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Wpływ infradźwięków i hałasu o niskich częstotliwościach na człowieka – przegląd piśmiennictwa

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EN
The influence of infra- and low-frequency sound on human – a review of the literature
Języki publikacji
PL
Abstrakty
PL
Infradźwięki są naturalnym zjawiskiem w świecie, a hałas infradźwiękowy powszechnie występuje w pobliżu dróg komunikacyjnych i w środowisku miejskim. W ostatnich latach znacznie wzrosło zainteresowanie infradźwiękami, zarówno ze względu na rozwój technologii wytwarzających infradźwięki i rosnący odsetek populacji eksponowany na ten hałas, jak i licznych niejasności z nim związanych. Z fizycznego punktu widzenia infradźwięki niczym nie różnią się od dźwięków słyszalnych czy ultradźwięków. Są zmianami ciśnienia rozchodzącymi się w postaci fal akustycznych w środowisku materialnym: ciałach stałych, cieczach i gazach. W niniejszym artykule będą rozważane tylko dźwięki rozchodzące się w powietrzu. Podział fal dźwiękowych na infradźwięki, dźwięki słyszalne i ultradźwięki wynika z tradycji i ma swoje korzenie w historycznych już badaniach wrażliwości narządu słuchu w funkcji częstotliwości, gdy skalę dźwiękową, z uwagi na ówczesne możliwości aparatury generującej sygnały akustyczne, podzielono na dźwięki słyszalne od 20 do 20 000 Hz i dźwięki niewywołujące u człowieka wrażenia słuchowego. Zaliczenie dźwięków o częstotliwościach < 20 Hz do dźwięków niesłyszalnych było podyktowane także i tym, że badane osoby określały słyszenie dźwięków z tego zakresu, nie jako słyszenie tonów w „normalnym” sensie, lecz raczej jako odczucie „ucisku” w uszach czy dudnienie, buczenie, a ponadto sygnały o niskich częstotliwościach najpierw były odbierane przez receptory drgań (Moore 1999). Ponadto, zarówno w przypadku dźwięków < 20 Hz, jak i dźwięków > 20 000 Hz problemem były, ograniczone wówczas, technicznie możliwości wytworzenia dźwięków o pożądanych parametrach. Dźwięki o częstotliwości poniżej 20 Hz nazywa się infradźwiękami (w niektórych pracach za górną gra-nicę infradźwięków przyjęto częstotliwość 16 Hz), a dźwięki o częstotliwościach powyżej 20 000 Hz nazwano ultradźwiękami (w niektórych pracach za dolną granicę ultra-dźwięków przyjęto częstotliwość 16 000 Hz). Istnieje wiele źródeł emitujących dźwięki o częstotliwościach poza zakresem 20 ÷ 20 000 Hz zarówno naturalnych, jak i antropogenicznych.
EN
Infrasound is traditionally defined as low-frequency sound that is inaudible. Infrasound is acoustic energy with a frequency below 16Hz or 20 Hz and both frequency limits are used. There is no agreement regarding a definition of infrasonic noise. According to Polish standard PN-N-01338:1986, noise whose spectrum consists of sounds with frequencies below 50 Hz is called infrasonic noise, but in literature the term low-frequency noise is more common and 250 Hz is usually considered its upper-frequency limit. Besides a natural origin sources of infrasound like volcanoes, tornados, snow avalanches or less intensive ones like sounds of some animals, etc., there are many human origin sources, e.g., air transport, heavy trucks, compressors, ventilation, air-conditioning systems and more recently wind farms. The latter are spreading as alternative renewable sources of energy. That is why interest in infrasound has recently in-creased. Infrasound, contrary to traditional opinion about its inaudibility, is perceived by our body through our hearing organ and perception via mechanoreceptors has been reported when the infrasound is sufficiently strong. Its audibility depends on the acoustic pressure level and re-quires a much higher level than in the conventional range (20 ÷ 20000 Hz). Infrasound at an extreme high level above 175 dB induces aural pain and could destroy the middle and inner ear (eardrum rupture occurs at 185 ÷ 190 dB). Exposure to infrasound induces temporary threshold shift of hearing. Data on permanent hearing effects are scarce and this problem requires further research. The vestibular organ seems to be sensitive. There are some studies reporting that exposure to infrasound elicits nystagmus (eye movements) from both animals and humans and can result in nausea and giddiness. Subjects exposed to infrasound at a high level (above 130 dB) have reported body vibration. In the region of 40 ÷ 80 Hz the lungs, and below 10 Hz the chest, head and abdomen are resonated. Some results on infrasound were the basis for acoustic