Planting Healthier Indoor Air
2011; National Institute of Environmental Health Sciences; Volume: 119; Issue: 10 Linguagem: Inglês
10.1289/ehp.119-a426
ISSN1552-9924
Autores Tópico(s)Noise Effects and Management
ResumoVol. 119, No. 10 News | ForumOpen AccessPlanting Healthier Indoor Air Luz Claudio Luz Claudio Published:1 October 2011https://doi.org/10.1289/ehp.119-a426Cited by:18AboutSectionsPDF ToolsDownload CitationsTrack Citations ShareShare onFacebookTwitterLinked InReddit Poor indoor air quality has been linked to health problems, especially in children. Asthma has reached epidemic proportions among multiple age groups and is considered the most common chronic disease in urban-dwelling children.1 The American Academy of Allergy, Asthma and Immunology Indoor Allergen Committee suggested in a 2010 report that allergists consider indoor air filtration to be part of a comprehensive strategy to improve respiratory health.2 Air cleaners with HEPA filters have been shown to improve symptoms of asthma.2 However, filtration systems and air purifiers do not reduce levels of all indoor air pollutants, and some types can actually aggravate the problem. For example, one study showed that some air purifiers raise indoor concentrations of ozone above safety levels established by the U.S. Environmental Protection Agency.3A more benign addition to air filtration could be the use of houseplants. In addition to basic photosynthesis that removes carbon dioxide and returns oxygen to the air, plants can remove toxicants from air, soil, and water in at least two ways. First, they can metabolize some toxic chemicals, releasing harmless by-products, and second, they can incorporate toxicants such as heavy metals into plant tissues, thus sequestering them.Data on plant-mediated indoor air quality come from experiments conducted by the U.S. National Aeronautics and Space Administration (NASA). As NASA researchers explored the possibilities of long-term space habitation, it became evident that the air in a tightly sealed space capsule would quickly become contaminated with volatile organic compounds (VOCs) and other chemicals released by the materials used to manufacture the capsule interior.4This is similar to the situation in newly constructed energy-efficient dwellings. If energy-efficient construction is not carefully designed to maintain indoor–outdoor air exchange, one unintended consequence can be increased concentrations of pollutants indoors. For example, in a study recently published in the American Journal of Public Health, Gary Adamkiewicz and colleagues used a simulation model to demonstrate that in homes with low air exchange rates and multiple sources of air pollution, up to 90% of exposure to fine particulate matter came from indoor sources.5 Besides particles and VOCs, indoor air and dust can also contain brominated flame retardants, pesticides, toxic metals, and other pollutants.6For more than 30 years, B.C. "Bill" Wolverton, a retired civilian scientist for NASA, investigated the use of plants as air- and water-purifying systems for enclosed environments in space missions. Through his research, Wolverton found the air-cleaning capacity of houseplants can be improved exponentially by increasing air circulation to the roots of the plants, where symbiotic microorganisms help make the substances culled from air bioavailable to the plant.For maximum benefit, multiple species of houseplants would likely be needed on a site to remove the relevant toxicants in a particular space, given that houseplants vary in the types of chemicals they are able to remove from the environment and the efficiency with which they do their work. "For effective phytoremediation, the number and type of plants selected would need to be tailored to each individual building," says Stanley J. Kays of the University of Georgia.Shutterstock.comIn those studies, Wolverton and colleagues tested several types of low-light houseplants.7 For example, golden pothos (Epipremnum aureum, also known as devil's ivy) grown on an activated carbon filter system reduced air levels of benzene and trichloroethylene inside a Plexiglas chamber measuring 0.58 cubic yard from approximately 36 ppm to barely detectable levels within 2 hours.4 Experiments conducted elsewhere by Stanley J. Kays and colleagues at the University of Georgia also documented the ability of different plant species to remove VOCs such as benzene, toluene, octane, and trichloroethylene.8One indoor contaminant of particular concern is formaldehyde, which is released by many household products, among