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The basic roles of indoor plants in human health and comfort

Environmental Science and Pollution Research volume 25pages 36087–36101 (2018)Cite this article

Abstract

Humans have a close relationship with nature, and so integrating the nature world into indoor space could effectively increase people’s engagement with nature, and this in turn may benefit their health and comfort. Since people spend 80–90% of their time indoors, the indoor environment is very important for their health. Indoor plants are part of natural indoor environment, but their effect on the indoor environment and on humans has not been quantified. This review provides a comprehensive summary of the role and importance of indoor plants in human health and comfort according to the following four criteria: photosynthesis; transpiration; psychological effects; and purification. Photosynthesis and transpiration are important mechanisms for plants, and the basic functions maintaining the carbon and oxygen cycles in nature. Above all have potential inspiration to human’s activities that people often ignored, for example, the application of solar panel, artificial photosynthesis, and green roof/facades were motivated by those functions. Indoor plants have also been shown to have indirect unconscious psychological effect on task performance, health, and levels of stress. Indoor plants can act as indoor air purifiers, they are an effective way to reduce pollutants indoor to reduce human exposure, and have been widely studied in this regard. Indoor plants have potential applications in other fields, including sensing, solar energy, acoustic, and people’s health and comfort. Making full use of various effects in plants benefit human health and comfort.

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References

  • Adachi M, Rohde CLE, Kendle AD (2000) Effects of floral and foliage displays on human emotions. Horttech 10:142–155

    Google Scholar 

  • Afsharinejad A, Davy A, Jennings B (2016) Dynamic channel allocation in electromagnetic nanonetworks for high resolution monitoring of plants. Nano Commun Networks 7:2–16

    Google Scholar 

  • Alharbi FH, Kais S (2015) Theoretical limits of photovoltaics efficiency and possible improvements by intuitive approaches learned from photosynthesis and quantum coherence. Renew Sust Energ Rev 43:1073–1089

    Google Scholar 

  • Alstrum-Acevedo JH, Brennaman MK, Meyer TJ (2005) Chemical approaches to artificial photosynthesis. 2. Inorg Chem 44:6802–6827

    CAS  Google Scholar 

  • Aydogan A, Montoya LD (2011) Formaldehyde removal by common indoor plant species and various growing media. Atmos Environ 45:2675–2682

    CAS  Google Scholar 

  • Bello AO, Tawabini BS, Khalil AB, Boland CR, Saleh TA (2018) Phytoremediation of cadmium-, lead- and nickel-contaminated water by Phragmites australis in hydroponic systems. Ecol Eng 120:126–133

    Google Scholar 

  • Benniston AC, Harriman A (2008) Artificial photosynthesis. Mater Today 11:26–34

    CAS  Google Scholar 

  • Bensaid S, Centi G, Garrone E, Perathoner S, Saracco G (2012) Towards artificial leaves for solar hydrogen and fuels from carbon dioxide. ChemSusChem 5:500–521

    CAS  Google Scholar 

  • Bergstrand K, Schussler H (2013) Growth, development and photosynthesis of some horticultural plants as affected by different supplementary lighting technologies. Eur J Hortic Sci 78:119–125

    Google Scholar 

  • Bernstein JA, Alexis N, Barnes C, Bernstein IL, Nel A, Peden D, Diaz-Sanchez D, Tarlo SM, Williams PB (2004) Health effects of air pollution. J Allergy Clin Immunol 114:1116–1123

    Google Scholar 

  • Bernstein JA, Alexis N, Bacchus H, Bernstein IL, Fritz P, Horner E, Li N, Mason S, Nel A, Oullette J (2008) The health effects of nonindustrial indoor air pollution. J Allergy Clin Immunol 121:585–591

    CAS  Google Scholar 

  • Blunden SL, Beebe DW (2006) The contribution of intermittent hypoxia, sleep debt and sleep disruption to daytime performance deficits in children: consideration of respiratory and non-respiratory sleep disorders. Sleep Med Rev 10:109–118

    Google Scholar 

  • Bot GP (2001) Developments in indoor sustainable plant production with emphasis on energy saving. Comput Electron Agric 30:151–165

    Google Scholar 

  • Boulard T, Wang S (2000) Greenhouse crop transpiration simulation from external climate conditions. Agric For Meteorol 100:25–34

    Google Scholar 

  • Bowler DE, Buyung-Ali L, Knight TM, Pullin AS (2010) Urban greening to cool towns and cities: a systematic review of the empirical evidence. Landsc Urban Plan 97:147–155

    Google Scholar 

  • Bringslimark T, Hartig T, Patil GG (2007) Psychological benefits of indoor plants in workplaces: putting experimental results into context. HortScience 42:581–587

