Motor vehicle pollution and pregnancy

The health of a mother directly affects the fetus during pregnancy. High levels of vehicle pollution where pregnant women reside can have adverse health effects on fetuses.

In the United States about 10% of the population, 33 million people, live within 900 meters of a high traffic road[1] High-traffic roads are commonly identified as being host to more than 50,000 vehicles per day, which is a source of toxic vehicle pollutants.[2] Previous studies have found correlations between exposure to vehicle pollutants and certain diseases such as asthma, lung and heart disease, and cancer among others. Car pollutants include carbon monoxide, nitrogen oxides, particulate matter (fine dusts and soot), and toxic air pollutants [3] While these pollutants affect the general health of populations, they are known to also have specific adverse effects on expectant mothers, their fetuses and children. The purpose of this article is to outline how vehicular pollutants affect the health of expectant mothers and the adverse health effects these exposure have on the adult.

Population characteristics

edit

Areas with high levels of nitrogen dioxide in the air, which is an output of vehicular air-pollution, are shown to have negative effects on fetuses. Effects of the exposure include reduced fetal growth, premature birth, and respiratory conditions. Two studies were conducted to evaluate the effects of nitrogen dioxide on fetuses in the southern United States as well as Valencia Spain. In the United States, babies that were born prematurely were 94% more likely to have been exposed to high levels of pollution than those that were not premature. In Spain, fetuses that were small for gestational age in terms of weight were 37% more likely to have been exposed to high levels of air pollution than those that were not small for gestational age in terms of weight.[4][5]

In Los Angeles County, researchers found a higher risk in premature birth (10-20%) and low birth weight for infants whose mothers lived near high traffic areas [6] Studies conducted on populations living near the 405 and 710 interstates in Southern California found their exposure to particulate vehicle emissions to be almost 25 times higher than for people living 1000 ft from the freeways. This research also concluded that particulate vehicle emissions are more toxic to children's health than other particles such as Carbon Monoxide and Nitrogen Dioxide [7][8]

Dangers of vehicle emissions

edit

Carbon monoxide

edit

Carbon monoxide (CO) is directly released from motor vehicles engines, which are a major source of this pollutant in the LA Basin[8] 5. CO inhaled by pregnant women may threaten the unborn child's growth and mental development. Because CO competes with Oxygen to achieve dispersion throughout the blood stream, fetal hypoxia (lack of oxygen) may result at high levels of maternal CO exposure, however the exact amount of exposure of CO to become a fetal threat is unknown [9] High levels of carbon monoxide are also found in cigarettes, it is advised that pregnant women avoid smoking so as to not run the risk of affecting their child's growth or mental development. For further information on Carbon Monoxide and its effects on human health please see, Carbon monoxide poisoning.

Nitrogen oxides

edit

Nitrogen oxides (NO) are common air pollutants found throughout most of the United States. You can be exposed to these oxides by breathing polluted air, which is most commonly found in areas with heavy motor vehicle traffic [10] Exposure to high levels of Nitrogen oxides damages tissues of the throat and upper respiratory tract and can interfere with the body's ability to carry oxygen. High exposure to nitrogen dioxide may cause fetal mutations, damage a developing fetus, and decrease a woman's ability to become pregnant. Studies have also shown that higher exposures to NO inhibit embryo development during both traditional pregnancies and artificial inseminations [11][12]

Particulate matter

edit

Examples of particulate matter include ash from smoke in campfires, dust particles around your house, and smoke coming from car exhaust pipes; in areas close to freeways this is a problem. A study conducted on European women indicated that higher exposure to particulate matter during the initial first weeks of their pregnancy resulted in low birth weight babies [13] This toxin is also considered to be the most dangerous of the three because it can be basically anything small enough to be inhaled. This may also be due to the fact that brain growth begins within the first month of conception.

Low-birth weight (LBW), and preterm delivery

edit

A previous study conducted in the Los Angeles Basin of Southern California reported a consistent association between levels of CO and particulate matter during the first trimester and the last six weeks prior to birth and risk of preterm birth. Prematurity in babies is accompanied by an array of health complications. Children born prematurely are at highest risk for developing Infant respiratory distress syndrome, gastrointestinal, and hematologic diseases, central nervous system (CNS) problems such as hearing loss, are more prone to infections, and at risk for hearing and vision loss.