them pressed woods, some types of foam insulation, paper products, some paints and varnishes, and permanent-press fabrics. The National Toxicology Program lists formaldehyde as reasonably anticipated to be a human carcinogen.9In an unpublished 2006 study, Wolverton tested a small fan-assisted planter/air filter inside a travel trailer that had been used as temporary housing for displaced Hurricane Katrina victims. This trailer, like similar units, had been found to be highly contaminated with formaldehyde. The plant/air filter contained a plant growing in a mixture of activated carbon and expanded clay pebbles. Wolverton's tests showed that the levels of formaldehyde were reduced from potentially toxic levels of 0.18 ppm to 0.03 ppm, within the safety limits defined by the World Health Organization.10Those studies fit well with evidence on the biochemical mechanisms involved in plant detoxification of formaldehyde. In studies published this year Zhongjun Xu and colleagues tested three kinds of potted plants for their capacity to remove formaldehyde from indoor air in test chambers. They found that the formaldehyde-removal capacity of the plants depended on the dehydrogenase activity in the leaves and root system—that is, how efficiently the plant could metabolize formaldehyde.11 As Wolverton found earlier, these investigators also found that formaldehyde removal by plants was diffusion-limited. That means increasing the circulation of contaminated air through the root system and leaves improved the formaldehyde-removal effect.Top 10 Houseplant Air CleanersBased on an assessment17 of 50 houseplants by four criteria: 1) removal of chemical vapors, 2) ease of growth and maintenance, 3) resistance to insect infestation, and 4) transpiration rates. Wolverton says studies suggest houseplants are most effective in removing VOCs in energyefficient, nonventilated buildings; in highly ventilated buildings, the rapid exchange of inside and outside air makes the benefits of houseplants mostly limited to their psychologic and aesthetic values.Shutterstock.comIn another recent study, Kays and colleagues tested 86 species of houseplants from five general classes for their ability to remove formaldehyde. In their experiments, ferns had the highest formaldehyde-removal efficiency of all the plants tested, especially Osmunda japonica, commonly known as Japanese royal fern, or zenmai.12Another important air contaminant that is amenable to plants' cleanup abilities is mercury vapor. Mercury can make its way into homes through accidental spills (for instance, breakage of thermometers and fluorescent bulbs) as well as through its use in certain cultural and religious practices.13 Mercury vapor is neurotoxic and lingers in the air even after new sources have been eliminated from the environment.14Joao Paulo Machado Torres, a senior scientist at the Radioisotopes Laboratory of the Federal University of Rio de Janeiro, Brazil, and his group have published many studies on the use of plants in indoor and outdoor mercury-contaminated settings.15 "We have used plants of the bromeliad family and Spanish moss (Tillandsia usneoides) as sentinel species to detect and absorb mercury from the air in shops contaminated by the gold trade in the Amazon," he says. The use of plants can be uniquely useful in these environments where other kinds of remediation technology may be impractical or difficult to deploy.But as has been shown with many natural remedies, "natural" does not necessarily equate to "absolutely harmless." A study by Kays and colleagues published in 2009 pointed out that some houseplants—as well as the media and plastic pots they are grown in, the microorganisms that inhabit them, and the pesticides used to treat them—can potentially contaminate indoor air with VOCs.16 "It is not yet possible to project the true potential of plants for purifying indoor air," Kays says. "At this time the role of plants, though appearing [generally] positive, is not totally clear. The absence of funding for phytoremediation research has greatly impeded solving the problem."Kays also notes the lack of an accurate means for the public to determine if the VOCs in their home or office represent a significant health problem. "The absence of a relatively inexpensive method available to the public results in situations where it takes two and a half years to determine that the Katrina trailers had toxic levels of formaldehyde even though there had been health complaints by the occupants almost as soon as the trailers were in place," he says. "If an accurate, reasonably