Toward understanding the risk of secondary airborne infection: emission of respirable pathogens M Nicas, WW Nazaroff, A Hubbard Journal of occupational and environmental hygiene 2 (3), 143-154, 2005 | 1107 | 2005 |
A study quantifying the hand-to-face contact rate and its potential application to predicting respiratory tract infection M Nicas, D Best Journal of occupational and environmental hygiene 5 (6), 347-352, 2008 | 333 | 2008 |
Relative contributions of four exposure pathways to influenza infection risk M Nicas, RM Jones Risk Analysis: An International Journal 29 (9), 1292-1303, 2009 | 214 | 2009 |
Estimating exposure intensity in an imperfectly mixed room M Nicas American Industrial Hygiene Association Journal 57 (6), 542-550, 1996 | 174 | 1996 |
An integrated model of infection risk in a health‐care environment M Nicas, G Sun Risk Analysis 26 (4), 1085-1096, 2006 | 151 | 2006 |
Respiratory protection and the risk of Mycobacterium tuberculosis infection M Nicas American journal of industrial medicine 27 (3), 317-333, 1995 | 95 | 1995 |
Respiratory protection against Mycobacterium tuberculosis: quantitative fit test outcomes for five type N95 filtering-facepiece respirators K Lee, A Slavcev, M Nicas Journal of occupational and environmental hygiene 1 (1), 22-28, 2004 | 90 | 2004 |
Informing optimal environmental influenza interventions: how the host, agent, and environment alter dominant routes of transmission IH Spicknall, JS Koopman, M Nicas, JM Pujol, S Li, JNS Eisenberg PLoS Computational Biology 6 (10), e1000969, 2010 | 84 | 2010 |
Worker exposure to volatile organic compounds in the vehicle repair industry MP Wilson, SK Hammond, M Nicas, AE Hubbard Journal of Occupational and Environmental Hygiene 4 (5), 301-310, 2007 | 84 | 2007 |
Framework for evaluating measures to control nosocomial tuberculosis transmission WW Nazaroff, M Nicas, SL Miller Indoor Air 8 (4), 205-218, 1998 | 82 | 1998 |
A multi-zone model evaluation of the efficacy of upper-room air ultraviolet germicidal irradiation M Nicas, SL Miller Applied Occupational and Environmental Hygiene 14 (5), 317-328, 1999 | 78 | 1999 |
The Infectious Dose of Coxiella Burnetii (Q Fever) RM Jones, M Nicas, AE Hubbard, AL Reingold Applied Biosafety 11 (1), 32-41, 2006 | 77 | 2006 |
An analytical framework for relating dose, risk, and incidence: an application to occupational tuberculosis infection M Nicas Risk Analysis 16 (4), 527-538, 1996 | 75 | 1996 |
Organophosphorous pesticide breakdown products in house dust and children's urine L Quirós-Alcalá, A Bradman, K Smith, G Weerasekera, M Odetokun, ... Journal of exposure science & environmental epidemiology 22 (6), 559-568, 2012 | 62 | 2012 |
Markov modeling of contaminant concentrations in indoor air M Nicas AIHAJ-American Industrial Hygiene Association 61 (4), 484-491, 2000 | 60 | 2000 |
Environmental versus analytical variability in exposure measurements M Nicas, BP Simmons, RC Spear American Industrial Hygiene Association Journal 52 (12), 553-557, 1991 | 60 | 1991 |
Characterizing the Risk of Infection from Mycobacterium tuberculosis in Commercial Passenger Aircraft Using Quantitative Microbial Risk Assessment RM Jones, Y Masago, T Bartrand, CN Haas, M Nicas, JB Rose Risk Analysis: An International Journal 29 (3), 355-365, 2009 | 56 | 2009 |
The Infectious Dose of Francisella Tularensis (Tularemia) RM Jones, M Nicas, A Hubbard, MD Sylvester, A Reingold Applied Biosafety 10 (4), 227-239, 2005 | 56 | 2005 |
Predicting room vapor concentrations due to spills of organic solvents CB Keil, M Nicas AIHA Journal 64 (4), 445-454, 2003 | 54 | 2003 |
Evaluation of COSHH Essentials for vapor degreasing and bag filling operations RM Jones, M Nicas Annals of occupational hygiene 50 (2), 137-147, 2006 | 53 | 2006 |