weapons. The most prominent effect of infrasound is annoyance, especially in non-occupational exposure but extra-aural effects of exposure are very large in dependence of levels, frequency, circumstances and the subject’s sensitivity. The following have been reported: temporary changes in EEG, sleep disturbances, changes in the cardiovascular system and blood pressure, changes in the digestive and endocrine systems and many others. Tiredness, drowsiness, reduction in concentration ability and performance have been shown as well. Experiments with animals supported human results, however, summing up there are many inconsistencies between the results of different research centres. For over 25 years a team led by Alves-Pereira and Castelo Branco has published many papers on the vibroacoustic disease (VAD). According to their hypothesis exposure to low-frequency noise causes many pathological changes called VAD. The list of symptoms is long, starting with mood and behavioral abnormalities that are early findings related to stage 1 of VAD through in-creased irritability and aggressiveness, a tendency for isolation, depressions and decreased cogni-tive skills to psychiatric disorders, hemorrhages, ulcers, neurological problems, muscle pain and many others at VAD stage III. So far, nobody other than Alves-Pereira and Castelo Branco’s team has reported VAD. Therefore, their hypothesis seems to be original but controversial. Lack or scarcity of evidence should be filled by multicenter research based on scientific methods including epidemiological studies. Some problems with the effect of infrasound on human have resulted from the inconsistency in various authors’ measurements of low-frequency noise. There are some regulations related to infrasound and low-frequency noise, e.g., in Sweden, France, Russia, New Zealand and recently Poland. There is also a recommendation of the American Conference of Governmental Industrial Hygienists for ceiling levels of infrasound in occupational settings. Besides, some countries established national criteria for low-frequency noise in the environment or indoors (Denmark, the Netherlands, Germany, the UK, Sweden and Po-land). Summarizing, it should be emphasised that further research on the health effect of infrasound on human are necessary; especially the hypothesis of VAD should be investigated by multi-center research to be confirmed or refuted. Research should be performed using standardized methods of measurement and equipment. So nowadays to establish TLVs for low-frequency noise in occupational settings further research is necessary.
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  • Akademia Medyczna im. Piastów Śląskich we Wrocławiu 50-365 Wrocław ul. Pasteura 1
Bibliografia
  • 1.ACGIH (1998) Threshold limit values for chemical substances and physical agents TLV’s and BEI’s, 113.
  • 2..Adams M., Moorhouse A., Waddington D. (2008) Social effects of low frequency noise expo-sure on sufferers; developing a procedure of assessment NVB 2008. J. Low. Freq. Noise Vibr. Active Control 113–122 [reprint].
  • 3.Alekseev S.V. (1985) Myocardial ischemia in rats exposed to infrasound. Gigiena Truda i Prof. Zabolewania 8, 34–38.
  • 4.Altmann J. (1999) Acoustic weapons – A prospective assessment. Sources, propagation, and effects of strong sound. Ithaca NY, Peace Studies Program, Cornell University 1999.
  • 5.Altmann J. (2001) Acoustic weapons. A prospective assessment. Science & Global Security 9, 165–234.
  • 6.Alves-Pereira M. (1999) Noise-induced extra-aural pathology: a review and commentary. Aviat. Space Environ. Med. 70(3 Pt 2), A721.
  • 7.Alves-Pereira M., Castelo Branco N.A.A. (2007) Vibroacoustic disease. Biological effects of infrasound and low frequency noise explained by mechanotransduction cellular signaling. Progress in Biophysics and Molecular Biology 93, 256–279.
  • 8.Alves-Pereira M., Joanaz de Melo J., Castelo Branco N.A.A. (2004a) Public transportation and low frequency noise, a health hazard? [W:] Proceedings of the 11th International Congress on Sound and Vibration. St. Petersburg, Russia, 1761–1766.
  • 9.Alves-Pereira M., Joanaz de Melo J., Castelo Branco, N.A.A. (2004b) Low frequency noise in trains. [W:] Proceedings of Internoise (2004). Prague, Czech Republic 643, 5.
  • 10.Arlinger S.D. (1991) Normal hearing threshold levels in the low-frequency range determined by an insert earphone. The Journal of the Acoustical Society of America. Vol. 90, issue 5, 2411–2414.