priced method was available from a credible source such as a university extension analytical laboratory, the public would be able to ascertain their potential health risk before buying or renting a house, apartment, or office."References1 Anandan Cet al.Is the prevalence of asthma declining? Systematic review of epidemiological studies.Allergy 65(2):152-1672010. http://dx.doi.org/10.1111/j.1398-9995.2009.02244.x19912154. Crossref, Medline, Google Scholar2 Sublett JLet al.Air filters and air cleaners: rostrum by the American Academy of Allergy, Asthma & Immunology Indoor Allergen Committee.J Allergy Clin Immunol 125(1):32-382010. http://dx.doi.org/10.1016/j.jaci.2009.08.03619910039. Crossref, Medline, Google Scholar3 Britigan Net al.Quantification of ozone levels in indoor environments generated by ionization and ozonolysis air purifiers.J Air Waste Manag Assoc 56(5):601-6102006. PMID: 16739796.16739796. Crossref, Medline, Google Scholar4 Wolverton BC, et al. Interior Landscape Plants for Indoor Air Pollution Abatement. Final Report––September 15, 1989. Stennis Space Center, MS:Science and Technology Laboratory, John C. Stennis Space Center, National Aeronautics and Space Administration (1989). Available: http://tinyurl.com/39cz3ju [accessed 7 Sep 2011]. Google Scholar5 Adamkiewicz G, et al. Moving environmental justice indoors: understanding structural influences on residential exposure patterns in low-income communities. Am J Public Health; http://dx.doi.org/10.2105/AJPH.2011./300119 [online 11 Aug 2011]. Google Scholar6 EPA. An Introduction to Indoor Air Quality (IAQ) [website]. Washington, DC:U.S. Environmental Protection Agency (updated 29 Nov 2010). Available: http://tinyurl.com/6drczvx [accessed 7 Sep 2011]. Google Scholar7 NASA. John C. Stennis Space Center Environmental Assurance Program [website]. Stennis Space Center, MS:John C. Stennis Space Center, National Aeronautics and Space Administration. Available: http://tinyurl.com/3bva6zs [accessed 7 Sep 2011]. Google Scholar8 Yang DSet al.Screening indoor plants for volatile organic pollutant removal efficiency.HortScience 44(5):1377-1381 (2009). Crossref, Google Scholar9 NTP. Final Report on Carcinogens, Background Document for Formaldehyde. Research Triangle Park, NC:National Toxicology Program (2010). Available: http://tinyurl.com/3hym4jp [accessed 7 Sep 2001]. Google Scholar10 WHO. WHO Guidelines for Indoor Air Quality: Selected Pollutants. Copenhagen, Denmark:World Health Organization Regional Office for Europe (2010). Available: http://tinyurl.com/6d2xxmg [accessed 7 Sep 2011]. Google Scholar11 Xu Zet al.Formaldehyde removal by potted plant-soil systems.J Hazard Mater 192(1):314-3182011. http://dx.doi.org/10.1016/j.jhazmat.2011.05.02021641719. Medline, Google Scholar12 Kim KJet al.Variation in formaldehyde removal efficiency among indoor plant species.HortScience 45(10):1489-1495 (2010). Crossref, Google Scholar13 Lee Ret al.A review of events that expose children to elemental mercury in the United States.Environ Health Perspect 117(6):871-8782009. http://dx.doi.org/10.1289/ehp.080033719590676. Link, Google Scholar14 Guzzi G, La Porta C.Molecular mechanisms triggered by mercury.Toxicology 244(1):1-122008. http://dx.doi.org/10.1016/j.tox.2007.11.00218077077. Crossref, Medline, Google Scholar15 Rodrigues Bastos Wet al.Mercury persistence in indoor environments in the Amazon Region, Brazil.Environ Res 96(2):235-2382004. http://dx.doi.org/10.1016/j.envres.2004.01.00815325884. Crossref, Medline, Google Scholar16 Yang DSet al.Volatile organic compounds emanating from indoor ornamental plants.HortScience 44(2):396-400 (2009). Crossref, Google Scholar17 Wolverton BC. How to Grow Fresh Air: 50 House Plants that Purify Your Home or Office. New York, NY:Penguin Books (1997). Google ScholarFiguresReferencesRelatedDetailsCited by Gabriel M, Felgueiras F, Fernandes M, Ribeiro C, Ramos E, Mourão Z and de Oliveira Fernandes E (2020) Assessment of indoor air conditions in households of Portuguese families with newborn children. Implementation of the HEALS IAQ checklist, Environmental Research, 10.1016/j.envres.2019.108966, 182, (108966), Online publication date: 1-Mar-2020. Chang L, Hong G, Weng S, Chuang H, Chang T, Liu C, Chuang W and Chuang K (2019) Indoor ozone levels, houseplants and peak expiratory flow rates among healthy adults in Taipei, Taiwan, Environment International, 10.1016/j.envint.2018.11.010, 122, (231-236), Online publication date: 1-Jan-2019. Ryńska E, Koźmińska U and Rucińska J (2018) Effectivity–ecosphere–economics in nZEB retrofit