1. bookVolume 18 (2018): Edizione 4 (October 2018)
Dettagli della rivista
License
Formato
Rivista
eISSN
2300-8733
Prima pubblicazione
25 Nov 2011
Frequenza di pubblicazione
4 volte all'anno
Lingue
Inglese
Open Access

Air Ionization in Livestock Buildings – A Review

Pubblicato online: 02 Nov 2018
Volume & Edizione: Volume 18 (2018) - Edizione 4 (October 2018)
Pagine: 899 - 905
Ricevuto: 12 Jun 2018
Accettato: 21 Sep 2018
Dettagli della rivista
License
Formato
Rivista
eISSN
2300-8733
Prima pubblicazione
25 Nov 2011
Frequenza di pubblicazione
4 volte all'anno
Lingue
Inglese

Alonso C., Raynor P.C., Davies P.R., Morrison R.B., Torremorell M. (2016). Evaluation of an electrostatic particle ionization technology for decreasing airborne pathogens in pigs. Aerobiologia, 32: 405–419.Search in Google Scholar

Arnold J.W. (2004). Use of negative air ionization for reducing bacterial pathogens and spores on stainless steel surfaces. J. Appl. Poultry Res., 13: 200–206.Search in Google Scholar

Asaj A. (1987). The influence of negative air ionization on domestic animals. Proc. Int. Symp.: Micro-physical problems in biology versus animal hygiene, Kraków, Poland, 1–3.06.1987.Search in Google Scholar

Bailey W.H., Williams A.L., Leonhard M.J. (2018). Exposure of laboratory animals to small air ions: a systematic review of biological and behavioral study. BioMed Eng OnLine, 17: 72.Search in Google Scholar

Banhazi T., Aland A., Hartung J. (2018). Editors. Air quality and livestock farming. CRC Press, 372 pp.10.1201/9781315738338Search in Google Scholar

Brigmon R.L., Mather F.B. (1992). Seasonal temperature and its influence on plasma corticosteone, triiodothyronine, thyroxine, plasma protein and packed cell volume in mature male chickens. Comp. Broch. Physiol., 102: 289–293.Search in Google Scholar

Cambra-López M., Winkel A., Harn J. Van, Ogink N.W.M., Aarnink A.J.A. (2009). Ionization for reducing particulate matter emissions from poultry houses. Transactions of the ASABE, 52: 1757–1771.Search in Google Scholar

Gast R.K., Bailey W., Mitchell W., Holt P.S. (1999). Application of negative air ionization for reducing experimental airborne transmission of Salmonella enteritidis to chicks. Poultry Sci., 78: 57–61.Search in Google Scholar

Goel N., Terman M., Terman J.S., Macchi M.M., Stewart J.W. (2005). Controlled trial of bright light and negative air ions for chronic depression. Psychol. Med., 35: 1–11.Search in Google Scholar

Hagbom M., Nordgren J., Nybom R., Heldlund K.O., Wigzell H., Svensso n L. (2015). Ionizing air affects influenza virus infectivity and prevents airborne-transmission. Sci. Rep., 23: 1–10.Search in Google Scholar

Hagen D. (2012). Ionic system aids air quality for nursery pigs. Feedstuffs, 26: 16–21.Search in Google Scholar

Herbut E., Nizioł B., Pietras M. (1995). Preliminary studies on the effect of thermal environment and air ionization on selected haematological parameters and productivity of broiler chickens (in Polish). Rocz. Nauk. Zoot., 22: 395–403.Search in Google Scholar

Herbut E., Nizioł B., Pietras M., Sosnówka E. (1997 a). Effect of humidity and artificial air ionization on negative ion concentration and performance of broiler chickens (in Polish). Rocz. Nauk. Zoot., 24: 181–188.Search in Google Scholar

Herbut E., Nizioł B., Sosnówka E., Pietras M. (1997 b). Effect of thermal conditions on air ionization and rearing performance of broiler chickens (in Polish). Rocz. Nauk. Zoot., 24: 301–306.Search in Google Scholar

Huynh T.T.T., Aarnink A.J.A., Verstegen M.W.A., Gerrits W.J.J., Heetkamp M.J.W., Kemp B., Canh T.T. (2005). Effects of increasing temperatures on physiological changes in pig different relative humidities. J. Anim. Sci., 83: 1385–1396.Search in Google Scholar

Iwama H. (2004). Negative air ions created by water shearing improve erythrocyte deformability and aerobic metabolism. Indoor Air, 14: 293–297.Search in Google Scholar

Janowski T., Nizioł B., Zimmal S. (1989). Studies on air ionization in poultry houses with different degrees of ventilation (in Polish). Acta Agr. Silv. Zoot., 28: 19–23.Search in Google Scholar

Jovanić B.R., Jovanić S.B. (2001). The effect of high concentration of negative ions in the air on the chlorophyll content in plant leaves water. Air Soil Pollut., 129: 259–265.Search in Google Scholar

Kellog E.W. (1984). Significance of air ions. J. Bioelectr., 3: 119–136.Search in Google Scholar

Khrenov N.M. (1987). Artificial aeroionization and its influence on the productivity and reproductive functions of the cow. Proc. Int. Symp.: Microphysical problems in biology versus animal hygiene, Kraków, Poland, 1–3.06.1987.Search in Google Scholar

