2,2',4-Trihydroxybenzophenone


Associated AOPs with Level of Relevance - 1 AOPs with at least 1 KE associated with chemical, where the KE(s) are neither MIE nor AO

AOP Identifier AOP Title AO Classification OECD Status Taxonomic applicability Coverage Score The fraction of KEs within the AOP, that are mapped to the chemical-associated toxicological endpoints. KE Identifier KE Name
AOP:27Cholestatic Liver Injury induced by Inhibition of the Bile Salt Export Pump (ABCB11)Gastrointestinal system diseaseUnder DevelopmentHumans0.12KE:149Increase, Inflammation
AOP:115Epithelial cytotoxicity leading to forestomach tumors (in mouse and rat)Cancer-Mus musculus, Rattus norvegicus0.2KE:149Increase, Inflammation
AOP:206Peroxisome proliferator-activated receptors γ inactivation leading to lung fibrosisMusculoskeletal system disease; Respiratory system diseaseUnder DevelopmentHomo sapiens0.17KE:149Increase, Inflammation
AOP:280α-diketone-induced bronchiolitis obliteransMusculoskeletal system disease; Respiratory system disease-0.14KE:149Increase, Inflammation
AOP:362Immune mediated hepatitisGastrointestinal system disease; Immune system disease-Homo sapiens, Rat0.12KE:1633Increase in inflammation
AOP:439Activation of the AhR leading to metastatic breast cancerThoracic disease; CancerUnder DevelopmentHumans, Mice0.11KE:149Increase, Inflammation
AOP:446PM-related Adverse outcome pathway frameworks on various systemsRespiratory system disease-0.05KE:149Increase, Inflammation
AOP:447Kidney failure induced by inhibition of mitochondrial electron transfer chain through apoptosis, inflammation and oxidative stress pathwaysUrinary system disease-0.08KE:1633Increase in inflammation
AOP:463The AOP framwork on silica nanopariticles induced hepatoxicityGastrointestinal system disease-0.09KE:149Increase, Inflammation
AOP:472DNA adduct formation leading to kidney failureUrinary system disease-0.11KE:149Increase, Inflammation
AOP:493ERa inactivation alters AT expansion and functions and leads to insulin resistance and metabolically unhealthy obesityAcquired metabolic disease-Mus musculus, Homo sapiens0.1KE:1633Increase in inflammation
AOP:505Reactive Oxygen Species (ROS) formation leads to cancer via inflammation pathwayCancer-Human, Mouse, Rat0.2KE:149Increase, Inflammation
AOP:535Binding and activation of GPER leading to learning and memory impairmentsDevelopmental disorder of mental health-Mouse, Human0.11KE:2233Decreased, ERαβ heterodimers
AOP:544Inhibition of neuropathy target esterase leading to delayed neuropathy via increased inflammationNervous system disease-Homo sapiens, Mus musculus0.17KE:149Increase, Inflammation
AOP:550Increased LMNA gene mutation leading to heart failureCardiovascular system disease-Human, Mouse, Rat0.2KE:2066Altered Signaling Pathways

Associated AOPs with Level of Relevance - 2 AOPs with at least 1 AO associated with chemical, and no associated MIE

AOP Identifier AOP Title AO Classification OECD Status Taxonomic applicability Coverage Score The fraction of KEs within the AOP, that are mapped to the chemical-associated toxicological endpoints. KE Identifier KE Name
AOP:392Decreased fibrinolysis and activated bradykinin system leading to hyperinflammationUnclassifiedUnder DevelopmentHumans0.2KE:1868Hyperinflammation
AOP:406SARS-CoV-2 infection leading to hyperinflammationUnclassified-0.17KE:1868Hyperinflammation
AOP:468Binding of SARS-CoV-2 to ACE2 leads to hyperinflammation (via cell death)Unclassified-0.12KE:1868Hyperinflammation

No associated AOPs with Level of Relevance 3

No associated AOPs with Level of Relevance 5
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We have built a comprehensive resource which compiles potential endocrine disrupting chemicals (EDCs) based on the observed adverse effects or endocrine-mediated endpoints in published experiments on humans or rodents to support basic research. We are not responsible for any errors or omissions in the published research articles or supporting literature on potential EDCs compiled in this resource. Users are advised to exercise their own judgement on the weight of evidence for potential EDCs compiled in this resource. Importantly, our sole goal to build this resource on potential EDCs is to enable future basic research towards better understanding of the systems-level perturbations upon chemical exposure rather than influencing regulatory advice on chemical use.