10
Mention of any company or product does not constitute an
endorsement by NIOSH or CDC. The authors declare no
other conflict of interest relating to the material presented
in this paper.
REFERENCES
[1] Krefft, S., J. Wolff, and C. Rose, Silicosis: An Update
and Guide for Clinicians. Clin Chest Med, 2020.
41(4): p. 709–722.
[2] Leung, C.C., I.T. Yu, and W. Chen, Silicosis. Lancet,
2012. 379(9830): p. 2008–18.
[3] U.S. Department of Health and Human Services
(HHS) Centers for Disease Control and Prevention
(CDC) National Institute for Occupational Safety
and Health, (NIOSH)., Dust control handbook for
industrial minerals mining and processing. 2019. 2nd
edition.
[4] Wolfe, C., et al., Monitoring Worker Exposure to
Respirable Crystalline Silica: Application for Data-
driven Predictive Modeling for End-of-Shift Exposure
Assessment. Ann Work Expo Health, 2022. 66(8):
p. 1010–1021.
[5] Ashley, E.L., et al., Performance Comparison of
Four Portable FTIR Instruments for Direct-on-Filter
Measurement of Respirable Crystalline Silica. Ann
Work Expo Health, 2020. 64(5): p. 536–546.
[6] Cauda, E., et al., Benefits and limitations of field-based
monitoring approaches for respirable dust and crystalline
silica applied in a sandstone quarry. J Occup Environ
Hyg, 2022. 19(12): p. 730–741.
[7] Hart, J.F., et al., A comparison of respirable crystalline
silica concentration measurements using a direct-on-filter
Fourier transform infrared (FT-IR) transmission method
vs. a traditional laboratory X-ray diffraction method. J
Occup Environ Hyg, 2018. 15(10): p. 743–754.
[8] Ashley, K., NIOSH Manual of Analytical Methods
5(th) Edition and Harmonization of Occupational
Exposure Monitoring. Gefahrst Reinhalt Luft, 2015.
2015(1–2): p. 7–16.
[9] Cecala, A.B., et al., Helmet-Cam: tool for assessing
miners’ respirable dust exposure. Min Eng, 2013. 65(9):
p. 78–84.
[10] Patts, J.R., A.B. Cecala, and E.J. Haas, Helmet-CAM:
Strategically Minimizing Exposures to Respirable Dust
Through Video Exposure Monitoring. Min Metall
Explor, 2020. 37(2): p. 727–732.
[11] Haas, E.J., A.B. Cecala, and C.L. Hoebbel, Using Dust
Assessment Technology to Leverage Mine Site Manager-
Worker Communication and Health Behavior: A
Longitudinal Case Study. J Progress Res Soc Sci, 2016.
3(1): p. 154–167.
[12] Cauda, E., L. Chubb, R. Reed, and R. Stepp,
Evaluating the use of a field-based silica monitor-
ing approach with dust from copper mines. J Occup
Environ Hyg, 2018. 15(10): p. 732–742.
[13] Kelly, K.E., et al., Ambient and laboratory evaluation
of a low-cost particulate matter sensor. Environ Pollut,
2017. 221: p. 491–500.
[14] Sayahi, T., A. Butterfield, and K.E. Kelly, Long-term
field evaluation of the Plantower PMS low-cost particu-
late matter sensors. Environmental Pollution, 2019.
245: p. 932–940.
[15] Chubb, L.G. and E.g., Cauda, A novel sampling cas-
sette for field-based analysis of respirable crystalline sil-
ica. J Occup Environ Hyg, 2021. 18(3): p. 103–109.
[16] Patts, J.R., et al., Performance Comparison of Real-
Time Light Scattering Dust Monitors Across Dust Types
and Humidity Levels. Min Metall Explor, 2019. 36(4):
p. 741–749.
Mention of any company or product does not constitute an
endorsement by NIOSH or CDC. The authors declare no
other conflict of interest relating to the material presented
in this paper.
REFERENCES
[1] Krefft, S., J. Wolff, and C. Rose, Silicosis: An Update
and Guide for Clinicians. Clin Chest Med, 2020.
41(4): p. 709–722.
[2] Leung, C.C., I.T. Yu, and W. Chen, Silicosis. Lancet,
2012. 379(9830): p. 2008–18.
[3] U.S. Department of Health and Human Services
(HHS) Centers for Disease Control and Prevention
(CDC) National Institute for Occupational Safety
and Health, (NIOSH)., Dust control handbook for
industrial minerals mining and processing. 2019. 2nd
edition.
[4] Wolfe, C., et al., Monitoring Worker Exposure to
Respirable Crystalline Silica: Application for Data-
driven Predictive Modeling for End-of-Shift Exposure
Assessment. Ann Work Expo Health, 2022. 66(8):
p. 1010–1021.
[5] Ashley, E.L., et al., Performance Comparison of
Four Portable FTIR Instruments for Direct-on-Filter
Measurement of Respirable Crystalline Silica. Ann
Work Expo Health, 2020. 64(5): p. 536–546.
[6] Cauda, E., et al., Benefits and limitations of field-based
monitoring approaches for respirable dust and crystalline
silica applied in a sandstone quarry. J Occup Environ
Hyg, 2022. 19(12): p. 730–741.
[7] Hart, J.F., et al., A comparison of respirable crystalline
silica concentration measurements using a direct-on-filter
Fourier transform infrared (FT-IR) transmission method
vs. a traditional laboratory X-ray diffraction method. J
Occup Environ Hyg, 2018. 15(10): p. 743–754.
[8] Ashley, K., NIOSH Manual of Analytical Methods
5(th) Edition and Harmonization of Occupational
Exposure Monitoring. Gefahrst Reinhalt Luft, 2015.
2015(1–2): p. 7–16.
[9] Cecala, A.B., et al., Helmet-Cam: tool for assessing
miners’ respirable dust exposure. Min Eng, 2013. 65(9):
p. 78–84.
[10] Patts, J.R., A.B. Cecala, and E.J. Haas, Helmet-CAM:
Strategically Minimizing Exposures to Respirable Dust
Through Video Exposure Monitoring. Min Metall
Explor, 2020. 37(2): p. 727–732.
[11] Haas, E.J., A.B. Cecala, and C.L. Hoebbel, Using Dust
Assessment Technology to Leverage Mine Site Manager-
Worker Communication and Health Behavior: A
Longitudinal Case Study. J Progress Res Soc Sci, 2016.
3(1): p. 154–167.
[12] Cauda, E., L. Chubb, R. Reed, and R. Stepp,
Evaluating the use of a field-based silica monitor-
ing approach with dust from copper mines. J Occup
Environ Hyg, 2018. 15(10): p. 732–742.
[13] Kelly, K.E., et al., Ambient and laboratory evaluation
of a low-cost particulate matter sensor. Environ Pollut,
2017. 221: p. 491–500.
[14] Sayahi, T., A. Butterfield, and K.E. Kelly, Long-term
field evaluation of the Plantower PMS low-cost particu-
late matter sensors. Environmental Pollution, 2019.
245: p. 932–940.
[15] Chubb, L.G. and E.g., Cauda, A novel sampling cas-
sette for field-based analysis of respirable crystalline sil-
ica. J Occup Environ Hyg, 2021. 18(3): p. 103–109.
[16] Patts, J.R., et al., Performance Comparison of Real-
Time Light Scattering Dust Monitors Across Dust Types
and Humidity Levels. Min Metall Explor, 2019. 36(4):
p. 741–749.