Posts tagged air pollution
Articles and news from the latest research reports.
Researcher adds to evidence linking autism to air pollutants
A researcher at the University of Wisconsin-Milwaukee (UWM) has added to a growing body of evidence that links autism to air pollutants such as those generated by cars and trucks.
Amy Kalkbrenner’s study, published this week online at the journal Epidemiology, showed that pollution’s impact on autism rates in North Carolina is similar to results of pollution-autism studies in California – despite weather and climate differences between the two states.
In addition, the work of Kalkbrenner and her colleagues, building on previous studies, showed that women in the third trimester of pregnancy were more susceptible to the damaging effects of air pollution on their unborn child.
“It adds another piece supporting the hypothesis that environmental chemicals are part of the autism puzzle,” says Kalkbrenner, an assistant professor in UWM’s Joseph J. Zilber School of Public Health. Autism, a spectrum of disorders affecting interpersonal relations and work achievement, now affects some 1 in 68 children in the U.S.
Her research team focused on exposure to coarse and fine particulate matter, known as PM10, which arises in part from traffic-related air pollution. The study evaluated records in the two states, covering pre-conception through the first birthday for 87,000 children in North Carolina and 77,500 in California born in the mid-to-late 1990s. Key regions in each state were selected based on researchers’ ability to simultaneously measure the level of particulate matter present, and know which children had autism in these regions.
Researchers used a new, more exact tool to measure the levels of particulate matter in smaller slices of time, based on pollution at the family’s address during pregnancy. With this method, they were able to compare exposures during specific weeks of pregnancy. The approximately one thousand children who later developed some form of autism spectrum disorders were then compared to all other children.
Kalkbrenner says it was important to look at eastern states because of the differences in climate, seasonal weather patterns and the chemical make-up of the particulate matter that might impact brain development. “Evidence for a link between a chemical exposure and a health impact like autism is stronger when it can be shown in more than one region.” The team found that the concentration of particulate matter was highest among children born in summer months in North Carolina and those born in fall and winter months in California.
Reasons for increased susceptibility in the third trimester of pregnancy are not known at this time. However, Kalkbrenner says this finding is consistent with theories that show links between autism and altered brain network development, specifically synaptic connections that are developing during the final months of pregnancy.
“We’ve now had three solid studies saying the same thing. The evidence is pretty compelling that something is going on with air pollution and autism,” says Kalkbrenner, who adds that further study is needed to determine the neurodevelopmental impacts of specific chemical pollutants during precise developmental windows.
(Source: www5.uwm.edu)
Study Finds Air Pollution Harmful to Young Brains
Pollution in many cities threatens the brain development in children.
Findings by University of Montana Professor Dr. Lilian Calderón-Garcidueñas, MA, MD, Ph.D., and her team of researchers reveal that children living in megacities are at increased risk for brain inflammation and neurodegenerative changes, including Alzheimer’s or Parkinson’s disease.
Calderón-Garcidueñas’ findings are detailed in a paper titled “Air pollution and children: Neural and tight junction antibodies and combustion metals, the role of barrier breakdown and brain immunity in neurodegeneration,” which can be found online at http://iospress.metapress.com/content/xx6582688105j48h/.
The study found when air particulate matter and their components such as metals are inhaled or swallowed, they pass through damaged barriers, including respiratory, gastrointestinal and the blood-brain barriers and can result in long-lasting harmful effects.
Calderón-Garcidueñas and her team compared 58 serum and cerebrospinal fluid samples from a control group living in a low-pollution city and matched them by age, gender, socioeconomic status, education and education levels achieved by their parents to 81 children living in Mexico City.
The results found that the children living in Mexico City had significantly higher serum and cerebrospinal fluid levels of autoantibodies against key tight-junction and neural proteins, as well as combustion-related metals.
“We asked why a clinically healthy kid is making autoantibodies against their own brain components,” Calderón-Garcidueñas said. “That is indicative of damage to barriers that keep antigens and neurotoxins away from the brain. Brain autoantibodies are one of the features in the brains of people who have neuroinflammatory diseases like multiple sclerosis.”
The issue is important and relevant for one reason, she explained. The breakdown of the blood-brain barrier and the presence of autoantibodies to important brain proteins will contribute to the neuroinflammation observed in urban children and raises the question of what role air pollution plays in a 400 percent increase of MS cases in Mexico City, making it one of the main diagnoses for neurology referrals.
Calderón-Garcidueñas points out that there is a need for a longitudinal follow-up study to determine if there is a relationship between the cognition deficits and brain MRI alterations previously reported in Mexico City children, and their autoimmune responses. But what is clear is that the kids are suffering from immune dysregulation.
Once there is a breakdown in the blood-brain barrier, not only will particulate matter enter the body but it also opens the door to harmful neurotoxins, bacteria and viruses.
“The barriers are there for a reason,” she explains. “They are there to protect you, but once they are broken the expected results are not good.”
The results of constant exposure to air pollution and the constant damage to all barriers eventually result in significant consequences later in life. She explains that the autoimmune responses are potentially contributing to the neuroinflammatory and Alzheimer’s and Parkinson’s pathology they are observing in young urban children.