    Google Scholar 

  • Bringslimark T, Hartig T, Patil GG (2009) The psychological benefits of indoor plants: a critical review of the experimental literature. J Environ Psychol 29:422–433

    Google Scholar 

  • Browne S, Halligan P, Wade D, Taggart D (2003) Postoperative hypoxia is a contributory factor to cognitive impairment after cardiac surgery. J Thorac Cardiovasc Surg 126:1061–1064

    CAS  Google Scholar 

  • Chang C-Y, Chen P-K (2005) Human response to window views and indoor plants in the workplace. HortScience 40:1354–1359

    Google Scholar 

  • Chaves MM, Pereira JS, Maroco J, Rodrigues ML, Ricardo CPP, Osório ML, Carvalho I, Faria T, Pinheiro C (2002) How plants cope with water stress in the field? Photosynthesis and Growth. Ann Bot 89:907–916

    CAS  Google Scholar 

  • Claudio L (2011) Planting healthier indoor air. Environ Health Perspect 119:a426

    Google Scholar 

  • Collins CD, Bell JNB, Crews C (2000) Benzene accumulation in horticultural crops. Chemosphere 40:109–114

    CAS  Google Scholar 

  • Cook G, Dixon J, Leopold A (1964) Transpiration: its effects on plant leaf temperature. Science 144:546–547

    CAS  Google Scholar 

  • Cornejo J, Munoz F, Ma C, Stewart A (1999) Studies on the decontamination of air by plants. Ecotoxicology 8:311–320

    CAS  Google Scholar 

  • Cruz MD, Müller R, Bo S, Pedersen JS, Christensen JH (2014) Assessment of volatile organic compound removal by indoor plants—a novel experimental setup. Environ Sci Pollut Res Int 21:7838–7846

    Google Scholar 

  • Cure JD, Acock B (1986) Crop responses to carbon dioxide doubling: a literature survey✩. Agric For Meteorol 38:127–145

    Google Scholar 

  • D'Alessandro F, Asdrubali F, Mencarelli N (2015) Experimental evaluation and modelling of the sound absorption properties of plants for indoor acoustic applications. Build Environ 94:913–923

    Google Scholar 

  • Darlington AB, Dat JF, Dixon MA (2001) The biofiltration of indoor air: air flux and temperature influences the removal of toluene, ethylbenzene and xylene. Environ Sci Technol 35:240–246

    CAS  Google Scholar 

  • De Kempeneer L, Sercu B, Vanbrabant W, Van Langenhove H, Verstraete W (2004) Bioaugmentation of the phyllosphere for the removal of toluene from indoor air. Appl Microbiol Biotechnol 64:284–288

    Google Scholar 

  • Delgado-Saborit JM, Aquilina NJ, Meddings C, Baker S, Vardoulakis S, Harrison RM (2009) Measurement of personal exposure to volatile organic compounds and particle associated PAH in three UK regions. Environ Sci Technol 43:4582–4588

    CAS  Google Scholar 

  • Deng Q, Lu C, Norbäck D, Bornehag C-G, Zhang Y, Liu W, Sundell J (2015a) Early life exposure to ambient air pollution and childhood asthma in China. Environ Res 143:83-92

  • Deng Q, Lu C, Ou C, Liu W (2015b) Effects of early life exposure to outdoor air pollution and indoor renovation on childhood asthma in China. Build Environ 93:84–91

    Google Scholar 

  • Deng Q, Lu C, Jiang W, Zhao J, Deng L, Xiang Y (2017) Association of outdoor air pollution and indoor renovation with early childhood ear infection in China. Chemosphere 169:288–296

    CAS  Google Scholar 

  • Deng Q, Deng L, Lu C, Li Y, Norbäck D (2018a) Parental stress and air pollution increase childhood asthma in China. Environ Res 165:23–31

    CAS  Google Scholar 

  • Deng Q, Ou C, Chen J, Xiang Y (2018b) Particle deposition in tracheobronchial airways of an infant, child and adult. Sci Total Environ 612:339–346

    CAS  Google Scholar 

  • Dijkstra K, Pieterse ME, Pruyn A (2008) Stress-reducing effects of indoor plants in the built healthcare environment: the mediating role of perceived attractiveness. Prev Med 47:279–283

    CAS  Google Scholar 

  • Dingle P, Tapsell P, Hu S (2000) Reducing formaldehyde exposure in office environments using plants. Bull Environ Contam Toxicol 64:302–308