  • 11.ASA/NOISE-CON (2000, wersja z 20.08.2008) Daniel Raichel Boom Cars: Noise Pollution at its Worst [www.acoustics.org/press/140th/raichel2.htm].
  • 12.Babisch W. (1998) Epidemiological studies of the cardiovascular effcts of occupational noise – a critical appraisal. Noise and Health 1, 24–39.
  • 13.Babisch W. (2004) Health effects related to stress mechanisms – cardiovascular effects. [W:] WHO, Report on the second meeting on night noise guidelines. Geneve 2004, 9–10.
  • 14.Bedard A.J. (2000) Detection of infrasound from natural and civilization sources: measurement of complex signal/noise environments. Geoscience and Remote Sensing Symposium. Proceed-ings. IGARSS. IEEE 2000 International vol. 3, issue 1195–1197.
  • 15.Bedard A.J., George T.M. (2000) Atmospheric infrasound. Physics Today 53(3) 32–37.
  • 16.Bengtsson J., Peroson Waye K., Kjellberg A. (2004) Evaluations of effects due to low frequency noise in low demanding work situation. J. Sound. Vibr. 278, 83–99.
  • 17.Bengtsson J. (2003) Low frequency noise during work – effects on performace and annoyance. Thesis Goteborg University.
  • 18.Berger E. H. (1996) Protection for infrasonic and ultrasonic noise exposure. Monographie technique [http://www.e-a-r.com/pdf/hearingcons/earlog14.pdf].
  • 19.Berglund B., Lindvall T., Schwela D.H. (1999) Guidelines for community noise, Genewa, DMS/WHO 94.
  • 20.Berglund B., Hassmen P., Job R.F. (1996) Sources and effects of low-frequency noise. J. Acoust Soc. Am. 99(5), 29853002.
  • 21.Berkow E.R., Beers, Fletcher M.A. (1997) The merck manual of medical information. Home edition. New York, Pocket Books 5, 94–5, 1089–1091.
  • 22.Bigert C., Bluhm G., Theorell T. (2005) Saliva cortisol – a new approach in noise research to study stress effects. Int. J. Hyg. Environ. Health 208, 227–230.
  • 23.Biuletyn Międzyresortowej Komisji ds. Aktualizacji Wykazu NDS i NDN Czynników Szkodli-wych dla Zdrowia w Środowisku Pracy (1986), z. 2, 77–105.
  • 24.Borredon P. (1980) Physiological effects of infrasounds in our everyday environment. [W:] Proceedings of the Conference on Low frequency Noise and hearing. Alborg University Press.
  • 25.British Wind Energy Association (February 2005) Low frequency noise and wind turbines. Technical Annex. 10 pages [http://www.bwea.com/pdf/lfn-annex.pdf].
  • 26.Bunsel R.G., Lehmann A.G. (1978) Infrasound and sound: differentiation of their psychophysio-logical effects through use of genetically deaf animals. JASA 63(3) 974–977.
  • 27.Buxton I. ( 2006, wersja wrzesień 2008) Low frequency noise and infrasound A literary com-ment [http://www.wind-watch.org/documents/wp-content/uploads/buxton-infrasoundandlandba-sedanimals.doc].
  • 28.Campo P., Damongeot A. (1991) La ponderation « A » est-elle un indicateur pertinent de la no-civite des bruits basse frequence? Étude bibliographique. Cahiers de Notes Documentaires 144, 3éme trimestre 1991, 485–492.
  • 29.Castelo Branco N.A., Rodriquez E. (1999) The vibroacoustic disease. An emerging pathology. Aviat. Space.
  • 30.Castelo Branco N.A., Ferreira J.R., Alves-Pereira M. (2007) Respiratory pathology in vibroac-oustic disease: 25 years of research. Revista Portuguesa De Pneumologia 13 (1), 129–35.
  • 31.Castelo Branco N.A. i in. (2008, wersja wrzesień) Monitoring vibroacoustic disease [http://www.noisefree.org/monitor.pdf].
  • 32.Cavallo D. i in. (2006) Occupational exposure in airport personel. Characterization and evalua-tion of genotoxic and oxidative effects. Toxicology 223, 26–35.
  • 33.Chatillon J. (2006) Limites d'exposition aux infrasons et aux ultrasons – Etude bibliographique, Hygiene et Securite du Travail, Cahiers de Notes Documentaires, INRS, 2éme trimestre 2006, 203.
  • 34.CIOP [http://www.ciop.pl/6541.html] (dane z 20.08.2008).
