectively. Carbonyl compounds were detected in room air; however, none were specifically attributed to the 3-d printing process. Personal exposure to metals (aluminum, iron) and 12 different organic chemicals were all below applicable NIOSH Recommended Exposure Limit values, but results are not reflective of all possible exposure scenarios. More research is needed to understand 3- d printer emissions, exposures, and efficacy of engineering controls in occupational settings. |
Insights into emissions and exposures from use of industrial-scale additive manufacturing machines
Stefaniak AB , Johnson AR , du Preez S , Hammond DR , Wells JR , Ham JE , LeBouf RF , Martin SB , Duling MG , Bowers LN , Knepp AK , de Beer DJ , du Plessis JL . Saf Health Work 2018 10 (2) 229-236 Background Emerging reports suggest the potential for adverse health effects from exposure to emissions from some additive manufacturing (AM) processes. There is a paucity of real-world data on emissions from AM machines in industrial workplaces and personal exposures among AM operators. Methods Airborne particle and organic chemical emissions and personal exposures were characterized using real-time and time-integrated sampling techniques in four manufacturing facilities using industrial-scale material extrusion and material jetting AM processes. Results Using a condensation nuclei counter, number-based particle emission rates (ERs) (number/min) from material extrusion AM machines ranged from 4.1 x 1010 (Ultem filament) to 2.2 x 1011 [acrylonitrile butadiene styrene and polycarbonate filaments). For these same machines, total volatile organic compound ERs (microg/min) ranged from 1.9 x 104 (acrylonitrile butadiene styrene and polycarbonate) to 9.4 x 104 (Ultem). For the material jetting machines, the number-based particle ER was higher when the lid was open (2.3 x 1010 number/min) than when the lid was closed (1.5-5.5 x 109 number/min); total volatile organic compound ERs were similar regardless of the lid position. Low levels of acetone, benzene, toluene, and m,p-xylene were common to both AM processes. Carbonyl compounds were detected; however, none were specifically attributed to the AM processes. Personal exposures to metals (aluminum and iron) and eight volatile organic compounds were all below National Institute for Occupational Safety and Health (NIOSH)-recommended exposure levels. Conclusion Industrial-scale AM machines using thermoplastics and resins released particles and organic vapors into workplace air. More research is needed to understand factors influencing real-world industrial-scale AM process emissions and exposures. |
Infection prevention and control training and capacity building during the Ebola epidemic in Guinea
Soeters HM , Koivogui L , de Beer L , Johnson CY , Diaby D , Ouedraogo A , Toure F , Bangoura FO , Chang MA , Chea N , Dotson EM , Finlay A , Fitter D , Hamel MJ , Hazim C , Larzelere M , Park BJ , Rowe AK , Thompson-Paul AM , Twyman A , Barry M , Ntaw G , Diallo AO . PLoS One 2018 13 (2) e0193291 BACKGROUND: During the 2014-2016 Ebola epidemic in West Africa, a key epidemiological feature was disease transmission within healthcare facilities, indicating a need for infection prevention and control (IPC) training and support. METHODS: IPC training was provided to frontline healthcare workers (HCW) in healthcare facilities that were not Ebola treatment units, as well as to IPC trainers and IPC supervisors placed in healthcare facilities. Trainings included both didactic and hands-on components, and were assessed using pre-tests, post-tests and practical evaluations. We calculated median percent increase in knowledge. RESULTS: From October-December 2014, 20 IPC courses trained 1,625 Guineans: 1,521 HCW, 55 IPC trainers, and 49 IPC supervisors. Median test scores increased 40% (interquartile range [IQR]: 19-86%) among HCW, 15% (IQR: 8-33%) among IPC trainers, and 21% (IQR: 15-30%) among IPC supervisors (all P<0.0001) to post-test scores of 83%, 93%, and 93%, respectively. CONCLUSIONS: IPC training resulted in clear improvements in knowledge and was feasible in a public health emergency setting. This method of IPC training addressed a high demand among HCW. Valuable lessons were learned to facilitate expansion of IPC training to other prefectures; this model may be considered when responding to other large outbreaks. |
Assessment of traditional and improved stove use on household air pollution and personal exposures in rural western Kenya
Yip F , Christensen B , Sircar K , Naeher L , Bruce N , Pennise D , Lozier M , Pilishvili T , Loo Farrar J , Stanistreet D , Nyagol R , Muoki J , de Beer L , Sage M , Kapil V . Environ Int 2016 99 185-191 BACKGROUND: Over 40% of the world's population relies on solid fuels for heating and cooking. Use of improved biomass cookstoves (ICS) has the potential to reduce household air pollution (HAP). OBJECTIVES: As part of an evaluation to identify ICS for use in Kenya, we collected indoor air and personal air samples to assess differences between traditional cookstoves (TCS) and ICS. METHODS: We conducted a cross-over study in 2012 in two Kenyan villages; up to six different ICS were installed in 45 households during six two-week periods. Forty-eight hour kitchen measurements of fine particulate matter (PM2.5) and carbon monoxide (CO) were collected for