Babies born of low weight are also at risk for respiratory, gastrointestinal, cardiac, CNS, infection and vision problems. These gestational issues persist until the adult years for most children and result in high blood pressure, Type II Diabetes, and other heart diseases.

Prematurity and Low Birth Weight caused by air pollution also affects fetal brain development. This is of importance since lack of proper brain development will not allow a child's brain to form proper synapse connections which will negatively affect the child's speech, learning abilities, and social skills.

Exposure to air pollution not only affects newborns in early stages of their development, it can also have lifelong consequences for children exposed from the time of conception to when they reach two years of age. Air pollution has been found to cause lower birth weights, insufficient development of the immune system and organs, and premature births. These birth effects have been linked to respiratory issues that can persist into one's long-term health.[14]

Long-term and short-term effects on babies

edit

Exposure to vehicle air pollutants has been noted as primary cause for infant mortality and morbidity, and is also argued to be a cause of chronic diseases such as asthma in child and adulthood [15]

Asthma

edit

The number of children affected by asthma has increased in past decades the point where it is now the most chronic illness in children and the most common cause of children hospitalizations in the U.S. causing it to also be a number one contributor to school absences[16] Excessive school absences ultimately affect the child's learning ability, and decrease their time to socialize with kids their age. It is not uncommon for children who suffer from asthma to oftentimes repeat grades due to failure to keep up academically. If students are not repeating grades they are highly likely to dropout prior to graduation over their non-affected peers.[17]

Respiratory problems

edit

Studies have found that children who are exposed to higher levels of car pollutants report higher respiratory problems including wheezing, ear and throat infections and have a higher incidence of physician-diagnosed asthma.[18][19] Bronchiolitis is also found in greater amounts when the child's home is around high amounts of traffic.[20]

Cancer

edit

Children living in close proximity to high traffic areas are also eight times more likely to develop leukemia compared to children who do not [21] This finding indicates that children who develop cancer as a result of traffic exposure will also spend more time in the hospital. This is not only a cause of school absences, but also a time of trauma for a child who is constantly visiting providers for treatment. Children with cancer have a harder time keeping up with school and keeping up with their friends [22]

Traffic exposure and autism

edit

Autism is a spectrum of disorders that range from a severe inability to communicate and some mental disabilities to milder symptoms such as attention disorders. Some claims exist that the incidence of autism is higher for babies whose mothers spend time in ‘high traffic pollution’ areas compared to mothers who spend their pregnancy in cleaner air. In a recent study conducted by UCLA, air pollutant levels were measured for mothers who had children with autism and then compared to air pollutant levels in environments for mothers who had children without autism. This study found that babies who were exposed to higher levels of pollutants while in the womb had a 10% higher risk of autism than babies who had low levels of exposure; another finding from this study is that fine particulates had the strongest association with autism [23]

Epidemiology

edit

Motor vehicle emissions are not solely a United States issue. Of the 10 cities with the most traffic, there are no cities from the United States listed.[24] The United States also has regulations regarding what and how many emissions vehicles are allowed to emit that are on the road. This is done by the USEPA and they are currently working on new regulations.[25] Of the countries that have vehicle emission standards, the European Union and Japan have the most strict regulations. These standards have been added because it is shown that regulating fuel economy is effective in controlling oil demands for the country as well as reducing their greenhouse emissions.[26]

Respiratory and allergic disorders among children in Japan were studied after the implementation of new regulations were put in place and it showed the prevalence of asthma and other respiratory disorders decreased.[27] There have also been more recent studies showing that the incidence of asthma cases worldwide is increasing in children. Much of this increase is due to the increase in NO2 which is a gas that is emitted from motor vehicles among other sources.[28]

Across the United States, vehicle emissions make up a large portion of air pollution, especially in urban areas. An epidemiological study conducted by the National Institute of Health compared pregnancy loss to local vehicle emissions, specifically nitrogen dioxide (NO₂). The study used data from Boston, Massachusetts and Tel Aviv, Israel, and both regions observed associations between pregnancy loss and NO₂, largely in the second trimester of pregnancies. This study further increases scientific confidence that vehicle emissions can be detrimental to pregnant individuals and fetuses and that these findings are consistent in different geographic locations and among different populations.[29]

