Cui, X-Y, Xiang, P, He, R-W, Juhasz, A, and Ma, L Q.  2016.  Advances in in vitro methods to evaluate oral bioaccessibility of PAHs and PBDEs in environmental matrices.  Chemosphere, 150, 3478–389.

Diamond, G L, Bradham, K D, Brattin, W J, Burgess, M, Griffin, S, Hawkins, C A, Juhasz, A L, Klotzbach, J M, Nelson, C, Lowney, Y W, Scheckel, K G, and Thomas, D J.  2016.  Predicting oral relative bioavailability of arsenic in soil from in vitro bioaccessibility.  Journal of Toxicology and Environmental Health, Part A, 79, 165–173.

Juhasz, A L, Herde, P, and Smith, E.  2016.  Oral relative bioavailability of Dichlorodiphenyltrichloroethane (DDT) in contaminated soil and its prediction using in vitro strategies for exposure refinement. Environmental Research, 150, 482–488.

Juhasz, A L, Scheckel, K G, Betts, A R, and Smith, E. 2016. Predictive Capabilities of in Vitro Assays for Estimating Pb Relative Bioavailability in Phosphate Amended Soil. Environmental Science & Technology, 50, 13086–13094.

Juhasz, A L, Tang, W, and Smith, E.  2016.  Using in vitro bioaccessibility to refine estimates of human exposure to PAHs via incidental soil ingestion.  Environmental Research, 145, 145–153.

Li, C, Sun, H, Juhasz, A L, Cui, X, and Ma, L Q.  2016.  Predicting the relative bioavailability of DDT and its metabolites in historically contaminated soils using a Tenax-improved physiologically based extraction test (TI-PBET).  Environmental Science & Technology, 50, 1118–1125.

Li, H-B, Zhao, D, Li, J, Li, S-W, Wang, N, Juhasz, A L, Zhu, Y-G and Ma, L Q.  2016.  Using the SBRC assay to predict lead relative bioavailability in urban soils: contaminant source and correlation model.  Environmental Science & Technology, 50, 4989–4996.

Li, J, Li, C, Sun, H-J, Juhasz, A L, Luo, J, Li, H-B, and Ma, L Q.  2016.  Arsenic relative bioavailability in contaminated soils: comparison of animal models, dosing schemes and biological end points.  Environmental Science & Technology, 50, 456–561.

Ollson, C J, Smith, W, Scheckel, K G, Betts, A R and Juhasz, A L.  2016.  Assessment of arsenic speciation and bioaccessibility in mine-impacted materials.  Journal of Hazardous Materials, 313, 130–137.

Ollson, C J, Smith, E, Herde, P, and Juhasz, J L. 2016. Influence of co–contaminant exposure on the absorption of arsenic, cadmium and lead. Chemosphere, 168, 658–666.

Zhao, D, Li, J, Li, C, Juhasz, A L, Scheckel, K G, Luo, J, Li, H-B, and Ma, L Q.  2016.  Lead relative bioavailability in lip products and their potential health risk to women.  Environmental Science & Technology, 50, 6036–6043

Juhasz, A L, Herde, P, Herde, C, Boland, J, and Smith, E.  2015.  Predicting arsenic relative bioavailability using multiple in vitro assays: validation of in vivo–in vitro correlations.  Environmental Science & Technology, 49, 11167–11175.

Li, H-B, Chen, K, Juhasz, A L, Huang, L, and Ma, L Q.  2015.  Childhood lead exposure in an industrial town in China: coupling stable isotope ratios with bioaccessible lead.  Environmental Science & Technology, 49, 5080–5087.

Li, H-B, Li, J, Zhu, Y-G, Juhasz, A L, and Ma, L Q.  2015.  Comparison of arsenic bioaccessibility in housedust and contaminated soils based on four in vitro assays.  Science of the Total Environment, 532, 803–811.

Li, K, Li, C, Yu, N-Y, Juhasz, A L, Cui, X-Y, and Ma, L Q.  2015.  In vivo bioavailability and in vitro bioaccessibility of perfluorooctanoic acid (PFOA) in food matrices: correlation analysis and method development.  Environmental Science & Technology, 49, 150–158.

Mele, E, Donner, E, Juhasz, A L, Brunetti, G, Smith, E, Betts, A R, Castaldi, P, Deiana, S, Scheckel, K G and Lombi, E.  2015.  In situ fixation of metal(loid)s in contaminated soils: a comparison of conventional, opportunistic, and engineered soil amendments.  Environmental Science & Technology, 49, 13501–13509.

Ng, J C, Juhasz, A, Smith, E, and Naidu, R.  2015.  Assessing the bioavailability and bioaccessibility of metals and metalloids.  Environmental Science and Pollution Research, 12, 8802–8825.

Basta, N T, and Juhasz, A.  2014.  Using in vivo bioavailability and/or in vitro gastrointestinal bioaccessibility testing to adjust human exposure to arsenic from soil ingestion.  Reviews in Mineralogy and Geochemistry, 79, 451–472.

