New study is one of the first to use advanced brain imaging to reveal how exposure to these chemicals changes the brain

August 27, 2019

Science Daily/University of California - Berkeley

Prenatal exposure to the organophosphate pesticides has been linked to poorer cognition and behavior problems in children. A new study is one of the first to use advanced brain imaging to reveal how exposure can actually change brain activity. Teenagers estimated to have higher levels of prenatal exposure to organophosphates showed altered brain activity compared to their peers while performing tasks that require executive control, the study found.

Organophosphates are among the most commonly used classes of pesticides in the United States, despite mounting evidence linking prenatal exposure to the chemicals to poorer cognition and behavior problems in children.

A new study led by University of California, Berkeley, researchers is one of the first to use advanced brain imaging to reveal how exposure to these chemicals in the womb changes brain activity.

The study, which appeared this week in the journal Proceedings of the National Academy of Sciences, used functional near-infrared imaging (fNIRS) to monitor blood flow in the brains of 95 teenagers born and raised in California's Salinas Valley, where agricultural spraying of pesticides is common.

Compared to their peers, teenagers estimated to have higher levels of prenatal exposure to organophosphates showed altered brain activity while performing tasks that require executive control, the study found.

"These results are compelling, because they support what we have seen with our neuropsychological testing, which is that organophosphates impact the brain," said Sharon Sagiv, associate adjunct professor of epidemiology at UC Berkeley and lead author on the study.

The teenagers were part of the Center for the Health Assessment of Mothers and Children of Salinas (CHAMACOS), a longitudinal study examining the effects of pesticides and other environmental toxins on childhood development. The sudy was initiated by UC Berkeley investigators more than 20 years ago. Previous CHAMACOS work has linked prenatal organophosphate exposure with attention problems and lower IQ in children.

In the current study, the researchers used fNIRS to measure brain activation while teens ages 15 to 17 engaged in a variety of tasks requiring executive function, attention, social cognition and language comprehension.

The fNIRS technique uses infrared light to monitor blood flow in the outer regions, or cortex, of the brain. It provides similar information as functional magnetic resonance imaging (fMRI), but only requires a small cap of infrared light sources, rather than massive MRI tube, making it a more affordable and portable choice for research studies.

The researchers also used data from the California Pesticide Use Reporting program, which documents when and where agricultural pesticides are sprayed, to estimate their residential proximity to organophosphate application during pregnancy.

They found that teens with higher prenatal organophosphate exposure had less blood flow to the frontal cortex when engaged in tasks that test cognitive flexibility and visual working memory, and that they had more blood flow to the parietal and temporal lobes during tests of linguistic working memory.

"With fNIRS and other neuroimaging, we are seeing more directly the potential impact of organophosphate exposure on the brain, and it may be more sensitive to neurological deficit than cognitive testing," said Brenda Eskenazi, Professor of the Graduate School at UC Berkeley and senior author of the study.

Little is known about the relationship between pesticide exposure and the brain, so it's not clear why organophosphate exposure is associated with lower brain activity for some tasks and higher brain activity for others.

However, similar patterns have been observed in other conditions affecting the brain, including Type 1 diabetes, Parkinson's and Alzheimer's, said Allan L. Reiss, the Howard C. Robbins Professor of Psychiatry and Behavioral Sciences and a professor of radiology at Stanford University and co-author of the paper.

"The brain has a remarkable ability to utilize compensatory mechanisms to counteract long-term insults," Reiss said. "Higher activation may represent the recruitment and utilization of extra neural resources to address functional inefficiency related to a long-term insult, and lower activation, then, could be related to the eventual failure to recruit these resources after continued exposure or disease exhausts the brain's ability to bring compensatory responses online."

In the future, the team plans to repeat the brain imaging experiments on the more than 500 other participants in the CHAMACOS study to test if the associations hold.

https://www.sciencedaily.com/releases/2019/08/190827123626.htm

July 2, 2019

Science Daily/University of California - San Diego

Adolescents exposed to elevated levels of pesticides are at an increased risk of depression, according to a new study led by Jose R. Suarez-Lopez, MD, PhD, assistant professor in the Department of Family Medicine and Public Health at University of California San Diego School of Medicine. The study was published online (ahead of print) in June 2019 in the journal International Journal of Hygiene and Environmental Health.

Suarez-Lopez and colleagues have been tracking the development of children living near agriculture in the Ecuadorian Andes since 2008. In this latest study, they examined 529 adolescents between the ages of 11 and 17. Ecuador is the world's third-largest exporter of roses, with much of the flower production located near the homes of participants. Like many other agricultural crops, flowers are routinely sprayed with organophosphate insecticides, which are known to affect the human cholinergic system, a key system in the function of the brain and nervous system.

To test exposure levels of children, the research team measured levels of the enzyme acetylcholinesterase (AChE) in the blood. Pesticides such as organophosphates and carbamates exert their toxicity by inhibiting AChE activity. Past studies have shown that cholinesterase inhibition is linked to behaviors of anxiety and depression in mice, and a few existing studies in humans have also suggested such a link; however, pesticide exposure assessment in past studies had been only established by self-report of exposure and not using biological measures.

The results confirmed their hypothesis: teens who had lower AChE activity, suggesting greater exposure to cholinesterase inhibitors, showed more symptoms of depression assessed using a standardized depression assessment tool. Notably, the association was stronger for girls (who comprised half of all participants) and for teens younger than 14 years.

"Agricultural workers and people in these communities have long offered anecdotal reports of a rise in adolescent depression and suicidal tendencies," said Suarez-Lopez. "This is the first study to provide empirical data establishing that link using a biological marker of exposure, and it points to a need for further study."

https://www.sciencedaily.com/releases/2019/07/190702152806.htm