    CAS  Google Scholar 

  • Dravigne A, Waliczek TM, Lineberger R, Zajicek J (2008) The effect of live plants and window views of green spaces on employee perceptions of job satisfaction. HortScience 43:183–187

    Google Scholar 

  • Enoch H, Hurd R (1979) The effect of elevated CO2 concentrations in the atmosphere on plant transpiration and water use efficiency. A study with potted carnation plants. Int J Biometeorol 23:343–351

    CAS  Google Scholar 

  • Evensen KH, Raanaas RK, Hagerhall CM, Johansson M, Patil GG (2015) Restorative elements at the computer workstation: a comparison of live plants and inanimate objects with and without window view. Environ Behav 47:288–303

    Google Scholar 

  • Ferl R, Wheeler R, Levine HG, Paul A-L (2002) Plants in space. Curr Opin Plant Biol 5:258–263

    Google Scholar 

  • Fernández-Cañero R, Urrestarazu LP, Franco Salas A (2012) Assessment of the cooling potential of an indoor living wall using different substrates in a warm climate. Indoor Built Environ 21:642–650

    Google Scholar 

  • Fjeld T, Veiersted B, Sandvik L, Riise G, Levy F (1998) The effect of indoor foliage plants on health and discomfort symptoms among office workers. Indoor Built Environ 7:204–209

    Google Scholar 

  • Fjeld T (2000) The effect of interior planting on health and discomfort among workers and school children. HortTechnology 10:46–52

    Google Scholar 

  • Franchini M, Mannucci PM (2018) Mitigation of air pollution by greenness: a narrative review. Eur J Intern Med 55:1–5

    CAS  Google Scholar 

  • Franklin PJ (2007) Indoor air quality and respiratory health of children. Paediatr Respir Rev 8:281–286

    Google Scholar 

  • Garland KB, Burnett SE, Day ME, van Tersel MW (2012) Influence of substrate water content and daily light integral on photosynthesis, water use efficiency, and morphology of Heuchera americana. J Am Soc Hortic Sci 137:57–67

    Google Scholar 

  • Gawrońska H, Bakera B (2015) Phytoremediation of particulate matter from indoor air by Chlorophytum comosum L. plants. Air Qual Atmos Health 8:265–272

    Google Scholar 

  • Giese M, Bauer-Doranth U, Langebartels C, Sandermann H Jr (1994) Detoxification of formaldehyde by the spider plant (Chlorophytum comosum L.) and by soybean (Glycine max L.) cell-suspension cultures. Plant Physiol 104:1301–1309

    CAS  Google Scholar 

  • Godish T, Guindon C (1989) An assessment of botanical air purification as a formaldehyde mitigation measure under dynamic laboratory chamber conditions. Environ Pollut 62:13–20

    CAS  Google Scholar 

  • Guéguen N (2012) Dead indoor plants strengthen belief in global warming. J Environ Psychol 32:173–177

    Google Scholar 

  • Gust D, Moore TA, Moore AL (2009) Solar fuels via artificial photosynthesis. Acc Chem Res 42:1890–1898

    CAS  Google Scholar 

  • Han K-T (2009) Influence of limitedly visible leafy indoor plants on the psychology, behavior, and health of students at a junior high school in Taiwan. Environ Behav 41:658–692

    Google Scholar 

  • Hoelscher M-T, Nehls T, Jänicke B, Wessolek G (2016) Quantifying cooling effects of facade greening: shading transpiration and insulation. Energ Buildings 114:283–290

    Google Scholar 

  • Hogewoning SW, Trouwborst G, Maljaars H, Poorter H, van Ieperen W, Harbinson J (2010) Blue light dose–responses of leaf photosynthesis, morphology, and chemical composition of Cucumis sativus grown under different combinations of red and blue light. J Exp Bot 61:3107–3117

    CAS  Google Scholar 

  • House RL, Iha NYM, Coppo RL, Alibabaei L, Sherman BD, Kang P, Brennaman MK, Hoertz PG, Meyer TJ (2015) Artificial photosynthesis: where are we now? Where can we go? J Photochem Photobiol C: Photochem Rev 25:32–45

    CAS  Google Scholar 

  • Ignatius RW, Martin TS, Bula RJ, Morrow RC, Tibbitts TW (1991): Method and apparatus for irradiation of plants using optoelectronic devices. Google Patents

  • Irga P, Torpy F, Burchett M (2013) Can hydroculture be used to enhance the performance of indoor plants for the removal of air pollutants? Atmos Environ 77:267–271

    CAS  Google Scholar 

  • Jarvis P, Morison J (1981) The control of transpiration and photosynthesis by the stomata, Stomatal physiology. Cambridge University Press, Cambridge, pp 247–279

