Autism among U.S. children has reached epidemic proportion. And it's getting worse by the year.
Since the '70's, there has been a 60-fold increase in American children with autism. The latest CDC data shows that currently 1 in every 100 U.S. children, and 1 in every 58 boys, are being diagnosed with autism. According to statistics from the most recent (2007) National Survey of Children (from HRSA of HHS), the the odds of a child in the U.S. receiving an Autism Spectrum Disorder diagnosis are 1 in 63, and go up to 1 in 38 for boys. That's over 2.6 percent of all male children in America. Autism Spectrum Disorder (ASD) includes Autism (classic), Asperger syndrome and Pervasive Development Disorder.
The number of autistic children expected to reach adulthood
in the next 10 years along with their caregivers will exceed the population of
Rhode Island and cost an estimated $27 billion in additional care beyond the
almost $60 billion being spent on current autism-related costs. (1,2)
Under the specter of an autism epidemic sweeping America, Senator Barbara Boxer (CA) convened hearings last week on the "State of Research on Potential Environmental Health Factors with Autism." (3)
Experts agree that the primary explanation for the dramatic increase in autism is toxic environmental exposure and gene-environment interactions. New research shows that even low-dose, multiple toxic and infectious exposures may be a key factor to the onset of autism.
One expert, Dr. Linda Birnbaum, Director of the National Institute of Environmental Health, testified that "Research supported by NIEH has clearly shown that it is not just genetics that causes neuro-developmental disorders such as autism but rather the interplay of both genes and the environment".
Dr. Birnbaum also stated that NIEH has uncovered information on the role that early environmental exposures play in the development of a broad spectrum of childhood disorders, including not only autism but also ADHD, and other learning disorders.
Another expert, Dr. Paul Anastas, the U.S.Environmental
Protection Agency's assistant administrator, told the subcommittee that children
are especially susceptible to the effects of chemicals in the environment
because they eat, drink and breathe in more for their body weight than adults.
They absorb a greater proportion of many chemicals in the environment than
adults, and due to hand to mouth behaviors, young children tend to have higher
exposures to contaminants, such as pollutants in the surrounding air and dust,
deposited from lead paint, tobacco smoke, cleaning products, pesticides and
other chemicals. (4,5)
We already know that prenatal and early childhood exposures to chemicals such as methyl mercury (commonly found in fish) ethyl-mercury (previously found in many childhood vaccines as part of a preservative, Thimerosla and currently contained in many flu vaccines although there are thimerosal free ones available), lead (in paints), PCBs (in plastics such as baby bottles and food storage containers) and arsenic (in the air) can affect development of the nervous system and lead to developmental disability. (6,7,8)
Also, the developing brain and nervous system can be disrupted by much lower levels of environmental exposures than would affect adults. (9,10,11) You can read about the current levels of exposure in the just released CDC's National Report on Human Exposure to Environmental Chemicals, a frightening document.
Dr. Isaac Pessah, Director of the UC Davis Center for Children's Environmental Health, testified that many of the molecular and cellular systems associated with autism are the same ones that are the target of environmental chemicals currently of concern to human health because of their widespread use. He spoke of a critical need to identify which chemicals in the environment influence the same biological pathways that are effected in autism. Dr. Pessah said that limiting exposure to these chemicals is the only way to mitigate or prevent autism in susceptible individuals.
Increasingly, evidence links even chronic, low-level exposure to industrial pollutants to many of the most prevalent and disabling learning and behavioral problems in children.
Professor Bruce Lanphear Ph.D, of the Child & Family Research Institute, Simon Fraser University, reported that some of the most widely dispersed environmental toxicants, even at very low levels are risk factors for the "new morbidities" of childhood -- both intellectual and behavioral impairments such as autism. Indeed, there is often no apparent threshold -- in some cases the effects appear to be greater at the lowest levels of exposure. (12) Emerging evidence shows that a whole host of new environmental chemicals such as Bisphenol A, (the protective inner lining in tin cans and baby bottles) PBDEs, pesticides, phthalates and airborne pollutants are all associated with intellectual deficits or behavioral problems in children. (13,14,15)
Just prior to the Senate hearing, several important research papers were published that further documented the relationship between environmental toxins and autism:
• A study in India correlated the increased body burdens of lead and mercury with the severity of children's autism -- the more severe the autism, the higher concentrations of heavy metals were found in their bodies. (16)
• An exhaustive scientific literature search just completed in August shows that the link between autism and toxic exposures in infants is supported by current published research. (17)
My own recent study of a large autistic clinical database shows that children with autism had elevated levels in their bodies of several chemicals known to be neurotoxic. The children have genetic variations, which interfere with the proper detoxification of those chemicals. With over 2,000 patients in the database, my paper is one of the largest studies to show that environmental factors interacting with associated genetic components may be contributing to the causation of autism.
Development of the human nervous system begins in the womb and extends throughout childhood. During these periods of rapid development, the brain is vulnerable to some environmental exposures, which may have the potential to disrupt the chemical signals that organize development. Even small changes can have potentially major consequences for brain structure and function. Thus, even brief adverse exposure at these vulnerable stages can have lasting effects on brain function throughout life.
My report showed on average the amount of lead and mercury in the children's blood was 50 percent higher than normal. Their genetic changes (SNPs) were related to what is called Phase I and Phase II detoxification -- specifically the CYP and GST family of genes. This defect reduced the children's ability to remove excess toxins from their bodies.