  • 35.Corso J.F. (1958) Absolute threshold for tones of low frequency. Am. J. Psychol. 71, 367–374
  • 36.Czynniki szkodliwe w środowisku pracy – wartości dopuszczalne (1998). Wyd I. Warszawa, CIOP–PIB.
  • 37.Danielsson A., Landstörm U. (1985)Blood presuure changes in man during infrasonic exposure. An experimental study. Acta Media Scandinavica, 217.5, 531-535
  • 38.Damijan Z., Wiciak J. (2005) The influence of LFN (low-frequency noise) on the changes of EEG signal morphology. Molecular and Quantum Acoustics 26, 61–74.
  • 39.Damijan Z., Wiciak J. (2007) The influence of LFN (low-frequency noise) on the changes of EEG signal morphology. Molecular and Quantum Acoustics 28, 65–70.
  • 40.Davis H.W. (2005) Occupational expousre to noise and mortality from acute myocardial infarc-tion. Epidemiology 16, 1, 25–32.
  • 41.Department for Environment, Food and Rural Affaires (Royaume-Uni). A Review of Published Research on Low Frequency Noise and its Effects. Report for Defra by Dr Geoff Leventhall Assisted by Dr Peter Pelmear and Dr Stephen Benton (2003) 88 [http://www.defra.gov.uk/ en-vironment/noise/lowfrequency/pgf/lowfreqnoise.pdf].
  • 42.Evans M.J., Tempest W. (1972) Some effcts of infrasonic noise in transportation. J. Sound and Vibration 22(1), 19–24.
  • 43.Frenzelli G. i in. (2004) Effects of loud noise exposure on DNA integrity in rat adrenal gland. Environmental Health Perspectives 112, 17, 1671–1672.
  • 44.Griefahn B. (2000) Noise-induced extraaural effects. Acoustical Science and Technology 21, 6, 307–317.
  • 45.Griffin M.J. (1990) Handbook of human vibration. London, Academic Press.
  • 46.Gorgeladze A.S., Glinchikov V.V., Usenko V.R. (1986) Experimental myocardial ischemia caused by infrasound. Gigiena Truda i Prof. Zabolewania 8, 30–33.
  • 47.Guest H. (2003) Inadequate standards currently applied by local authorities to determine statuto-ry nuisance from LF and infrasound. Journal of Low Frequency Noise, Vibration and Active Control 22, l, 1–7.
  • 48.Harris C.S., Sommer H.C., Johnsons D.L. (1976) Review of effects of infraosunds on man. Aviat Space Environ. Med. 47, 430–434.
  • 49.Hee G., Barbara J.J., Gros P. (1992) Valeurs limites d'exposition aux agents physiques en am-biance de travail. Cahiers de Notes Documentaires (1992) 148, 3éme trimestre. Mise á jour mai 1993. Référence INRS: ND 1886-148-92, 297–318.
  • 50.Hensel J. i in. (2007) Impact of infrasound on the human cochlea. Hearing Reaserach 233, 67–76.
  • 51.Holmberg K. i in. (1996) Hygienic assessment of low frequency noise annoyance in working environemnts. J. Low Freq. Noise Vibr. 15,1 7–15.
  • 52.Horror movies and low frequencies [http://wwwreallyscary.com/interviewdeltoro.asp] (wersja z 20.08.2008).
  • 53.[http://ntp-server.niehs.nih.gov/ntp/htdocs/Chem_Background/ExSumPdf/Infrasound.pdf]
  • 54.[http://www.ceere.org/rerl/publications/whitepapers/Wind_Turbine_Acoustic_Noise_Rev. 2006.pdf] (wersja wrzesień 2008).
  • 55.[http://www.ninapierpont.com/pdf/Effects_of_low_frequency_noise_on_sleep.pdf].
  • 56.[http://www.scribd.com/doc/430696/Survey-Low-Frequency-Noise-Aviation-Workers].
  • 57.Huang Qibay C.Y., Shi H. (2004) An investigation on the physiological and psychological ef-fects of infrasound on persons. Journal of Low Frequency Noise. Vibration and Active Control 23(l), 71–76.
  • 58.Infrasound brief review of toxicological literature (2001) [http://ntp.niehs.nih.gov/ntp/htdocs/ Chem_Background/ExSumPdf/Infrasound.pdf].
  • 59.ISO 226 (1987) Normal equall-loudness level contours. ISO 226: 2003 Aout 2003. Acoustique – Lignes isosoniques normales.