See also

edit

References

edit
  1. ^ Levin, David (2012-08-16). "Big Road Blues, Air Pollution and Our Highways |". Tufts Now. Retrieved 2013-11-26.
  2. ^ "Daily Traffic". Dirty Freehub. Retrieved 2023-11-20.
  3. ^ "Traffic Exhaust Pollutants". Environmental Health Investigations Branch, California Department of Public Health. Archived from the original on 2015-09-23. Retrieved 2013-11-26.
  4. ^ Ballester, Ferran; Estarlich, Marisa; Iñiguez, Carmen; Llop, Sabrina; Ramón, Rosa; Esplugues, Ana; Lacasaña, Marina; Rebagliato, Marisa (2010-01-29). "Air pollution exposure during pregnancy and reduced birth size: a prospective birth cohort study in Valencia, Spain". Environmental Health. 9 (1): 6. Bibcode:2010EnvHe...9....6B. doi:10.1186/1476-069X-9-6. ISSN 1476-069X. PMC 2845572. PMID 20113501.
  5. ^ Jones, Sara I.; Pruszynski, Jessica E.; Spong, Catherine Y.; Nelson, David B. (October 2023). "Traffic-related air pollution is associated with spontaneous extremely preterm birth and other adverse perinatal outcomes". American Journal of Obstetrics and Gynecology. 229 (4): 455.e1–455.e7. doi:10.1016/j.ajog.2023.07.040. ISSN 0002-9378. PMID 37516397. S2CID 260294609.
  6. ^ Wilhelm, Ritz. (2002). Residential Proximity to Traffic and Adverse Birth Outcomes in Los Angeles County, California, 1994-1996. Environmental Health Perspectives. doi: 10.1289/ehp.5688
  7. ^ Zhu, Hinds, Kim, Sioutas. Concentration and size distribution of ultrafine particles near a major highway. Journal of the Air and Waste Management Association. September 2002. Zhu, Hinds, Kim, Shen, Sioutas. Study of ultrafine particles near a major highway with heavy-duty diesel traffic. Atmospheric Environment. 36(2002), 4323-4335.
  8. ^ a b Marshall JD, Riley WJ, McKone TE, Nazaroff WW: Intake fraction of primary pollutants: motor vehicle emissions in the South Coast Air Basin. Atmos Environ 2003, 37:3455-3468
  9. ^ Venditti, Carolina C.; Casselman, Richard; Smith, Graeme N. (14 December 2011). "BMC Pregnancy and Childbirth | Article Statistics |". BMC Pregnancy and Childbirth. 11 (1). BioMed Central: 101. doi:10.1186/1471-2393-11-101. PMC 3297534. PMID 22168775. S2CID 2261855.
  10. ^ "Tox Town - Nitrogen Oxides - Toxic chemicals and environmental health risks where you live and work - Text Version". National Library of Medicine. 2013-08-08. Retrieved 2013-11-26.
  11. ^ "Nitric oxide inhibits development of embryos and implantation in mice" (PDF). molehr.oxfordjournals.org. 1998. Retrieved 2019-07-23.[dead link]
  12. ^ Tillett, Tanya (April 1, 2013). "When Blood Meets Nitrogen Oxides: Pregnancy Complications and Air Pollution Exposure". Environmental Health Perspectives. 121 (4): a136. doi:10.1289/ehp.121-a136. PMC 3620769. PMID 23548775.
  13. ^ Dejmek, J., Selevan, S., Beneš, I., Solanský, I., & Šrám, R. (1999). Fetal growth and maternal exposure to particulate matter during pregnancy. Environmental Health Perspectives, 107(6), 475-480
  14. ^ Kioumourtzoglou, Marianthi-Anna; Raz, Raanan; Wilson, Ander; Fluss, Ronen; Nirel, Ronit; Broday, David M.; Yuval; Hacker, Michele R.; McElrath, Thomas F.; Grotto, Itamar; Koutrakis, Petros; Weisskopf, Marc G. (January 2019). "Traffic-related Air Pollution and Pregnancy Loss". Epidemiology. 30 (1): 4–10. doi:10.1097/EDE.0000000000000918. ISSN 1044-3983. PMC 6269216. PMID 30199416.
  15. ^ Dollfus C, Patetta M, Siegel E, Cross AW. Infant mortality: a practical approach to the analysis of the leading causes of death and risk factors. Pediatrics 1990; 86:176–183