While the study focused on children living in Mexico City, others living in cities where there are alarming levels of air pollution such as Los Angeles, Philadelphia-Wilmington, New York City, Salt Lake City, Chicago, Tokyo, Mumbai, New Delhi or Shanghai, among others, also face major health risks. In the U.S. alone, 200 million people live in areas where pollutants such as ozone and fine particulate matter exceed the standards.
“Investing in defining the central nervous system pathology associated with exposure to air pollutants in children is of pressing importance for public health,” Calderón-Garcidueñas said.
The full article is scheduled to be published in Volume 43, Issue 3 of the Journal of Alzheimer’s Disease and will appear online at http://www.j-alz.com in December with a 2015 copyright.
(Source: news.umt.edu)
New Evidence Links Air Pollution to Autism, Schizophrenia
New research from the University of Rochester Medical Center describes how exposure to air pollution early in life produces harmful changes in the brains of mice, including an enlargement of part of the brain that is seen in humans who have autism and schizophrenia.
As in autism and schizophrenia, the changes occurred predominately in males. The mice also performed poorly in tests of short-term memory, learning ability, and impulsivity.
The new findings are consistent with several recent studies that have shown a link between air pollution and autism in children. Most notably, a 2013 study in JAMA Psychiatry reported that children who lived in areas with high levels of traffic-related air pollution during their first year of life were three times as likely to develop autism.
“Our findings add to the growing body of evidence that air pollution may play a role in autism, as well as in other neurodevelopmental disorders,” said Deborah Cory-Slechta, Ph.D., professor of Environmental Medicine at the University of Rochester and lead author of the study, published in the journal Environmental Health Perspectives.
In three sets of experiments, Cory-Slechta and her colleagues exposed mice to levels of air pollution typically found in mid-sized U.S. cities during rush hour. The exposures were conducted during the first two weeks after birth, a critical time in the brain’s development. The mice were exposed to polluted air for four hours each day for two four-day periods.
In one group of mice, the brains were examined 24 hours after the final pollution exposure. In all of those mice, inflammation was rampant throughout the brain, and the lateral ventricles — chambers on each side of the brain that contain cerebrospinal fluid — were enlarged two-to-three times their normal size.
“When we looked closely at the ventricles, we could see that the white matter that normally surrounds them hadn’t fully developed,” said Cory-Slechta. “It appears that inflammation had damaged those brain cells and prevented that region of the brain from developing, and the ventricles simply expanded to fill the space.”
The problems were also observed in a second group of mice 40 days after exposure and in another group 270 days after exposure, indicating that the damage to the brain was permanent. Brains of mice in all three groups also had elevated levels of glutamate, a neurotransmitter, which is also seen in humans with autism and schizophrenia.
Most air pollution is made up mainly of carbon particles that are produced when fuel is burned by power plants, factories, and cars. For decades, research on the health effects of air pollution has focused on the part of the body where the damage is most obvious — the lungs. That research began to show that different-sized particles produce different effects. Larger particles — the ones regulated by the Environmental Protection Agency (EPA) — are actually the least harmful because they are coughed up and expelled. But many researchers believe that smaller particles known as ultrafine particles — which are not regulated by the EPA — are more dangerous, because they are small enough to travel deep into the lungs and be absorbed into the bloodstream, where they can produce toxic effects throughout the body.
That assumption led Cory-Slechta to design a set of experiments that would show whether ultrafine particles have a damaging effect on the brain, and if so, to reveal the mechanism by which they inflict harm. Her study published today is the first scientific work to do both.
“I think these findings are going to raise new questions about whether the current regulatory standards for air quality are sufficient to protect our children,” said Cory-Slechta.
(Source: urmc.rochester.edu)
Environmentally sensitive cells with a Hulk-like rage
Human exposure to urban air pollution may trigger toxic responses in brain cells and impact neurodegenerative disease pathways
From diesel exhaust to gaseous pollutants and suspended particulate matter, such as dust, smoke and fumes, air pollution from transportation, industry and energy generation has taken a toll on the environment and human health.
While the adverse effects of air pollution on the cardiovascular and respiratory systems have been well documented, little is known about how the associated toxins may impact the brain and the central nervous system. In recent years, experts have reported a marked rise in the prevalence of stroke, autism and cognitive decline in the elderly.
Researchers such as Michelle Block, Ph.D., associate professor in the Department of Anatomy and Neurobiology in the Virginia Commonwealth University School of Medicine, are now on a mission to define the impact of air pollution on the brain and central nervous system.
Through basic science, Block and her team are working to understand the underlying molecular mechanisms in hopes of developing an intervention that can protect human health.
Recent scientific reports suggest air pollution exposure and the activation of a specific group of cells found in the brain being studied in Block’s laboratory may play a role in the increased incidence of central nervous system diseases and neurological conditions. They have observed that these factors may also impact the neurodegenerative disease process.
Last week, Block, presented her team’s significant research findings to peers from across the country during a symposium she co-organized at the 2014 annual meeting of the American Association for the Advancement of Science, held in Chicago, from Feb. 13 to 17.