    Google Scholar 

  • Jeon HS, Koh JH, Park SJ, Jee MS, Ko D-H, Hwang YJ, Min BK (2015) A monolithic and standalone solar-fuel device having comparable efficiency to photosynthesis in nature. J Mater Chem A 3:5835–5842

    CAS  Google Scholar 

  • Jim C (2014) Heat-sink effect and indoor warming imposed by tropical extensive green roof. Ecol Eng 62:1–12

    Google Scholar 

  • Jones AP (1999) Indoor air quality and health. Atmos Environ 33:4535–4564

    CAS  Google Scholar 

  • Kalyanasundaram K, Graetzel M (2010) Artificial photosynthesis: biomimetic approaches to solar energy conversion and storage. Curr Opin Biotechnol 21:298–310

    CAS  Google Scholar 

  • Kampa M, Castanas E (2008) Human health effects of air pollution. Environ Pollut 151:362–367

    CAS  Google Scholar 

  • Keniger LE, Gaston KJ, Irvine KN, Fuller RA (2013) What are the benefits of interacting with nature? Int J Environ Res Public Health 10:913–935

    Google Scholar 

  • Kichah A, Bournet P-E, Migeon C, Boulard T (2012) Measurement and CFD simulation of microclimate characteristics and transpiration of an Impatiens pot plant crop in a greenhouse. Biosyst Eng 112:22–34

    Google Scholar 

  • Kil M, Kim K, Cho J, Park C (2008) Formaldehyde gas removal effects and physiological responses of Fatsia japonica and Epipremnum aureum according to various light intensity. Korean J Hortic Sci Technol 26:189–196

    CAS  Google Scholar 

  • Kim J, Cha SH, Koo C, Tang S-K (2018) The effects of indoor plants and artificial windows in an underground environment. Build Environ 138:53–62

    Google Scholar 

  • Kim KJ, Kil MJ, Song JS, Yoo EH, Son K-C, Kays SJ (2008) Efficiency of volatile formaldehyde removal by indoor plants: contribution of aerial plant parts versus the root zone. J Am Soc Hortic Sci 133:521–526

    Google Scholar 

  • Kim KJ, Jeong MI, Lee DW, Song JS, Kim HD, Yoo EH, Jeong SJ, Han SW, Kays SJ, Lim Y-W (2010) Variation in formaldehyde removal efficiency among indoor plant species. HortScience 45:1489–1495

    Google Scholar 

  • Kim S-J, Hahn E-J, Heo J-W, Paek K-Y (2004) Effects of LEDs on net photosynthetic rate, growth and leaf stomata of chrysanthemum plantlets in vitro. Sci Hortic 101:143–151

    Google Scholar 

  • Kitaya Y, Tani A, Goto E, Saito T, Takahashi H (2000) Development of a plant growth unit for growing plants over a long-term life cycle under microgravity conditions. Adv Space Res 26:281–288

    CAS  Google Scholar 

  • Kovats RS, Hajat S (2008) Heat stress and public health: a critical review. Annu Rev Public Health 29:41–55

    Google Scholar 

  • Larsen L, Adams J, Deal B, Kweon BS, Tyler E (1998) Plants in the workplace the effects of plant density on productivity, attitudes, and perceptions. Environ Behav 30:261–281

    Google Scholar 

  • Liu C, Colón BC, Ziesack M, Silver PA, Nocera DG (2016) Water splitting–biosynthetic system with CO2 reduction efficiencies exceeding photosynthesis. Science 352:1210–1213

    CAS  Google Scholar 

  • Liu XY, Guo SR, Xu ZG, Jiao XL, Tezuka T (2011) Regulation of chloroplast ultrastructure, cross-section anatomy of leaves, and morphology of stomata of cherry tomato by different light irradiations of light-emitting diodes. J Biotechnol 24:129–139

    Google Scholar 

  • Liu Y-J, Mu Y-J, Zhu Y-G, Ding H, Arens NC (2007) Which ornamental plant species effectively remove benzene from indoor air? Atmos Environ 41:650–654

    CAS  Google Scholar 

  • Lohr VI, Pearson-Mims CH (1996) Particulate matter accumulation on horizontal surfaces in interiors: influence of foliage plants. Atmos Environ 30:2565–2568

    CAS  Google Scholar 

  • Lu C, Deng Q, Li Y, Sundell J, Norbäck D (2016) Outdoor air pollution, meteorological conditions and indoor factors in dwellings in relation to sick building syndrome (SBS) among adults in China. Sci Total Environ 560-561:186–196