  16. ^ Gasana, J., Dillikar, D., Mendy, A., Forno, E., & Ramos Vieira, E. (2012). Motor vehicle air pollution and asthma in children: A meta-analysis. Environmental Research, 117, 36-45
  17. ^ Moonie, Sheniz A.; Sterling, David A.; Figgs, Larry; Castro, Mario (January 2006). the%20causes%20are%20inadequately%20documented. "Asthma status and severity affects missed school days". The Journal of School Health. 76 (1): 18–24. doi:10.1111/j.1746-1561.2006.00062.x. ISSN 0022-4391. PMID 16457681. {{cite journal}}: Check |url= value (help)
  18. ^ Holst, Gitte J.; Pedersen, Carsten B.; Thygesen, Malene; Brandt, Jørgen; Geels, Camilla; Bønløkke, Jakob H.; Sigsgaard, Torben (2020-08-19). "Air pollution and family related determinants of asthma onset and persistent wheezing in children: nationwide case-control study". BMJ. 370: m2791. doi:10.1136/bmj.m2791. ISSN 1756-1833. PMC 7437497. PMID 32816747. S2CID 221177828.
  19. ^ Potera, Carol (September 2006). "Heavy Traffic Can Be a Pain in the . . . Ear?: Vehicle Emissions Linked to Otitis Media". Environmental Health Perspectives. 114 (9): A544. doi:10.1289/ehp.114-a544b. ISSN 0091-6765. PMC 1570094.
  20. ^ Ruffles, Tom; Inglis, Sarah K.; Memon, Anjum; Seddon, Paul; Basu, Kaninika; Bremner, Stephen A.; Rabe, Heike; Tavendale, Roger; Palmer, Colin N. A.; Mukhopadhyay, Somnath; Fidler, Katy J. (2023-09-10). "Environmental risk factors for respiratory infection and wheeze in young children: A multicentre birth cohort study". Pediatric Pulmonology. 59 (1): 19–30. doi:10.1002/ppul.26664. ISSN 8755-6863. PMID 37690457. S2CID 261680649.
  21. ^ Vinceti, M., Rothman, K., Crespi, C., Sterni, A., Cherubini, A., et al. (2012). Leukemia risk in children exposed to benzene and pm10 from vehicular traffic: A case-control study in an italian population. European Journal of Epidemiology, 27(10), 781
  22. ^ Anonymous,. (2012). Awareness week highlights effects of cancer on young children. Cancer Nursing Practice, 11(10), 5
  23. ^ Becerra, T., Wilhelm, M., Olsen, J., Cockburn, M., & Ritz, B. (2013). Ambient air pollution and autism in los angeles county, california. Environmental Health Perspectives, 121(3), 380-386
  24. ^ "10 Cities with the Worst Traffic in the World - Ranked 2023". GeeksforGeeks. 2023-09-05. Retrieved 2023-11-20.
  25. ^ USEPA. "Regulations for Greenhouse Gas Emissions from Passenger Cars and Trucks".
  26. ^ "Comparison of Passenger Vehicle Fuel Economy and GHG Emission Standards Around the World". Center for Climate and Energy Solutions. Retrieved 2023-11-20.
  27. ^ Hasunuma, Hideki; Ishimaru, Yasushi; Yoda, Yoshiko; Shima, Masayuki (May 2014). "Decline of ambient air pollution levels due to measures to control automobile emissions and effects on the prevalence of respiratory and allergic disorders among children in Japan". Environmental Research. 131: 111–118. Bibcode:2014ER....131..111H. doi:10.1016/j.envres.2014.03.007. ISSN 1096-0953. PMID 24727639.
  28. ^ "Nearly 2 Million Children Worldwide Develop Asthma as a Result of Breathing in Traffic- Related Pollution | Milken Institute School of Public Health | The George Washington University". Milken Institute School of Public Health. Retrieved 2023-11-20.
  29. ^ Rani, Prerna; Dhok, Archana (2023-01-18). "Effects of Pollution on Pregnancy and Infants". Cureus. 15 (1): e33906. doi:10.7759/cureus.33906. ISSN 2168-8184. PMC 9937639. PMID 36819435.
edit