Even tiny amounts of toxic chemicals at key phases of our lives can increase the risk of disease and other health effects later in life, or in future generations.
When it comes to exposures to certain chemicals, scientists discuss the importance of “timing of exposure” or “windows of susceptibility” during development when the body is especially sensitive to exposures.
Some of these key windows of susceptibility occur during prenatal development and puberty, when the body’s cells are dividing rapidly and when complex organs and functions such as brains, breasts and metabolism develop. For anyone who has been pregnant or known someone who was pregnant, this probably comes as no surprise. During pregnancy, women are cautioned to avoid smoking and alcohol, to limit consumption of foods that may contain neurotoxins such as tuna (which can contain mercury), and to get enough of key nutrients. The womb is the first environment, and it turns out that the health of this first environment can impact health for decades to follow.[1],[2],[3],[4]
Many personal care products contain chemicals that disrupt hormones. For instance, parabens, common preservatives in cosmetics, and triclosan, a common active ingredient in antibacterial soaps and hand sanitizers, have been shown to disrupt hormones.
Historical examples of toxic exposures in humans powerfully illustrate the ways that timing of exposure affects the development of disease across future generations.
Between 1938 and 1971 doctors prescribed Diethylstilbestrol (DES) for millions of pregnant women to prevent miscarriages, culminating in a medical tragedy that has affected at least 5 million people. Daughters of women who took the drug were found to have higher rates of an extremely rare vaginal cancer, in addition to breast cancer. The drug was banned in 1971.
As a synthetic estrogen, DES was ineffective in its intended use of preventing miscarriage and led to serious health consequences. DES exposure caused structural abnormalities, infertility, and increased rates of vaginal and cervical cancers among the daughters of mothers who took DES during pregnancy.[5] In addition, research suggests an increased risk of breast cancer for both mothers and daughters.[6],[7],[8]
Another historical example of human chemical exposure illustrates that certain exposures may have stronger effects when they occur early in life. DDT was first synthesized in 1874, and its efficacy as a pesticide was proven in 1939. The chemical was widely used during World War II, and afterward its use was prolific in parts of the US. In 1962, Rachel Carson documented concerns about the pesticide’s effects on wildlife and humans, but the following 35 years yielded scant data of a link to breast cancer. Then, in 2007, a researcher used blood samples from the 1950s and 60s to look at the levels of DDT among girls at that time. She asked whether the DDT exposures around the age of puberty led to increased risk of breast cancer many decades later. Results show that exposure to DDT during childhood and early adolescence (younger than age 14) was associated with a fivefold increase in risk of developing breast cancer before the age of 50. The younger the women were during the period of heavy DDT use (1945 to 1972), the greater the effect. At the time of the study, the authors noted, “Many U.S. women heavily exposed to DDT in childhood have not yet reached age 50. The public health significance of DDT exposure in early life may be large.”[9]
In both of these cases, decades went by with unfettered use of chemicals and resulting widespread exposures, in part because many adult-onset diseases don’t show up until decades later. Exposure to endocrine-disrupting compounds in personal care products could lead to similar interactions between timing and exposure that increase health risks and outcomes in ways that contribute to later life disease.
References
[1] Antshel KM, Waisbren SE (2003). Developmental timing of exposure to elevated levels of phenylalanine is associated with ADHD symptom expression.Journal of Abnormal Child Psychology, 31(6):565-74.
[2] Fenton SE (2006). Endocrine-disrupting compounds and mammary gland development: Early exposure and later life consequences. Endocrinology 147 (Suppl): S18-S24.
[3] Fenton SE, Hamm JT, Birnbaum LS, Youngblood GL (2002). Persistent abnormalities in the rat mammary gland following gestational and lactational exposure to 2,3,7,8-tetrachlorodibenzo-p-diosin (TCDD). Toxicological Science 67:63-74.
[4] Russo J, Hu YF, Silva IDCG, Russo IH (2001). Cancer risk related to mammary gland structure and development. Microscopy Research and Technique 52: 204-223.
[5] Li S, Hursting SD, Davis BJ, McLachlan JA, Barrett JC (2003). Environmental exposure, DNA methylation, and gene regulation: Lessons from diethylstilbestrol-induced cancers. Annals of the NY Academy of Sciences.983: 161-169.
[6] Colton T, Greenberg ER, Noller K, Resseguie L, Van Bennedom C, Heeren T, Zhang Y (1993). Breast cancer in mothers prescribed diethylstilbestrol in pregnancy. Further follow-up. Journal of the American Medical Association, 269: 2096-2100.
[7] Titus-Ernstoff L, Hatch EE, Hoover RN, Palmer J, Greenberg ER, Ricker W, Kaufman R, Noller K, Herbst Al, Colton T, Hartge P (2001). Long-term cancer risk in women given diethylstilbestrol (DES) during pregnancy. British Journal of Cancer, 84: 126-133.
[8] Troisi R, Hatch EE, Titus Ernstoff L, Hyer M, Palmer JR, Robboy SJ, Strohsnitter WC, Kaufman R, Herbst AL, Hoover RN. (2007). Cancer risk in women prenatally exposed to diethylstilbestrol. International Journal of Cancer, 121: 356-360.
[9] Cohn BA, Wolff MA, Cirillo PM, Sholtz RI (2007). DDT and breast cancer in young women: New data on the significance of age at exposure. Environmental Health Perspectives, 115: 1406-1414. Available online: https://pubmed.ncbi.nlm.nih.gov/17938728/. Accessed online April 28, 2022.
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