“Angry” cells, toxic responses
Block’s research examines microglia, a group of resident immune cells found in the brain and spinal cord, which can display a kind of dual personality – one good, and the other bad if agitated.
Under normal conditions, microglia primarily serve as the defenders of the central nervous system. They bring balance to the system. They destroy infectious agents, engulf various unwanted cellular and foreign materials and promote regrowth of damaged neural tissue.
But microglia can be dangerous when they are exceptionally “angry” and are known to leave behind significant bystander damage to neighboring cells. This adverse behavior may lead to the development of any number of neurodegenerative diseases, including Parkinson’s disease, Alzheimer’s disease, or Gulf War Illness.
In some ways, microglia are similar to misunderstood superhero The Incredible Hulk. Despite having a decent-sized heart and extraordinary abilities to help save the day, nobody wants to stir his rage and anger.
Block’s laboratory specializes in understanding the cellular and molecular machinery responsible for essentially fueling microglia “anger” – why they become chronically and excessively activated to drive damage in the brain.
“Our goal is to define how microglia detect and respond to air pollution, reveal when this microglial response may actually be damaging the brain, identify potential markers of ongoing silent neuropathology and ultimately use the mechanistic information we acquire as a tool to halt the induced or augmented neuropathology,” Block said.
In several peer-reviewed, published reports, Block and her colleagues have demonstrated that exposure to a diverse source of urban air pollution can trigger toxic microglial responses and impact neurodegenerative disease pathways.
“Given the prevalence of human exposure to urban air pollution above safety regulations, it is critical to understand the underlying mechanisms through which air pollution affects the brain,” Block said. “We hope to find an opportunity to intervene and protect human central nervous system health.”
According to Block, her team’s work shows that many components of urban air pollution, including the particle components of air pollution, also called particulate matter, and gases, such as ground level ozone, activate microglia.
Some of the problems with this cell type come in when the same molecular tools used by microglia internalize (eat) and clean up toxic stimuli and accidentally trigger the switch to an excessive, angry activation state. The work she presented reveals how air pollution does this, essentially leaving microglia with much more than a mouthful. Her lab has discovered that the MAC1 pattern recognition receptor may be a common mechanism through which microglia detect and ultimately misinterpret different forms of air pollution as an invading pathogen to result in excessive production of reactive oxygen species and consequent damage to neighboring brain cells.
Further, ongoing research in Block’s lab aims to define where damage to the lungs through inhaled toxicants produces injury signals in the circulation that are not only detected by microglia in the brain, but are responsible for shifting microglia to a deleterious phenotype impacting central nervous system health. She refers to this as a “Lung-Brain Axis.”
Air pollution and genetics combine to increase risk for autism
Exposure to air pollution appears to increase the risk for autism among people who carry a genetic disposition for the neurodevelopmental disorder, according to newly published research led by scientists at the Keck School of Medicine of the University of Southern California (USC).
"Our research shows that children with both the risk genotype and exposure to high air pollutant levels were at increased risk of autism spectrum disorder compared to those without the risk genotype and lower air pollution exposure," said the study’s first author, Heather E. Volk, Ph.D., M.P.H., assistant professor of research in preventive medicine and pediatrics at the Keck School of Medicine of USC and principal investigator at The Saban Research Institute of Children’s Hospital Los Angeles.
The study, “Autism spectrum disorder: Interaction of air pollution with the MET receptor tyrosine kinase gene,” is scheduled to appear in the January 2014 edition of Epidemiology.
Autism spectrum disorder (ASD) is a lifelong neurodevelopmental disability characterized by problems with social interaction, communication and repetitive behaviors. The Centers for Disease Control and Prevention estimates that one in 88 children in the United States has an ASD.
ASD is highly heritable, suggesting that genetics are an important contributing factor, but many questions about its causes remain. There currently is no cure for the disorder.
"Although gene-environment interactions are widely believed to contribute to autism risk, this is the first demonstration of a specific interaction between a well-established genetic risk factor and an environmental factor that independently contribute to autism risk," said Daniel B. Campbell, Ph.D., assistant professor of psychiatry and the behavioral sciences at the Keck School of Medicine of USC and the study’s senior author. "The MET gene variant has been associated with autism in multiple studies, controls expression of MET protein in both the brain and the immune system, and predicts altered brain structure and function. It will be important to replicate this finding and to determine the mechanisms by which these genetic and environmental factors interact to increase the risk for autism."
Independent studies by Volk and Campbell have previously reported associations between autism and air pollution exposure and between autism and a variant in the MET gene. The current study suggests that air pollution exposure and the genetic variant interact to augment the risk of ASD.
Campbell and Volk’s team studied 408 children between 2 and 5 years of age from the Childhood Autism Risks From Genetics and the Environment Study, a population-based, case-control study of preschool children from California. Of those, 252 met the criteria for autism or autism spectrum disorder. Air pollution exposure was determined based on the past residences of the children and their mothers, local traffic-related sources, and regional air quality measures. MET genotype was determined through blood sampling.
Campbell and Volk continue to study the interaction of air pollution exposure and the MET genotype in mothers during pregnancy.
(Source: eurekalert.org)