232 Autism and Exposure to Environmental Chemicals
120 Isgor C, Sengelaub DR (1998). Prenatal gonadal steroids affect adult spatial
behavior, CA1 and CA3 pyramidal cell morphology in rats. Horm. Behav.,
34 (2):183–98.
121 Christensen BC, Marsit CJ (2011). Epigenomics in environmental health.
Front. Genet., 2 :84.
122 Rissman EF, Adli M (2014). Minireview: transgenerational epigenetic
inheritance: focus on endocrine disrupting compounds. Endocrinology,
155 :2770–80.
123 Ho SM, Johnson A, Tarapore P, et al. (2012). Environmental epigenetics
and its implication on disease risk and health outcomes. ILAR J.,
53 :289–305.
124 Greally JM, Jacobs MN (2013). In vitro and in vivo testing methods of
epigenomic endpoints for evaluating endocrine disruptors. A LT E X,
30 :445–71.
125 Uzumcu M, Zama AM, Oruc E (2012). Epigenetic mechanisms in the actions
of endocrine‐disrupting chemicals: gonadal effects and role in female
reproduction. Reprod. Domest. Anim., 47 (Suppl. 4):338–47.
126 Skakkebaek NE, Rajpert‐De Meyts E, Main KM (2001). Testicular dysgenesis
syndrome: an increasingly common developmental disorder with
environmental aspects. Hum. Reprod., 16 :972–8.
127 Dalgaard MD, Weinhold N, Edsgärd D, et al. (2012). A genome‐wide
association study of men with symptoms of testicular dysgenesis syndrome
and its network biology interpretation. J. Med. Genet., 49 :58–65.
128 Christiansen S, Kortenkamp A, Axelstad M, et al. (2012). Mixtures of
endocrine disrupting contaminants modelled on human high end exposures:
an exploratory study in rats. Int. J. Androl., 35 :303–16.
129 Skakkebaek NE, Rajpert‐De Meyts E, Buck Louis GM, et al. (2016). Male
reproductive disorders and fertility trends: Influences of environment and
genetic susceptibility. Physiol. Rev., 96 (1):55–97.
130 Virtanen HE, Koskenniemi JJ, Sundqvist E, et al. (2012). Associations
between congenital cryptorchidism in newborn boys and levels of dioxins
and PCBs in placenta. Int. J. Androl., 35 :283–93.
131 Krysiak‐Baltyn K, Toppari J, Skakkebaek NE, et al. (2012). Association
between chemical pattern in breast milk and congenital cryptorchidism:
modelling of complex human exposures. Int. J. Androl. 35 :294–302.
132 Brucker‐Davis F, Wagner‐Mahler K, Delattre I, et al. (2008). Cryptorchidism
at birth in Nice area (France) is associated with higher prenatal exposure to
PCBs and DDE, as assessed by colostrum concentrations. Hum. Reprod.,
23 :1708–18.
133 Main KM, Mortensen GK, Kaleva MM, et al. (2006). Human breast milk
contamination with phthalates and alterations of endogenous reproductive
hormones in infants three months of age. Environ. Health Perspect.,
114 :270–6.