Juhasz, A L, Aleer, S, and Adetutu, E M.  2014.  Predicting PAH bioremediation efficacy using bioaccessibility assessment tools: validation of PAH biodegradation-bioaccessibility correlations.  International Biodeterioration & Biodegradation, 95, Part B, 320–329.

Juhasz, A L, Gancarz, D, Herde, C, McClure, S, Scheckel, K G, and Smith, E.  2014.  In situ formation of pyromorphite is not required for the reduction of in vivo Pb relative bioavailability in contaminated soils.  Environmental Science & Technology, 48, 7002–7009.

Juhasz, A L, Herde, P, Herde, C, Boland, J, and Smith, E.  2014.  Validation of the predictive capabilities of the Sbrc-G in vitro assay for estimating arsenic relative bioavailability in contaminated soils.  Environmental Science & Technology, 48, 12962–12969.

Juhasz, A L, Smith, E, Nelson, C, Thomas, D J, and Bradham, K.  2014.  Variability associated with As in vivo–in vitro correlations when using different bioaccessibility methodologies.  Environmental Science & Technology, 48, 11646–11653.

Juhasz, A L, Weber, J, Stevenson, G, Slee, D, Gancarz, D, Rofe, A, and Smith, E.  2014.  In vivo measurement, in vitro estimation and fugacity prediction of PAH bioavailability in post-remediated creosote-contaminated soil.  Science of the Total Environment, 473–474, 147–154.

Li, H-B, Cui, X-Y, Li, K, Li, J, Juhasz, A L, and Ma, L Q.  2014.  Assessment of in vitro lead bioaccessibility in house dust and its relationship to in vivo lead relative bioavailability.  Environmental Science & Technology, 48, 8548–8555.

Li, H-B, Li, J, Juhasz, A L, and Ma, L Q.  2014.  Correlation of in vivo relative bioavailability to in vitro bioaccessibility for arsenic in household dust from China and its implication for human exposure Assessment.  Environmental Science & Technology, 48, 13652–13659.

Smith, E, Scheckel, K, Miller, B W, Weber, J, and Juhasz, A L.  2014.  Influence of in vitro assay pH and extractant composition on As bioaccessibility in contaminated soils.  Science of the Total Environment, 473–474, 172–177.

Juhasz, A L, Basta, N T, and Smith, E  2013.  What is required for the validation of in vitro assays for predicting contaminant relative bioavailability? Considerations and criteria.  Environmental Pollution, 180, 372–375.

Juhasz, A L, Smith, E, Weber, J, Rees, M, Kuchel, T, Rofe, A, Sansom, L, and Naidu, R.  2013.  Predicting lead relative bioavailability in peri-urban contaminated soils using in vitro bioaccessibility assays.  Journal of Environmental Science and Health, Part A , 48, 604–611.

Mahmoudi, N, Slater, G F, and Juhasz, A L.  2013.  Assessing limitations for PAH biodegradation in long-term contaminated soils using bioaccessibility assays.  Water, Air, & Soil Pollution, 224, 1411.

Rostami, I, and Juhasz, A L.  2013.  Bioaccessibility-based predictions for estimating PAH biodegradation efficacy — comparison of model predictions and measured endpoints.  International Biodeterioration & Biodegradation, 85, 323–330.

Smith, E, Weber, J, Rofe, A, Gancarz, D, Naidu, R, and Juhasz, A L.  2013.  Assessment of DDT relative bioavailability and bioaccessibility in historically contaminated soils using an in vivo mouse model and fed and unfed batch in vitro assays.  Environmental Science & Technology, 46, 2928–2934.

Smith, E, and five others.  2012.  Assessment of DDT relative bioavailability and bioaccessibility in historically contaminated soils using an in vivo mouse model and fed and unfed batch in vitro assays. Environmental Science & Technology, 46, 2928–2934

Juhasz, A L, Weber, J, and Smith, E.  2011.  Impact of soil particle size and bioaccessibility on children and adult lead exposure in peri-urban contaminated soils.  Journal of Hazardous Materials, 186, 1870–1879.

Juhasz, A L, Weber, J, and Smith, E.  2011.  Influence of saliva, gastric and intestinal phases on the prediction of As relative bioavailability using the unified Bioaccessibility Research Group of Europe method (UBM).  Journal of Hazardous Materials, 197, 161–168.

Juhasz, A L, Weber, J, and Smith, E.  2011.  Predicting arsenic relative bioavailability in contaminated soils using meta analysis and relative bioavailability-bioaccessibility regression.  Environmental Science & Technology, 45, 10676–10683.

Rostami, I, and Juhasz, A L.  2011.  Assessment of persistent organic pollutant (POP) bioavailability and bioaccessibility for human health exposure assessment: a critical review.  Critical Reviews in Environmental Science and Technology, 41, 623–656.

Smith, E, Kempson, I M, Juhasz, A L, Weber, J, Rofe, A, Gancarz, D, Naidu, R, McLaren, R G, and Gräfe, M.  2011.  In vivo–in vitro and XANES spectroscopy assessments of lead bioavailability in contaminated periurban soils.Environmental Science & Techno, 45, 6145–6152.