    CAS  Google Scholar 

  • Mahajan P, Oliveira F, Macedo I (2008) Effect of temperature and humidity on the transpiration rate of the whole mushrooms. J Food Eng 84:281–288

    Google Scholar 

  • Mangone G, Kurvers SR, Luscuere PG (2014) Constructing thermal comfort: investigating the effect of vegetation on indoor thermal comfort through a four season thermal comfort quasi-experiment. Build Environ 81:410–426

    Google Scholar 

  • Medlyn B, Dreyer E, Ellsworth D, Forstreuter M, Harley P, Kirschbaum M, Le Roux X, Montpied P, Strassemeyer J, Walcroft A (2002) Temperature response of parameters of a biochemically based model of photosynthesis. II. A review of experimental data. Plant Cell Environ 25:1167–1179

    CAS  Google Scholar 

  • Medrano E, Lorenzo P, Sánchez-Guerrero MC, Montero JI (2005) Evaluation and modelling of greenhouse cucumber-crop transpiration under high and low radiation conditions. Sci Hortic 105:163–175

    Google Scholar 

  • Messinger J, Renger G (2008) Photosynthetic water splitting, primary processes of photosynthesis, part 2 principles and apparatus. RSCPublishing, Cambridge, pp 291–351

    Google Scholar 

  • Michl J (2011) Photochemical CO 2 reduction: towards an artificial leaf? Nat Chem 3:268–269

    CAS  Google Scholar 

  • Mishra V (2003) Indoor air pollution from biomass combustion and acute respiratory illness in preschool age children in Zimbabwe. Int J Epidemiol 32:847–853

    Google Scholar 

  • Monica G (2013) Green symphonies: a call for studies on acoustic communication in plants. Behav Ecol 24:789–796

    Google Scholar 

  • Montero J, Antón A, Munoz P, Lorenzo P (2001) Transpiration from geranium grown under high temperatures and low humidities in greenhouses. Agric For Meteorol 107:323–332

    Google Scholar 

  • Mosaddegh MH, Jafarian A, Ghasemi A, Mosaddegh A (2014) Phytoremediation of benzene, toluene, ethylbenzene and xylene contaminated air by D. deremensis and O microdasys plants. J Environ Health Sci Eng 12:39

    Google Scholar 

  • Mumford J, He X, Chapman R, Harris D, Li X, Xian Y, Jiang W, Xu C, Chuang J (1987) Lung cancer and indoor air pollution in Xuan Wei, China. Science 235:217–220

    CAS  Google Scholar 

  • Nemali KS, van Iersel MW (2004) Acclimation of wax begonia to light intensity: changes in photosynthesis, respiration, and chlorophyll concentration. J Am Soc Hortic Sci 129:745–751

    Google Scholar 

  • Nocera DG (2012) The artificial leaf. Acc Chem Res 45:767–776

    CAS  Google Scholar 

  • Oh GS, Jung GJ, Seo MH, Im YB (2011) Experimental study on variations of CO 2 concentration in the presence of indoor plants and respiration of experimental animals. Hortic Environ Biotechnol 52:321–329

    Google Scholar 

  • Orita I, Yurimoto H, Hirai R, Kawarabayasi Y, Sakai Y, Kato N (2005) The archaeon Pyrococcus horikoshii possesses a bifunctional enzyme for formaldehyde fixation via the ribulose monophosphate pathway. J Bacteriol 187:3636–3642

    CAS  Google Scholar 

  • Orwell RL, Wood RA, Burchett MD, Tarran J, Torpy F (2006) The potted-plant microcosm substantially reduces indoor air VOC pollution: II. Laboratory study. Water Air Soil Pollut 177:59–80

    CAS  Google Scholar 

  • Oyabu T, Sawada A, Onodera T, Takenaka K, Wolverton B (2003) Characteristics of potted plants for removing offensive odors. Sensors Actuators B Chem 89:131–136

    CAS  Google Scholar 

  • Pandey MR, Boleij J, Smith K, Wafula E (1989) Indoor air pollution in developing countries and acute respiratory infection in children. Lancet 333:427–429

    Google Scholar 

  • Papinchak HL, Holcomb EJ, Best TO, Decoteau DR (2009) Effectiveness of houseplants in reducing the indoor air pollutant ozone. HortTechnology 19:286–290

    CAS  Google Scholar 

  • Park J, Ikeda K (2006) Variations of formaldehyde and VOC levels during 3 years in new and older homes. Indoor Air 16:129–135

    CAS  Google Scholar 

  • Park S-H, Mattson RH (2009) Ornamental indoor plants in hospital rooms enhanced health outcomes of patients recovering from surgery. J Altern Complement Med 15:975–980