procedures, Environmental Science and Pollution Research, 10.1007/s11356-018-2446-8, 26:29, (29544-29559), Online publication date: 1-Oct-2019. Chen R, Ho K, Hong G and Chuang K (2019) Houseplant, indoor air pollution, and cardiovascular effects among elderly subjects in Taipei, Taiwan, Science of The Total Environment, 10.1016/j.scitotenv.2019.135770, (135770), Online publication date: 1-Nov-2019. Lumber R, Richardson M and Albertsen J (2018) HFE in Biophilic Design: Human Connections with Nature Ergonomics and Human Factors for a Sustainable Future, 10.1007/978-981-10-8072-2_7, (161-190), . Sarma P and Mohanty K (2018) Epipremnum aureum and Dracaena braunii as indoor plants for enhanced bio-electricity generation in a plant microbial fuel cell with electrochemically modified carbon fiber brush anode, Journal of Bioscience and Bioengineering, 10.1016/j.jbiosc.2018.03.009, Online publication date: 1-Apr-2018. Deng L and Deng Q (2018) The basic roles of indoor plants in human health and comfort, Environmental Science and Pollution Research, 10.1007/s11356-018-3554-1, 25:36, (36087-36101), Online publication date: 1-Dec-2018. Song C, Igarashi M, Ikei H and Miyazaki Y (2017) Physiological effects of viewing fresh red roses, Complementary Therapies in Medicine, 10.1016/j.ctim.2017.10.001, 35, (78-84), Online publication date: 1-Dec-2017. Singh G, Srivastava M and Misra P (2016) Genetic Transformation for Quality Improvement in Ornamental Climbers Biotechnological strategies for the conservation of medicinal and ornamental climbers, 10.1007/978-3-319-19288-8_14, (351-365), . Holt R (2016) Green roofs may cast shadows, Israel Journal of Ecology & Evolution, 10.1080/15659801.2015.1118844, 62:1-2, (15-22), Online publication date: 29-Aug-2016. Kabir E and Kim K (2012) A Review of Some Representative Techniques for Controlling the Indoor Volatile Organic Compounds, Asian Journal of Atmospheric Environment, 10.5572/ajae.2012.6.3.137, 6:3, (137-146), Online publication date: 30-Sep-2012. Dadvand P, de Nazelle A, Triguero-Mas M, Schembari A, Cirach M, Amoly E, Figueras F, Basagaña X, Ostro B and Nieuwenhuijsen M (2012) Surrounding Greenness and Exposure to Air Pollution During Pregnancy: An Analysis of Personal Monitoring Data, Environmental Health Perspectives, 120:9, (1286-1290), Online publication date: 1-Sep-2012. Wong L, Alias H, Aghamohammadi N, Ghadimi A and Sulaiman N (2017) Control Measures and Health Effects of Air Pollution: A Survey among Public Transportation Commuters in Malaysia, Sustainability, 10.3390/su9091616, 9:9, (1616) Song C, Ikei H, Nara M, Takayama D and Miyazaki Y (2018) Physiological Effects of Viewing Bonsai in Elderly Patients Undergoing Rehabilitation, International Journal of Environmental Research and Public Health, 10.3390/ijerph15122635, 15:12, (2635) Khanehshenas F, Habibi P and Zakerian S (2020) The Effect of Biophilic Design Patterns on Employee's Health and Well-being: A Systematic Review, Journal of Ergonomics, 10.30699/jergon.7.4.1, 7:4, (1-11) Zender-Świercz E (2021) Review of IAQ in Premises Equipped with Façade–Ventilation Systems, Atmosphere, 10.3390/atmos12020220, 12:2, (220) Bulgari R, Petrini A, Cocetta G, Nicoletto C, Ertani A, Sambo P, Ferrante A and Nicola S (2021) The Impact of COVID-19 on Horticulture: Critical Issues and Opportunities Derived from an Unexpected Occurrence, Horticulturae, 10.3390/horticulturae7060124, 7:6, (124) Ma Y, Yang D, Bai J, Zhao Y, Hu Q and Yu C (2022) Time Trends in Stroke and Subtypes Mortality Attributable to Household Air Pollution in Chinese and Indian Adults: An Age-Period-Cohort Analysis Using the Global Burden of Disease Study 2019, Frontiers in Aging Neuroscience, 10.3389/fnagi.2022.740549, 14 Vol. 119, No. 10 October 2011Metrics About Article Metrics Publication History Originally published1 October 2011Published in print1 October 2011 Financial disclosuresPDF download License information EHP is an open-access journal published with support from the National Institute of Environmental Health Sciences, National Institutes of Health. All content is public domain unless otherwise noted. Note to readers with disabilities EHP strives to ensure that all journal content is accessible to all readers. However, some figures and Supplemental Material published in EHP articles may not conform to 508 standards due to the complexity of the information being presented. If you need assistance accessing journal content, please contact [email protected]. Our staff will work with you to assess and meet your accessibility needs within 3 working days.
Referência(s)