Maternal serum persistent organic pollutants in the Finnish Prenatal Study of Autism: A pilot study

Cheslack‐Postava, Keely; Rantakokko, Panu; Hinkka‐Yli‐Salomäki, Susanna; Surcel, Heljä‐Marja; McKeague, Ian W.; Kiviranta, Hannu; Sourander, André; Brown, Alan S.

doi:10.1016/j.ntt.2013.04.001

Cited by 92 publications

(99 citation statements)

References 39 publications

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“…Because the hypothalamus is critically important for the regulation of mood and emotion, as well as sociality (Engel, Miodovnik et al 2010, Hoffman, Webster et al 2010, Miodovnik, Engel et al 2011, Eskenazi, Chevrier et al 2013), the neural outcomes reviewed here are consistent with and supportive of epidemiological data in children associating BPA and PCBs with ASD, ADHD, and anxiety disorders (Eubig, Aguiar et al 2010, Sagiv, Thurston et al 2010, Braun, Kalkbrenner et al 2011, Cheslack-Postava, Rantakokko et al 2013). Interestingly, no immune related endpoints have been investigated to date in sub-adult animals, even though some immune cells like microglia (Wood 2011, Wu, Tan et al 2013) and neutrophils (Molero, Garcia-Duran et al 2002, Shindo, Moore et al 2013) have been found to express estrogen receptors, impact sexually dimorphic development (O’Malley, Liston et al 2011) and the immune system is reciprocally influenced by the hypothalamus.…”

Section: Resultssupporting

confidence: 80%

Assessment of sex specific endocrine disrupting effects in the prenatal and pre-pubertal rodent brain

Rebuli

Patisaul

2016

The Journal of Steroid Biochemistry and Molecular Biology

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Background Brain sex differences are found in nearly every region of the brain and fundamental to sexually dimorphic behaviors as well as disorders of the brain and behavior. These differences are organized during gestation and early adolescence and detectable prior to puberty. Endocrine disrupting compounds (EDCs) interfere with hormone action and are thus prenatal exposure is hypothesized to disrupt the formation of sex differences, and contribute to the increased prevalence of pediatric neuropsychiatric disorders that present with a sex bias. Objective Available evidence for the ability of EDCs to impact the emergence of brain sex differences in the rodent brain was reviewed here, with a focus on effects detected at or before puberty. Methods The peer-reviewed literature was searched using PubMed, and all relevant papers published by January 31, 2015 were incorporated. Endpoints of interest included molecular cellular and neuroanatomical effects. Studies on behavioral endpoints were not included because numerous reviews of that literature are available. Results The hypothalamus was found to be particularly affected by estrogenic EDCs in a sex, time, and exposure dependent manner. The hippocampus also appears vulnerable to endocrine disruption by BPA and PCBs although there is little evidence from the pre-pubertal literature to make any conclusions about sex-specific effects. Gestational EDC exposure can alter fetal neurogenesis and gene expression throughout the brain including the cortex and cerebellum. The available literature primarily focuses on a few, well characterized EDCs, but little data is available for emerging contaminants. Conclusion The developmental EDC exposure literature demonstrates evidence of altered neurodevelopment as early as fetal life, with sex specific effects observed throughout the brain even before puberty.

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Section: Resultssupporting

confidence: 80%

Assessment of sex specific endocrine disrupting effects in the prenatal and pre-pubertal rodent brain

Rebuli

Patisaul

2016

The Journal of Steroid Biochemistry and Molecular Biology

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“…We hypothesize that one of the major reasons for the alarming rise in autism and autism spectrum disorder is the rise in use of fragrances 2 . It should be noted that autism used to be a relatively rare diseases at the turn of the 20th century [2][3][4][5][6][22][23][24] , but it has now been found that 1 out 88 children is suffering from ASD; again, this may be an underestimate. Since a neonate's brain is still developing after birth, we should expect a rise in other neurological but related conditions (e.g.…”

