These are exposure studies associated with the disease and all of its children.
|Reference||Associated Study Title||Author's Summary||Study Factors||Stressor||Receptors||Country||Medium||Exposure Marker||Measurements||Outcome|
|1.||Forns J, et al. (2016).||Norwegian Human Milk Study (HUMIS)||Within a mixture of 24 toxicants measured in breast milk, p,p'-DDT was the single toxicant associated with behavioral problems at 12 months using different methods for handling numerous correlated exposures.||2,2',3,3',4,4',5-
||Infants or newborns | Mothers||Norway||milk, human||2,2',3,3',4,4',5-
||Details||Child Behavior Disorders|
|2.||Rahman SM, et al. (2016).||Maternal and Infant Nutrition Interventions in Matlab (MINIMat)||Elevated prenatal water manganese exposure was positively associated with cognitive function in girls, while boys appeared unaffected; however, early-life exposure appeared to adversely affect children's behavior.||age | diet | sex||Arsenic | Manganese||Children | Pregnant females||Bangladesh||water, drinking||Arsenic | Manganese||Details||Child Behavior Disorders | cognition|
|3.||Szkup-Jabłońska M, et al. (2012).||The effect of lead on the developing child has behavioral consequences including attention disorders, hyperactivity, and impulsive behavior; no effect of cadmium was shown.||age||Cadmium | Lead||Subjects with disease:Attention Deficit Disorder with Hyperactivity | Subjects with disease:Child Behavior Disorders | Children||Poland||blood||Cadmium | Lead||Details||Attention Deficit Disorder with Hyperactivity|
|4.||Forns J, et al. (2016).||BRain dEvelopment and Air polluTion ultrafine particles in scHool childrEn (BREATHE) Project||In our study population of 7- to 11-year-old children residing in Barcelona, exposure to TRAPs at school was associated with increased behavioral problems in schoolchildren.||Carbon | Nitrogen Dioxide | Soot||Children||Spain||air||Carbon | Nitrogen Dioxide | Soot||Details||Child Behavior Disorders|