  • 60.ISO 389-7.1996 Reference zero for calibration of audiometric equipment – Part 7. Reference threshold of hearing under free-field and diffuse-field listening conditions.
  • 61.ISO 7196:1995 Acoustics – Frequency – weighting characteristic for infrasound measurements. ISO 7196:1995 Acoustics. Methods for describing infrasound with respect to its effects on hu-mans.
  • 62.ISO 9612:1997 Acoustics. Guidelines for the measurement and assessment of exposure to noise in the working environment.
  • 63.Iwahashi K., Ochiai H. (2001) Infrasound pressure meter and examples of measuring data. Journal of Low Frequency Noise. Vibration and Active Control. 20, l, 15–19.
  • 64.Jakobsen J. (2001) Danish guidelines on environmental low frequency noise, infrasound and vibration. Journal of Low Frequency Noise. Vibration and Active Control. (20)3, 141–148. 65.Jacobsen J. (2005) Infrasound emission from wind turbines. J. Low Freq. Noise. Vibr. Active Control 24, 3, 145–155.
  • 66.Johnson D.L. (1980) The effects of high level infrasound. Porceed of Conference on Low Fre-quency. Noise, Moller H. &Rubak P Aaalbork 1–14.
  • 67.Johnson D.L. (1982) Hearing hazards associated with infrasound. [W:] New perspectivees on noise-induced hearing. Loss New York, Raven Press 407–421.
  • 68.Johnson D.L. (1997) Proposed TLV for infrasound and low frequency noise [niepublikowana dokumentacja dla zespołu ekspertów ACGIH, Physical Agents TLV’s].
  • 69.Kaczmarska-Kozłowska A., Augustyńska D. (1992) Study of sound insulation of control cabins in industry in the low frequency range. Journal of Low Frequency Noise. Vibration and Active Control, II, 2, 42–46.
  • 70.Kaczmarska A., Augustyńska D. (1999) Ograniczenie hałasu niskoczęstotliwościowego w kabinach przemysłowych. Warszawa, CIOP.
  • 71.Kaczmarska A., Augustyńska D., Wierzejski A. (2006) Hałas infradźwiękowy na stanowiskach pracy kierowców. Bezpieczeństwo Pracy 10, 6–7.
  • 72.Kjellberg A. i in. (1997) Evaluation of frequency – weighted sound level measurements for pre-diction of low frequency noise annoyance. Environ. International 23, 4 519–527.
  • 73.Landström U. (1987) Laboratory and field studies on infrasound and its effects on humans. Journal of Low Frequency Noise, Vibration and Active Control 6, l, 29–33.
  • 74.Landström U., Landström R., Byström M. (1983) Exposure to infrasound. Perception and changes in wakefulness. Journal of Low Frequency Noise. Vibration and Active Control. 2, l, L–ll.
  • 75.Landström U. i in. (1982) Changes in wakefulness during exposure to infrasound. J. Low. Freq. Noise Vibr. 1,2, 79–87.
  • 76.Landström U., Byström M. (1984) Infrasonic threshold levels of physiological effects. J. Low Freq. Noise Vibr. 3(4) 167–173.
  • 77.Legislation hinders resaerch into low frequency noise [http://kondor.etf.bg.ac.yu/~vm/ cd1/ papers/135.pdf].
  • 78.Leighton T.G. (2007) Rapporteur report. Mechanism and interaction. Progress in Biophysics and Molecular Biology 93, 256–279.
  • 79.Lenzi P. i in. (2003) DNA damage associated wit ultrastructural alteration in rat myocardium after loud noise exosure. Environmental Health Perspectives 111, 4, 467–471.
  • 80.Leventhall G.A. (2003) Review of published research on low frequency noise and its effects. Report for DEFRA.
  • 81.Leventhall H.G. (2004) Low frequency noise and annoyance. Noise and Health 6(23), 5972. 82.Leventhall G. (2007) What is infrasound? Progress in Biophysics and Molecular Biology 93, 130–137.
  • 83.Lim D.J. i in. (1982) Trauma of the ear from infrasound. Acta Oto-Laryngol 94(3-4), 213–231.
  • 84.Mahendra Prashanth K., Sridar V. (2008) The relashonship between noise frequency compo-nents and physical, physiological and psychological effects of industrail workers. Noise and Health 10, 90–98.