Section: Discussionmentioning

confidence: 99%

“…Since a neonate's brain is still developing after birth, we should expect a rise in other neurological but related conditions (e.g. attention de icit hyperactive disorder [ADHD], regressive autism; for example, a child is born normal but begins to show signs of autism after 18 months or later) [21][22][23][24] . ASD is a developmental condition characterized by de icits in social interaction, verbal and nonverbal communication and obsessive/stereotyped patterns of behaviour.…”

Section: Discussionmentioning

confidence: 99%

Smell of autism: Synthetic fragrances and cause for allergies, asthma, cancer and autism

Bagasra¹,

Pace²

2013

OA Autism

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“…Five studies in the first category (a) utilized biomarkers of toxicant exposure 17, 18, 19, 20, 21 to create dichotomous toxicant exposure groups and then prospectively investigated whether these exposure groups were associated with ASD development later in life. As these studies were not primarily concerned with the relationship between these biomarkers and ASD, these studies were placed into category (a) instead of (b).…”

Section: Methodsmentioning

confidence: 99%

Environmental toxicants and autism spectrum disorders: a systematic review

Rossignol¹,

2014

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Although the involvement of genetic abnormalities in autism spectrum disorders (ASD) is well-accepted, recent studies point to an equal contribution by environmental factors, particularly environmental toxicants. However, these toxicant-related studies in ASD have not been systematically reviewed to date. Therefore, we compiled publications investigating potential associations between environmental toxicants and ASD and arranged these publications into the following three categories: (a) studies examining estimated toxicant exposures in the environment during the preconceptional, gestational and early childhood periods; (b) studies investigating biomarkers of toxicants; and (c) studies examining potential genetic susceptibilities to toxicants. A literature search of nine electronic scientific databases through November 2013 was performed. In the first category examining ASD risk and estimated toxicant exposures in the environment, the majority of studies (34/37; 92%) reported an association. Most of these studies were retrospective case–control, ecological or prospective cohort studies, although a few had weaker study designs (for example, case reports or series). Toxicants implicated in ASD included pesticides, phthalates, polychlorinated biphenyls (PCBs), solvents, toxic waste sites, air pollutants and heavy metals, with the strongest evidence found for air pollutants and pesticides. Gestational exposure to methylmercury (through fish exposure, one study) and childhood exposure to pollutants in water supplies (two studies) were not found to be associated with ASD risk. In the second category of studies investigating biomarkers of toxicants and ASD, a large number was dedicated to examining heavy metals. Such studies demonstrated mixed findings, with only 19 of 40 (47%) case–control studies reporting higher concentrations of heavy metals in blood, urine, hair, brain or teeth of children with ASD compared with controls. Other biomarker studies reported that solvent, phthalate and pesticide levels were associated with ASD, whereas PCB studies were mixed. Seven studies reported a relationship between autism severity and heavy metal biomarkers, suggesting evidence of a dose–effect relationship. Overall, the evidence linking biomarkers of toxicants with ASD (the second category) was weaker compared with the evidence associating estimated exposures to toxicants in the environment and ASD risk (the first category) because many of the biomarker studies contained small sample sizes and the relationships between biomarkers and ASD were inconsistent across studies. Regarding the third category of studies investigating potential genetic susceptibilities to toxicants, 10 unique studies examined polymorphisms in genes associated with increased susceptibilities to toxicants, with 8 studies reporting that such polymorphisms were more common in ASD individuals (or their mothers, 1 study) compared with controls (one study examined multiple polymorphisms). Genes implicated in these studies included paraoxonase (PON1, three of five...

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Maternal serum persistent organic pollutants in the Finnish Prenatal Study of Autism: A pilot study

Cited by 92 publications

References 39 publications

Assessment of sex specific endocrine disrupting effects in the prenatal and pre-pubertal rodent brain

Assessment of sex specific endocrine disrupting effects in the prenatal and pre-pubertal rodent brain

Smell of autism: Synthetic fragrances and cause for allergies, asthma, cancer and autism

Environmental toxicants and autism spectrum disorders: a systematic review

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