the TCS and ICS. Concurrent personal CO measurements were conducted on the mother and one child in each household. We performed descriptive analysis and compared paired measurements between baseline (TCS only) and each ICS. RESULTS: The geometric mean of 48-hour baseline PM2.5 and CO concentrations in the kitchen was 586mug/m3 (95% CI: 460, 747) and 4.9ppm (95% CI: 4.3, 5.5), respectively. For each ICS, the geometric mean kitchen air pollutant concentration was lower than the TCS: median reductions were 38.8% (95% CI: 29.5, 45.2) for PM2.5 and 27.1% (95% CI: 17.4, 40.3) for CO, with statistically significant relationships for four ICS. We also observed a reduction in personal exposures to CO with ICS use. CONCLUSIONS: We observed a reduction in mean 48-hour PM2.5 and CO concentrations compared to the TCS; however, concentrations for both pollutants were still consistently higher than WHO air quality guidelines. Our findings illustrate that ICS tested in real-world settings can reduce exposures to HAP, but implementation of cleaner fuels and related stove technologies may also be necessary to optimize public health benefits. |
Second worldwide proficiency study on variable number of tandem repeats typing of Mycobacterium tuberculosis complex
De Beer JL , Kodmon C , Van Ingen J , Jamieson FB , Bidovec-Stojkovic U , Brown T , Cirillo DM , Cruz L , Miranda A , Dou HY , Fauville-Dufaux M , Fitzgibbon MM , Garcia De Viedma D , Groenheit R , Haanpera-Heikkinen M , Indra A , Kam KM , Kramer R , Jiang GL , Niemann S , Obrovac M , Rasmussen EM , Refregier G , Realpe T , Samper S , Sharma MK , Sougakoff W , Stakenas P , Stavrum R , Trenkler J , Wada T , Siame KK , Tafaj S , Cowan L , Sng LH , Seagar AL , Basu I , Rastogi N , Ferro BE , De Matos F , Kipnis A , Van Soolingen D , Supply P . Int J Tuberc Lung Dis 2014 18 (5) 594-600+i BACKGROUND: The quality of variable number of tandem repeats (VNTR) typing of Mycobacterium tuberculosis was first investigated in 2009 in 37 laboratories worldwide. The results revealed an inter- and intra-laboratory reproducibility of respectively 60% and 72%. These data spurred an improvement in laboratory-specific assays and global standardisation of VNTR typing. OBJECTIVE: To measure the effects of the technical improvements and increased standardisation, a test panel consisting of 30 M. tuberculosis complex DNA samples was distributed for VNTR typing in 41 participating laboratories from 36 countries. RESULTS: The inter- and intra-laboratory reproducibility increased overall to respectively 78% and 88%. The 33 laboratories that participated in both the first and second proficiency studies improved their inter- and intra-laboratory reproducibility from 62% and 72% to respectively 79% and 88%. The largest improvement in reproducibility was detected in 10 laboratories that use an in-house polymerase chain reaction technique and perform amplicon sizing using gel electrophoresis. Detailed error analysis revealed a reduction in the number of systematic errors, sample exchange events and non-amplifiable loci. CONCLUSION: This second worldwide proficiency study indicates a substantial increase in the reproducibility of VNTR typing of M. tuberculosis. This will contribute to a more meaningful interpretation of molecular epidemiological and phylogenetic studies on the M. tuberculosis complex. |
Evaluation of mycobacterial interspersed repetitive-unit-variable-number tandem-repeat genotyping as performed in laboratories in Canada, France, and the United States
Cowan LS , Hooks DP , Christianson S , Sharma MK , Alexander DC , Guthrie JL , Jamieson FB , Supply P , Allix-Beguec C , Cruz L , Desmond E , Kramer R , Lugo S , Rudrik J . J Clin Microbiol 2012 50 (5) 1830-1 The external quality assessment of 24-locus mycobacterial interspersed repetitive-unit–variable-number tandem-repeat (MIRU-VNTR) genotyping by de Beer et al. reveals issues with its international performance (5). Detailed analysis of the data was confounded by the complexity of the participants. The five genotyping laboratories in Canada and the United States participating in this study use similar typing protocols based on the standardized protocol proposed by Supply et al. (8) and developed in collaboration with each other. Systems for routine handling of samples and data management are well established. Quality control (QC) and assurance measures include routine testing of the Mycobacterium tuberculosis strain H37Rv and repeat testing of 1% of isolates at an external laboratory. The laboratorians conducting the analysis have at a minimum 5 years of experience performing MIRU-VNTR typing. This cohesiveness allows for a more in-depth analysis of the data collected by de Beer et al. | Each laboratory reported 24-locus MIRU-VNTR results for the proficiency testing panel of 30 DNA samples (including 10 pairs of duplicates), and their performance is summarized in Table 1. Reproducibility as calculated at the sample level and disregarding missing results ranged from 93% to 100%, and typeability as calculated by the percentage of loci with a reportable result ranged from 98.9% to 100%. Here we present a detailed description of the 38 observed discrepancies to provide a more complete understanding of the performance of MIRU-VNTR typing in our laboratories. |
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