Smith, E, Weber, J, Naidu, R, McLaren, R G, and Juhasz, A L.  2011.  Assessment of lead bioaccessibility in peri-urban contaminated soils.  Journal of Hazardous Materials, 186, 300–305.

Bioavailability and speciation of arsenic contaminated food and the relevance to human exposure. (No link available.)

Dandie, C E, Weber, J, Aleer, S, Adetutu, E M, Ball, A, and Juhasz, A L.  2010.  Assessment of five bioaccessibility assays for predicting the efficacy of petroleum hydrocarbon biodegradation in aged contaminated soils.  Chemosphere, 81, 1061–1068.

Juhasz, A L, Smith, E, Waller, N, Stewart, R, and Weber, J.  2010.  Bioavailability of residual polycyclic aromatic hydrocarbons following enhanced natural attenuation of creosote-contaminated soil.  Environmental Pollution, 158, 585–591.

Juhasz, A L, Weber, J, Naidu, R, Gancarz, D, Rofe, A, Todor, D, and Smith, E.  2010.  Determination of cadmium relative bioavailability in contaminated soils and its prediction using in vitro methodologies.  Environmental Science & Technology, 44, 5240–5247.

Juhasz, A L, Weber, J, Smith, E, Naidu, R, Marschner, B, Rees, M, Rofe, A, Kuchel, T, and Sansom, L.  2009.  Evaluation of SBRC-gastric and SBRC-intestinal methods for the prediction of in vivo relative lead bioavailability in contaminated soils.  Environmental Science & Technology, 43, 4503–4509.

Juhasz, A L, Weber, J, Smith, E, Naidu, R, Rees, M, Rofe, A, Kuchel, T, and Sansom, L.  2009.  Assessment of four commonly employed in vitro arsenic bioaccessibility assays for predicting in vivo relative arsenic bioavailability in contaminated soils.  Environmental Science & Technology, 43, 9487–9494.

Rees, M, Sansom, L, Rofe, A, Juhasz, A L, Smith, E, Weber, J, Naidu, R, and Kuchel, T.  2009.  Principles and application of an in vivo swine assay for the determination of arsenic bioavailability in contaminated matrices.  Environmental Geochemistry and Health, 31, 167–177.

Smith, E, Juhasz, A L, and Weber, J.  2009.  Arsenic uptake and speciation in vegetables grown under greenhouse conditions.  Environmental Geochemistry and health, 31, 125–132.

Smith, E, Weber, J and Juhasz, A L.  2009.  Arsenic distribution and bioaccessibility across particle fractions in historically contaminated soils.  Environmental Geochemistry and Health, 31, 85–92.

Juhasz, A L, Smith, E, Weber, J, Naidu, R, Rees, M, Rofe, A, Kuchel, T, and Sansom, L.  2008.  Effect of soil ageing on in vivo arsenic bioavailability in two dissimilar soils.  Chemosphere, 71, 2180–2186.

Juhasz, A L, Smith, E, Weber, J, Rees, M, Rofe, A, Kuchel, T, Sansom, L, and Naidu, R.  2008.  Application of an in vivo swine model for the determination of arsenic bioavailability in contaminated vegetables.  Chemosphere, 71, 1963–1969.

Smith, E, Naidu, R, Weber, J, and Juhasz, A L.  2008.  The impact of sequestration on the bioaccessibility of arsenic in long-term contaminated soils. Chemosphere, 71, 773–780.

Juhasz, A L, Smith, E, Weber, J, Rees, M, Rofe, A, Kuchel, T, Sansom, L, and Naidu, R.  2007.  Comparison of in vivo and in vitro methodologies for the assessment of arsenic bioavailability in contaminated soils.  Chemosphere, 69, 961–966.

Juhasz, A L, Smith, E, Weber, J, Rees, M, Rofe, A, Kuchel, T, Sansom, L, and Naidu, R.  2007.  In vitro assessment of arsenic bioaccessibility in contaminated (anthropogenic and geogenic) soils.  Chemosphere, 69, 69–78.

Juhasz, A L, Smith, E, Weber, J, Rees, M, Rofe, A, Kuchel, T, Sansom, L, and Naidu, R  2006.  In vivo assessment of arsenic bioavailability in rice and its significance for human health risk assessment.  Environmental Health Perspectives, 114, 1826–1831.

Juhasz, A L, Waller, N , and Stewart, R.  2005.  Predicting the efficacy of PAH bioremediation in creosote-contaminated soil using bioavailability assays.  Bioremediation Journal, 9, 99–114.

Juhasz, A L, Naidu, R, Zhu, Y G, Wang, L S, Jiang, J Y, and Cao, Z H.  2003.  Toxicity issues associated with geogenic arsenic in the groundwater–soil–plant–human continuum  Bulletin of Environmental Contamination and Toxicology, 71, 1100–1107.