Available studies (67 found)
| Short citation | Full citation | Bioassay | Epidemiology | Epi. meta-analysis | In vitro | Ecology |
|---|---|---|---|---|---|---|
| Isales, 2015 | Isales, 2015, Triphenyl phosphate-induced developmental toxicity in zebrafish: Potential role of the retinoic acid receptor | |||||
| Johannsen, 1977, 4120438 | Johannsen, 1977, Evaluation of Delayed Neurotoxicity and Dose-Response Relationships of Phosphate Esters in the Adult Hen | |||||
| Kim, 2015 | Kim, 2015, Thyroid disruption by triphenyl phosphate, an organophosphate flame retardant, in zebrafish (Danio rerio) embryos/larvae, and in GH3 and FRTL-5 cell lines | |||||
| Kojima, 2013 | Kojima, 2013, In vitro endocrine disruption potential of organophosphate flameretardants via human nuclear receptors | |||||
| Kojima, 2016 | Kojima, 2016, Effects of primary metabolites of organophosphate flame retardants on transcriptional activity via human nuclear receptors | |||||
| Krivoshiev, 2015 | Krivoshiev, 2015, Elucidating toxicological mechanisms of current flame retardants using a bacterial gene profiling assay | |||||
| Krivoshiev, 2016 | Krivoshiev, 2016, Assessing in-vitro estrogenic effects of currently-used flame retardants | |||||
| Liu, 2012, 1401243 | Liu, X; Ji, K; Choi, K (2012). Endocrine disruption potentials of organophosphate flame retardants and related mechanisms in H295R and MVLN cell lines and in zebrafish, in vivo. Aquatic Toxicology 114-115: 173-181. https://www.sciencedirect.com/science/article/pii/S0166445X12000690?via%3Dihub | |||||
| Liu, 2012, in-vitro | Liu, 2012, Endocrine disruption potentials of organophosphate flame retardants and related mechanisms in H295R and MVLN cell lines and in zebrafish, in-vitro | |||||
| Liu, 2013, 4214653 | Liu, X; Ji, K; Jo, A; Moon, HB; Choi, K (2013). Effects of TDCPP or TPP on gene transcriptions and hormones of HPG axis, and their consequences on reproduction in adult zebrafish (Danio rerio). Aquatic Toxicology 134-135:104-111. 10.1016/j.aquatox.2013.03.013 | |||||
| Liu, 2013a | Liu, 2013a, Effects of tris(1,3-dichloro-2-propyl) phosphate and triphenyl phosphate on receptor-associated mRNA expression in zebrafish embryos/larvae | |||||
| Liu, 2016, 4182540 | Liu, X; Jung, D; Jo, A; Ji, K; Moon, HB; Choi, K (2016). Long-term Exposure to Triphenylphosphate Alters Hormone Balance and HPG, HPI, and HPT Gene Expression in Zebrafish (Danio Rerio). Environmental Toxicology and Chemistry 35(9): 2288-2296. https://setac.onlinelibrary.wiley.com/doi/abs/10.1002/etc.3395 | |||||
| McGee, 2013 | McGee, 2013, Aryl Phosphate Esters Within a Major PentaBDE Replacement Product Induce Cardiotoxicity in Developing Zebrafish Embryos: Potential Role of the Aryl Hydrocarbon Receptor | |||||
| Meeker, 2010, 999025 | Meeker JD and Stapleton HM. House dust concentrations of organophosphate flame retardants in relation to hormone levels and semen quality parameters. Environmental Health Perspectives 118:318-323. HERO DOI | |||||
| Mitchell, 2018 | Mitchell, 2018, Disruption of Nuclear Receptor Signaling Alters Triphenyl Phosphate-Induced Cardiotoxicity in Zebrafish Embryos | |||||
| Obersteiner, 1978 | Obersteiner, 1978, Evaluation of Cytotoxic Responses Caused by Selected Organophosphorus Esters in Chick Sympathetic Ganglia Cultures | |||||
| Oliveri, 2015, 3363884 | Oliveri, AN; Bailey, JM; Levin, ED (2015). Developmental exposure to organophosphate flame retardants causes behavioral effects in larval and adult zebrafish. Neurotoxicology and Teratology 52: 220-227. https://heronet.epa.gov/heronet/index.cfm/reference/details/reference_id/3363884 | |||||
| Owens, 2007 | Owens, 2007, Identification of Estrogenic Compounds Emitted from the Combustion of Computer Printed Circuit Boards in Electronic Waste | |||||
| Palawski, 1983, 4937481 | Palawski, D; Buckler, DR; Mayer, FL (1983). Survival and Condition of Rainbow Trout (Salmo gairdneri) After Acute Exposures to Methyl Parathion, Triphenyl Phosphate, and DEF. Bulletin of Environmental Contamination and Toxicology 30(5): 614-620. https://link.springer.com/article/10.1007%2FBF01610183 | |||||
| Pei, 2016 | Pei, 2016, Comparative neurotoxicityscreeninginhuman iPSC-derived neuralstemcells,neurons and astrocytes | |||||
| Philbrook, 2018, 4928176 | Philbrook, NA; Restivo, VE; Belanger, CL; Winn, LM (2018). Gestational triphenyl phosphate exposure in C57Bl/6 mice perturbs expression of insulin-like growth factor signaling genes in maternal and fetal liver. Birth Defects Research 110 (6): 483-494. 10.1002/bdr2.1185 | |||||
| Pillai, 2014 | Pillai, 2014, Ligand Binding and Activation of PPARγ by Firemaster® 550: Effects on Adipogenesis and Osteogenesis in Vitro | |||||
| Preston, 2017, 3863813 | Preston EV et al. Associations between urinary diphenyl phosphate and thyroid function. Environment International 101:158-164. HERO DOI | |||||
| Saboori, 1991 | Saboori, 1991, Structural Requirements for the Inhibition of Human Monocyte Carboxylesterase by Organophosphorus Compounds | |||||
| Scanlan, 2015 | Scanlan, 2015, Gene Transcription, Metabolite and Lipid Profiling in Eco-Indicator Daphnia magna Indicate Diverse Mechanisms of Toxicity by Legacy and Emerging Flame-Retardants |
Showing studies 26-50 of 67