    Google Scholar 

  • Parseh I, Teiri H, Hajizadeh Y, Ebrahimpour K (2018) Phytoremediation of benzene vapors from indoor air by Schefflera arboricola and Spathiphyllum wallisii plants. Atmos Pollut Res 9:1083–1087

    Google Scholar 

  • Pennisi SV, van Iersel MW (2012) Quantification of carbon assimilation of plants in simulated and in situ interiorscapes. HortScience 47:468–476

    CAS  Google Scholar 

  • Perez V, Alexander DD, Bailey WH (2013) Air ions and mood outcomes: a review and meta-analysis. BMC Psychiatry 13:29

    Google Scholar 

  • Pretty J (2004) How nature contributes to mental and physical health. Spiritual Health Int 5:68–78

    Google Scholar 

  • Raanaas RK, Evensen KH, Rich D, Sjøstrøm G, Patil G (2011) Benefits of indoor plants on attention capacity in an office setting. J Environ Psychol 31:99–105

    Google Scholar 

  • Raji B, Tenpierik MJ, van den Dobbelsteen A (2015) The impact of greening systems on building energy performance: a literature review. Renew Sust Energ Rev 45:610–623

    CAS  Google Scholar 

  • Reddy V, Reddy K, Hodges H (1995) Carbon dioxide enrichment and temperature effects on cotton canopy photosynthesis, transpiration, and water-use efficiency. Field Crop Res 41:13–23

    Google Scholar 

  • Ren X, Zeng G, Tang L, Wang J, Wan J, Feng H, Song B, Huang C, Tang X (2018a) Effect of exogenous carbonaceous materials on the bioavailability of organic pollutants and their ecological risks. Soil Biol Biochem 116:70–81

    CAS  Google Scholar 

  • Ren X, Zeng G, Tang L, Wang J, Wan J, Liu Y, Yu J, Yi H, Ye S, Deng R (2018b) Sorption, transport and biodegradation–an insight into bioavailability of persistent organic pollutants in soil. Sci Total Environ 610:1154–1163

    Google Scholar 

  • Ringsmuth AK, Landsberg MJ, Hankamer B (2016) Can photosynthesis enable a global transition from fossil fuels to solar fuels, to mitigate climate change and fuel-supply limitations? Renew Sust Energ Rev 62:134–163

    CAS  Google Scholar 

  • Rinne ST, Rodas EJ, Bender BS, Rinne ML, Simpson JM, Galer-Unti R, Glickman LT (2006) Relationship of pulmonary function among women and children to indoor air pollution from biomass use in rural Ecuador. Respir Med 100:1208–1215

    Google Scholar 

  • Roy J, Boulard T, Kittas C, Wang S (2002) Convective and ventilation transfers in greenhouses, part 1: the greenhouse considered as a perfectly stirred tank. Biosyst Eng 83:1–20

    Google Scholar 

  • Ruijtenbeek K, Kessels LC, De Mey JG, Blanco CE (2003) Chronic moderate hypoxia and protein malnutrition both induce growth retardation, but have distinct effects on arterial endothelium-dependent reactivity in the chicken embryo. Pediatr Res 53:573–579

    Google Scholar 

  • Söderback I, Söderström M, Schälander E (2004) Horticultural therapy: the ‘healing garden’ and gardening in rehabilitation measures at Danderyd Hospital Rehabilitation Clinic, Sweden. Pediatr Rehabil 7:245–260

    Google Scholar 

  • Salt DE, Prince RC, Pickering IJ, Raskin I (1995) Mechanisms of cadmium mobility and accumulation in Indian mustard. Plant Physiol 109:1427–1433

    CAS  Google Scholar 

  • Sawada A, Oyabu T (2008) Purification characteristics of pothos for airborne chemicals in growing conditions and its evaluation. Atmos Environ 42:594–602

    CAS  Google Scholar 

  • Seginer I (1994) Transpirational cooling of a greenhouse crop with partial ground cover. Agric For Meteorol 71:265–281

    Google Scholar 

  • Shibata S, Suzuki N (2001) Effects of indoor foliage plants on subjects’ recovery from mental fatigue. N Am J Psychol 3:385–396

    Google Scholar 

  • Shibata S, Suzuki N (2002) Effects of the foliage plant on task performance and mood. J Environ Psychol 22:265–272

    Google Scholar 

  • Shibata S, Suzuki N (2004) Effects of an indoor plant on creative task performance and mood. Scand J Psychol 45:373–381

    Google Scholar 

  • Shiue A, Hu S-C, Tu M-L (2011) Particles removal by negative ionic air purifier in cleanroom. Aerosol Air Qual Res 11:179–186