Kolar ž P., Gaisberger M., Madl P., Hofmann W., Ritter M., Hartl A. (2012). Characterization of ions at Alpine waterfalls. Atmos. Chem. Phys., 12: 3687–3697.Search in Google Scholar

Krueger A.P. (1985). The biological effect of air ions. Int. J. Biometerol., 29: 205–206.Search in Google Scholar

Laza V. (2010). Environmental factors (negative air ions) with beneficial effects on animals and humans. Revista de Igiena Si Sanatate Publica, J. Hyg. Public Health, 60: 62–69.Search in Google Scholar

Laza V., Bolboacă S.D. (2008). The effect of negative air ionization exposure on ontogenetic development of chicken. Leonardo El. J. Pract. Technol., 13: 76–87.Search in Google Scholar

Laza V., Lotrean L. (2009). Using the negative air generators to improve the animal reactivity. In: Vlad S., Ciupa R.V., Nicu A.I. (eds), MEDITECH 2009, IFMBE Proceedings, 26, pp. 157–162.10.1007/978-3-642-04292-8_35Search in Google Scholar

Lenkiewicz Z., Dąbrowska B., Schiffer Z. (1989). The influence of negative ionization of the air on motor activity in Syrian hamsters (Masocricetus auratus Waterhouse) in light conditions. Int. J. Biometorol., 33: 251–258.Search in Google Scholar

Mitchell B.W., Holt P.S., Seo K.H. (2000). Reducing dust in a caged layer room: An electrostatic space charge system. J. Appl. Poultry Res., 9: 292–296.Search in Google Scholar

Mitchell B.W., Richardson J., Wilson J., Hofacre C. (2004). Application of an electrostatic space charge system for dust, ammonia and pathogen reduction in a broiler breeder house. App. Eng. Agric., 20: 87–93.Search in Google Scholar

Moga M., Małecka I. (2011). The effect of differentiated air on the human organism (in Polish). Zesz. Nauk. Inż. Ląd. Wod. Kształt. Środow., 4: 26–29.Search in Google Scholar

Nizioł B. (1987). The composition of air-ions and their effect on human and animal organisms. Proc. Int. Symp.: Microphysical problems in biology versus animal hygiene. Kraków, Poland, 1–3.06.1987.Search in Google Scholar

Pająk T. (2011). Effect of air ionization on the microclimate, well-being and productivity of pigs (in Polish). Praca doktorska, IZ PIB, Kraków-Balice.Search in Google Scholar

Patil V.N., Patil B.P., Shimpi N.G. (2014). Effect of negative ionization on egg incubation and burn patient. Wulfenia, 21: 125–142.Search in Google Scholar

Pawar S.D., Meena G.S., Jadha v D.B., (2012). Air ion variation at poultry-farm, coastal, mountain, rural and urban sites in India. Aerosol Air Qual. Res., 12: 440–451.Search in Google Scholar

Rademacher C., Bradley G., Pollmann S., Coffelt B., Baumgartner M., Baumgartner J., (2012). Electrostatic particle ionization (EPI) improves nursery pig performance and air quality. Proc. AASV. Integrating Science, Welfare, and Economics in Practice, Denver USA, pp. 257–258.Search in Google Scholar

Richardson L.J., Hofacre C.L., Mitchell B.W., Wilson J.L. (2003). Effect of electrostatic space charge on reduction of airborne transmission of Salmonella and other bacteria in broiler breeders in production and their progeny. Avian Dis., 47: 1352–1361.Search in Google Scholar

Ritz C.W., Mitchel B.W., Fairchild B.D., Czarick M., Worley J.W. (2006). Improving in-house air quality in broiler production facilities using an electrostatic space charge system. J. Appl. Poultry Res., 15: 333–340.Search in Google Scholar

Skromulis A., Noviks G. (2012). Atmospheric light air ion concentrations and related meteorological factors in Rezekne City, Latvia. J. Environ. Boil., 33: 455–462.Search in Google Scholar

Wakamura T., Sato M., Dohi T., Ozaki K., Ason N., Hagata S., Tokura H. (2004). A preliminary study on influence of negative air ions generated from pajamas on core body temperature and salivary IgA during night sleep. Int. J. Occup. Med. Env., 17: 295–298.Search in Google Scholar

Walczak J., Herbut E. (2000). The use of telemetric measurement of biophysical parameters for evaluating the response of growing pigs to different management systems. Ann. Anim. Sci., 27: 231–239.Search in Google Scholar

Wallner P., Kundi M., Panny M., Tappler P., Hutter H.P. (2015). Exposure to air ions in indoor environments: experimental study with healthy adults. Int. J. Environ. Res. Public Health, 12: 14301–14311.Search in Google Scholar

Wiszniewski A., Suchanowski A. (2008). Influence of air-ions on people subjected to physical effort and at rest. Pol. J. Environ. Stud., 17: 801–810.Search in Google Scholar

Wiszniewski A., Suchanowski A., Wielgomas B. (2014). Effects of air-ions on human circulatory indicators. Pol. J. Environ. Stud., 23: 521–531.Search in Google Scholar

Articoli consigliati da Trend MD

Pianifica la tua conferenza remota con Sciendo