NEHA December 2022 Journal of Environmental Health

December 2022 • our1al o) E18,ro1me1tal Healt+ 49 Garrison, V.E.H., & Ashley, P.J. (2021). Identifying jurisdictions at risk of containing housing units with deteriorated paint: Results and targeting implications for the US Department of Housing and Urban Development. Journal of Public Health Management &Practice, 27(6), 546–557. https:// Griggs, J.L., Thomas, D.J., Fry, R., & Bradham, K.D. (2021). Improving the predictive value of bioaccessibility assays and their use to provide mechanistic insights into bioavailability for toxic metals/metalloids—A research prospectus. Journal of Toxicology & Environmental Health, Part B: Critical Reviews, 24(7), 307–324. https:// Harmon, S.M., Tully, J., DeSantis, M.K., Schock, M.R., Triantafyllidou, S., & Lytle, D.A. (2022). A holistic approach to lead pipe scale analysis: Importance, methodology, and limitations. AWWA Water Science, 4(2), e1278. Hensley, K., Bosscher, V., Triantafyllidou, S., & Lytle, D.A. (2021). Lead service line identification: A review of strategies and approaches. AWWA Water Science, 3(3), e1226. Karna, R.R., Noerpel, M.R., Nelson, C., Elek, B., Herbin-Davis, K., Diamond, G., Bradham, K., Thomas, D.J., & Scheckel, K.G. (2020). Bioavailable soil Pb minimized by in situ transformation to plumbojarosite. Proceedings of the National Academy of Sciences of the United States of America, 118(3), e2020315117. 2020315117 Klemick, H., Mason, H., & Sullivan, K. (2020). Superfund cleanups and children’s lead exposure. Journal of Environmental Economics and Management, 100, Article 102289. jeem.2019.102289 Liggett, J., Baribeau, H., Deshommes, E., Lytle, D.A., Masters, S.V., Muylwyk, Q., & Triantafyllidou, S. (2022). Service line material identification: Experiences from North American water systems. Journal– American Water Works Association, 114(1), 8–19. Lytle, D.A., Schock, M.R., & Triantafyllidou, S. (2018). Identify lead plumbing sources to protect public health. Opflow, 44(3), 16–20. 2018.44.0027 Mielke, H.W., Gonzales, C.R., Powell, E.T., Laidlaw, M.A.S., Berry, K.J., Mielke, P.W., Jr., & Egendorf, S.P. (2019). The concurrent decline of soil lead and children’s blood lead in New Orleans. Proceedings of the National Academy of Sciences of the United States of America, 116(44), 22058–22064. Misenheimer, J., Nelson, C., Huertas, E., Medina-Vera, M., Prevatte, A., & Bradham, K. (2018). Total and bioaccessible soil arsenic and lead levels and plant uptake in three urban community gardens in Puerto Rico. Geosciences, 8(2), 43. https://doi. org/10.3390/geosciences8020043 Özkaynak, H., Glen, G., Cohen, J., Hubbard, H., Thomas, K., Phillips, L., & Tulve, N. (2022). Model based prediction of age-specific soil and dust ingestion rates for children. Journal of Exposure Science & Environmental Epidemiology, 32(3), 472–480. https://doi. org/10.1038/s41370-021-00406-5 President’s Task Force on Environmental Health Risks and Safety Risks to Children. (2016). Key federal programs to reduce childhood lead exposures and eliminate associated health impacts. https://ptfceh.niehs.nih. gov/features/assets/files/key_federal_pro grams_to_reduce_childhood_lead_expo sures_and_eliminate_associated_health_ impactspresidents_508.pdf Ruckart, P.Z., Jones, R.L., Courtney, J.G., LeBlanc, T.T., Jackson, W., Karwowski, M.P., Cheng, P.-Y., Allwood, P., Svendsen, E.R., & Breysse, P.N. (2021). Update of the blood lead reference value—United States, 2021. Morbidity and Mortality Weekly Report, 70(43), 1509–1512. https://doi. org/10.15585/mmwr.mm7043a4 Schock, M.R., Lytle, D.A., James, R.R., Lal, V., & Tang, M. (2021). Rapid and simple lead service line detection screening protocol using water sampling. AWWA Water Science, 3(5), e1255. aws2.1255 Schultz, B.D., Morara, M., Buxton, B.E., & Weintraub, M. (2017). Predicting bloodlead levels among U.S. children at the census tract level. Environmental Justice, 10(5), 129–136. env.2017.0005 Sowers, T.D., Bone, S.E., Noerpel, M.R., Blackmon, M.D., Karna, R.R., Scheckel, K.G., Juhasz, A.L., Diamond, G.L., Thomas, D.J., & Bradham, K.D. (2021). Plumbojarosite remediation of soil aªects lead speciation and elemental interactions in soil and in mice tissues. Environmental Science & Technology, 55(23), 15950–15960. https://doi. org/10.1021/acs.est.1c06067 U.S. Environmental Protection Agency. (2021). Public comment draft: EPA strategy to reduce lead exposures and disparities in U.S. communities. https://www.epa. gov/system/files/documents/2021-11/ updated-public-comment-draft-lead-strat egy-11-16-2021.pdf U.S. Environmental Protection Agency. (2022a). Revised Lead and Copper Rule. inking-water/revised-lead-and-cop per-rule U.S. Environmental Protection Agency. (2022b). Lead at Superfund sites: Software and users’ manuals. superfund/lead-superfund-sites-softwareand-users-manuals Xue, J., Zartarian, V., Tornero-Velez, R., Stanek, L.W., Poulakos, A., Walts, A., Triantafillou, K., Suero, M., & Grokhowsky, N. (2022). A generalizable evaluated approach, applying advanced geospatial statistical methods, to identify high lead exposure locations at census tract scale: Michigan case study. Environmental Health Perspectives, 130(7), Article 077004. Ye, D., Brown, J.S., Umbach, D.M., Adams, J., Thayer, W., Follansbee, M.H., & Kirrane, E.F. (2022). Estimating the eªects of soil remediation on children’s blood lead near a former lead smelter in Omaha, Nebraska, USA. Environmental Health Perspectives, 130(3), Article 037008. https:// Zartarian, V., Poulakos, A., Garrison, V.H., Spalt, N., Tornero-Velez, R., Xue, J., Egan, K., & Courtney, J. (in press). Lead data mapping to prioritize US locations for whole-of-government exposure prevention eªorts: State of the science, federal collaborations, and remaining challenges. American Journal of Public Health. Zartarian, V., Xue, J., Tornero-Velez, R., & Brown, J. (2017). Children’s lead exposure: A multimedia modeling analysis to guide public health decision-making. Environmental Health Perspectives, 125(9), Article 097009. EHP1605