    Google Scholar 

  • Shoemaker CA, Randall K, Relf PD, Geller ES (1992) Relationships between plants, behavior, and attitudes in an office environment. HortTechnology 2:205–206

    Google Scholar 

  • Silva E, Ribeiro R, Ferreira-Silva S, Viégas R, Silveira J (2010) Comparative effects of salinity and water stress on photosynthesis, water relations and growth of Jatropha curcas plants. J Arid Environ 74:1130–1137

    Google Scholar 

  • Sinae P, Mingi K, Munghwa Y, Myungmn O, Kicheol S (2010) Comparison of indoor CO2 removal capability of five foliage plants by photosynthesis. Korean J Hortic Sci Technol 28:864–870

    Google Scholar 

  • Smith A, Pitt M (2011) Healthy workplaces: plantscaping for indoor environmental quality. Facilities 29:169–187

    Google Scholar 

  • Smith KR, Samet JM, Romieu I, Bruce N (2000) Indoor air pollution in developing countries and acute lower respiratory infections in children. Thorax 55:518–532

    CAS  Google Scholar 

  • Sriprapat W, Thiravetyan P (2013) Phytoremediation of BTEX from indoor air by Zamioculcas zamiifolia. Water Air Soil Pollut 224:1–9

    CAS  Google Scholar 

  • Sriprapat W, Boraphech P, Thiravetyan P (2014) Factors affecting xylene-contaminated air removal by the ornamental plant Zamioculcas zamiifolia. Environ Sci Pollut Res 21:2603–2610

    CAS  Google Scholar 

  • Tang X, Bai Y, Duong A, Smith MT, Li L, Zhang L (2009) Formaldehyde in China: production, consumption, exposure levels, and health effects. Environ Int 35:1210–1224

    CAS  Google Scholar 

  • Tani A, Hewitt CN (2009) Uptake of aldehydes and ketones at typical indoor concentrations by houseplants. Environ Sci Technol 43:8338–8343

    CAS  Google Scholar 

  • Teiri H, Pourzamani H, Hajizadeh Y (2018) Phytoremediation of VOCs from indoor air by ornamental potted plants: a pilot study using a palm species under the controlled environment. Chemosphere 197:375–381

    CAS  Google Scholar 

  • Tenhunen J, Lange O, Gebel J, Beyschlag W, Weber J (1984) Changes in photosynthetic capacity, carboxylation efficiency, and CO2 compensation point associated with midday stomatal closure and midday depression of net CO2 exchange of leaves of Quercus suber. Planta 162:193–203

    CAS  Google Scholar 

  • Terashima I, Saeki T (1985) A new model for leaf photosynthesis incorporating the gradients of light environment and of photosynthetic properties of chloroplasts within a leaf. Ann Bot 56:489–499

    CAS  Google Scholar 

  • Tezara W, Mitchell V, Driscoll S, Lawlor D (1999) Water stress inhibits plant photosynthesis by decreasing coupling factor and ATP. Nature 401:914–917

    CAS  Google Scholar 

  • Tikhonov V, Tsvetkov V, Litvinova E, Sirota T, Kondrashova M (2004) Generation of negative air ions by plants upon pulsed electrical stimulation applied to soil. Russ J Plant Physiol 51:414–419

    CAS  Google Scholar 

  • Titus A, Rao BS, Harsha H, Ramkumar K, Srikumar B, Singh S, Chattarji S, Raju T (2007) Hypobaric hypoxia-induced dendritic atrophy of hippocampal neurons is associated with cognitive impairment in adult rats. Neuroscience 145:265–278

    CAS  Google Scholar 

  • Torpy F, Irga P, Burchett M (2014) Profiling indoor plants for the amelioration of high CO2 concentrations. Urban For Urban Green 13:227–233

    Google Scholar 

  • Treesubsuntorn C, Thiravetyan P (2012) Removal of benzene from indoor air by Dracaena sanderiana: effect of wax and stomata. Atmos Environ 57:317–321

    CAS  Google Scholar 

  • Ugrekhelidze D, Korte F, Kvesitadze G (1997) Uptake and transformation of benzene and toluene by plant leaves. Ecotoxicol Environ Saf 37:24–29

    CAS  Google Scholar 

  • Van der Vliet L, Peterson C, Hale B (2007) Cd accumulation in roots and shoots of durum wheat: the roles of transpiration rate and apoplastic bypass. J Exp Bot 58:2939–2947

    Google Scholar 

  • Van Loy MD, Riley WJ, Daisey JM, Nazaroff WW (2001) Dynamic behavior of semivolatile organic compounds in indoor air. 2. Nicotine and phenanthrene with carpet and wallboard. Environ Sci Technol 35:560–567