These autistic children also had a several fold higher level of bad gut bacteria and reduced levels of beneficial gut bacteria. Bad gut bacteria can produce neurotoxic amines and cause a "leaky gut" which allows toxic substances to more easily enter the circulatory system (see my previous Huffington Post entry "The Keys to Maintaining a Healthy Gut").
You may read the full clinical study here: http://personalizedmedicine.posterous.com/environmental-factors-contributing-to-the-ons#
We as a society have a toxic chemical addiction, which we
need to kick now. We need to be better informed consumers -- choosing chemically
free foods, products and environments, affecting change with our wallets.
Here are some Toxic Exposure Avoidance Tips for All of Us -- And Especially For Pregnant Women. Start taking them, right now:
- Avoid eating foods that may contain high levels of toxic chemicals
- While fish are a good source of protein and omega-3 fatty acids, some contain high levels of mercury. Tuna (especially white or albacore), Cod and Mahi Mahi are ones to avoid. Wild salmon is a good healthy choice. See americanpregnancy.org for an excellent chart showing levels of mercury in the most commonly ingested fish.
- Consume organic foods and drinks as much as possible.
- Use glass containers instead of plastic to store left over foods and drinks.
- Reduce our purchase of foods in cans as the can lining contains high levels of Bisphenol A (an endocrine disrupter linked to increased rates of cancer and abnormal behavior in children).
- Limit exposure to toxic household chemicals, pesticides and cleaning supplies. Look for natural alternatives.
- Install HEPA and carbon filter air purifiers in bedrooms to insure a healthy toxin free nights rest
Exposure to toxic chemicals by pregnant women, fetuses and children has a high probability of causing autism and other neuro-developmental disorders and learning disabilities in those whose genetic profile expresses in a reduced ability to detoxify these chemicals. This is not "fringe" science; it's fact.
The time for action is now. We must reduce our exposure to toxic chemicals for ourselves, for our children's sake and for future generations.
We have a responsibility to protect those who cannot protect themselves. We cannot afford to be incurious, indifferent or uninformed when the price of inattention is disability and heartache -- an overwhelming emotional and financial burden to families and society.
Ask for help: Tell your government that we must lessen our exposure to these chemicals. For the future of all Americans. Email or call your own representatives. Senator Boxer can be reached at: email@example.com.
Please share your thoughts by adding a comment below.
In good health,
(1) Autism Society of America (ASA). 2003. Facts and
(2) Pennsylvania Department of Public Welfate. 2005 PA Autism Census Project: Final Report; Oct 2009
(3) US Senate Subcommittee on Environment and Public Works. Aug 2010
(4) National Research Council. 1993. Pesticides in the Diets of Infants and Children. National Academy of Sciences Press, Washington, DC.
(5) U.S. Environmental Protection Agency (EPA). 2005 Guidance on selecting age groups for monitoring and assessing childhood exposures to environmental contaminants. National Center for Environmental Assessment, Washington, DC; EPA/630/P-03/003F
(6) Wasserman GA, Liu X, Parvez F, Ahsan H, Factor-Litvak P, Kline J, van Geen A, Slavkovich V, Loiacono NJ, Levy D, Cheng Z, Graziano JH. 2007. Water arsenic exposure and intellectual function in 6-year-old children in Araihazar, Bangladesh. Environ Health Perspect. 115(2):285-9
(7) Landrigan PJ, Whitworth RH, Baloh RW, Barthel WF, Staehling NW, Rosenblum BF. 1975. Neuropsychological dysfunction in children with chronic low-level lead absorption. Lancet 1:708-712
(8) Rogan WJ, Ware JH. 2003. Exposure to lead in children - how low is low enough? N Engl J Med. 348:1515-1516
(9)(ATSDR). 2007. Toxicological profile for Lead. Atlanta, GA: U.S. Department of Health and Human Services, Public Health Service. http://www.atsdr.cdc.gov/ToxProfiles/tp13-c3.pdf
(10) Grandjean P, and Landrigan PJ. 2006. Developmental neurotoxicity of industrial chemicals. Lancet.;368(9553):2167-78.
(11) Jett DA, Kuhlmann AC, Farmer SJ, Guilarte TR.1997. Age-dependent effects of developmental lead exposure on performance in the Morris water maze. Pharmacol Biochem Behav.57(1-2):271-9
(12) Canfield RL, Henderson CR, Cory-Slechta DA, Cox C, Jusko TA, Lanphear BP. Intellectual impairment in children with blood lead concentrations below 10 micrograms per deciliter. N Engl J Med 2003;348:1517-1526
(13) Eskenazi B, Marks AR, Bradman A, et al. Organophosphate pesticide exposure and neurodevelopment in young Mexican-American children. Environ Health Perspect 2007;115:792-798
(14) Herbstman JB, Sjödin A, Kurzon M, et al. Prenatal exposure to PBDEs and neuro-development. Environ Health Perspect 2010;118:712-719
(15) Braun JM, Froehlich TE, Daniels JL, et al. Association of environmental toxicants and conduct disorder in U.S. children: NHANES 2001-2004. Environ Health Perspect 2008;116:956-962
(16) Priya MD. Level of Trace Elements (Copper, Zinc, Magnesium
and Selenium) and Toxic Elements (Lead and Mercury)
in the Hair and Nail of Children with Autism. Biol Trace Elem Res
(17) DeSoto MC. Sorting out the spinning of autism: heavy metals and the
question of incidence. Acta Neurobiol Exp 2010, 70: 165-176