    Google Scholar 

  • Volkov AG, Ranatunga DRA (2006) Plants as environmental biosensors. Plant Signal Behav 1:105–115

    Google Scholar 

  • Wang HFD, Wang DN (1999) Cooling effect of ivy on a wall. Exp Heat Transfer 12:235–245

    Google Scholar 

  • Wang S, Boulard T (2000) Predicting the microclimate in a naturally ventilated plastic house in a Mediterranean climate. J Agric Eng Res 75:27–38

    Google Scholar 

  • Wilhelm C, Selmar D (2011) Energy dissipation is an essential mechanism to sustain the viability of plants: the physiological limits of improved photosynthesis. J Plant Physiol 168:79–87

    CAS  Google Scholar 

  • Wolkoff P, Nielsen GD (2001) Organic compounds in indoor air—their relevance for perceived indoor air quality? Atmos Environ 35:4407–4417

    CAS  Google Scholar 

  • Wolverton BC, Mcdonald RC (1984) Foliage plants for removing indoor air pollutants from energy-efficient homes. Econ Bot 38:224–228

    CAS  Google Scholar 

  • Wu CC, Lee GW (2004) Oxidation of volatile organic compounds by negative air ions. Atmos Environ 38:6287–6295

    CAS  Google Scholar 

  • Xu Z, Qin N, Wang J, Tong H (2010) Formaldehyde biofiltration as affected by spider plant. Bioresour Technol 101:6930–6934

    CAS  Google Scholar 

  • Xu Z, Wang L, Hou H (2011) Formaldehyde removal by potted plant–soil systems. J Hazard Mater 192:314–318

    CAS  Google Scholar 

  • Yan X, Wang H, Hou Z, Wang S, Zhang D, Xu Q, Tokola T (2015) Spatial analysis of the ecological effects of negative air ions in urban vegetated areas: a case study in Maiji, China. Urban For Urban Green 14:636–645

    Google Scholar 

  • Yang DS, Pennisi SV, Son K-C, Kays SJ (2009a) Screening indoor plants for volatile organic pollutant removal efficiency. HortScience 44:1377–1381

    Google Scholar 

  • Yang DS, Son K-C, Kays SJ (2009b) Volatile organic compounds emanating from indoor ornamental plants. HortScience 44:396–400

    Google Scholar 

  • Yarn K-F, Yu K-C, Huang J-M, Luo W-J, Wu P-C (2013) Utilizing a vertical garden to reduce indoor carbon dioxide in an indoor environment. Wulfenia J

  • Zeiger E, Field C (1982) Photocontrol of the functional coupling between photosynthesis and stomatal conductance in the intact leaf: blue light and PAR-dependent photosystems in guard cells. Plant Physiol 70:370–375

    CAS  Google Scholar 

  • Zhang D, Xiang T, Peihan L, Bao L (2011) Transgenic plants of Petunia hybrida harboring the CYP2E1 gene efficiently remove benzene and toluene pollutants and improve resistance to formaldehyde. Genet Mol Biol 34:634–639

    CAS  Google Scholar 

  • Zhang Y, Li C, Zhou X, Moore IIIB (2002) A simulation model linking crop growth and soil biogeochemistry for sustainable agriculture. Ecol Model 151:75–108

    CAS  Google Scholar 

  • Zhou J, Qin F, Su J, Liao J, Xu H (2011) Purification of formaldehyde-polluted air by indoor plants of Araceae, Agavaceae and Liliaceae. J Food Agric Environ 9:1012–1018

    CAS  Google Scholar 

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Funding

This work was financially supported by National Natural Science Foundation of China (51576214 and 21777193) and the Key Research and Development Program of Hunan Province (No.2017SK2091).

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Authors and Affiliations

  1. School of Energy Science and Engineering, Central South University, Changsha, 410083, China

    Linjing Deng & Qihong Deng

  2. XiangYa School of Public Health, Central South University, Changsha, 410078, Hunan, China

    Qihong Deng

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  1. Linjing Deng
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  2. Qihong Deng
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Correspondence to Qihong Deng.

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Responsible editor: Philippe Garrigues

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Deng, L., Deng, Q. The basic roles of indoor plants in human health and comfort. Environ Sci Pollut Res 25, 36087–36101 (2018). https://doi.org/10.1007/s11356-018-3554-1

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  • DOI: https://doi.org/10.1007/s11356-018-3554-1

Keywords

  • Indoor plants
  • Photosynthesis
  • Transpiration
  • Psychological effect
  • Purification
  • Health