  • 85.Maschke C., Rupp T., Hecht K. (2000) The influence of stressors on biochemical reactions – a review of present scientific findings with noise. Int. J. Hyg. Environ. Health 203, 45–53. 86.Mirowska M. (2002) An investigation and assessment of annoyance of low frequency noise in dwellings. Noise Notes vol. 1, 1, 30–34.
  • 87.Mohr G.C. i in. (1965) Effects of low frequency and infrasonic noise on man. Aerospace Medi-cine 36(9), 817–824.
  • 88.Moller H. (1987) Annoyance of audible infrasound. J. Low Freq. Noise Vibr 6(1), 1–17.
  • 89.Moller H., Pedersen C.S. (2004) Hearing at low and infrasonic frequencies. Noise and Health 6(23), 37–57.
  • 90.Moore B.C.J. (1999) Wprowadzenie do psychologii słyszenia. Warszawa, PWN 66–73. 91.Nekhoroshew A.S. (1986) Exposure to low frequency narrow band noise and reaction of stria vascularis vessles. Vest, Otorinolaringol 6, 17–19.
  • 92.Nishimura K.K. (1987) The pituitary adrenocortical response in rats and human subjects exposed to infrasound. Journal of Low Frequency Noise & Vibration 6. 1, 18–28.
  • 93.Noble J.M. (2008, wersja z dnia 20.08.) Tenney SM Detection of naturally occurring events from small aperture infrasound arrays [http://www.tornadochaser.net/research/ infasonicdetector.pdf].
  • 94.Okai O. i in. ( 1980) Physiological parameters in human response to infrasound. [W:] Proceed-ings of the Conference on Low Frequency Noise and Hearing. Aalborg, University Press 234–254.
  • 95.Okai O. i in. (1983) Infrasound generated by human body. Proceedings of Internoise 83, 239–242.
  • 96.Okamoto K. i in. (1986) The influence of infrasound uponhuman body. Sangyo Ika Da-igaku Zasshi 8(Suppl.), 135–149. (Japanese).
  • 97.Pawlaczyk-Łuszczyńska M. i in. (2003) Assessment of annoyance from low frequency and broadband noise. Int. J. Occupal. Med. Environe Health 16, 4 337–343.
  • 98.Pawlaczyk-Łuszczyńska M. i in. (2005) Ther impact of low frequency noise on human mental performance. Int. J. Occupal. Med. Environe. Health 18, 2 185–198. 61
  • 99.Pawlaczyk-Łuszczyńska M. i in. (2001) Hałas infradźwiękowy. Podstawy i Metody Oceny Środowiska Pracy 2(28), 5–45.
  • 100.Pawlaczyk-Łuszczyńska M. (2008) Hałas infradźwiękowy – jego oddziaływanie na organizm. Przegląd piśmiennictwa [Seminarium]. Warszawa, CIOP.
  • 101.Persson Waye K. i in. (1997) Effect on performance and work quality due to low frequency ven-tilation noise. J. Sound. Vibr. 203, 467–474.
  • 102.Persson Waye K. i in. (2002) Low frequency noise enhances cortisol among noise sensitive sub-jects during performance. Life Sciences 70, 745–758.
  • 103.Persson Waye K. i in. (2003) Effects of nighttime low frequnecy noise on cortisol response to awakening and subjective sleep quality. Life Sciences 72, 863–875.
  • 104.Persson Waye K. i in. (2004) Cortisol response and subjective sleep disturbance after low – fre-quency noise exposure. J. Sound. Vibr. 277, 453–457.
  • 105.Pimonow L. (1972) Les bruits. Etude documentaire relative aux effets des vibrations acoustiques sur l’organisme. Secretariat general de l’aviation civile.
  • 106.PN-86/N-01338. Hałas infradźwiękowy. Dopuszczalne wartości poziomów ciśnienia akustycz-nego na stanowiskach pracy i ogólne wymagania wykonywania pomiarów.
  • 107.PN-EN 61672-1:2005. Elektroakustyka – Mierniki poziomu dźwięku – Część 1. Wymagania.
  • 108.PN-N-01338:1986. Hałas infradźwiękowy. Wartości odniesienia poziomów ciśnienia akustycznego na stanowiskach pracy. Wymagania dotyczące wykonywania pomiarów i oceny [projekt roboczy z czerwca 2008, norma w nowelizacji].
  • 109.DEFRA (2005) Proposed criteria for the assessment of low frequency noise disturbance.
  • 110.Qibai C.Y.H., Shi H (2004) An investigation on the physiological and psychological effects of infrasound on persons. J. Low. Freq. Noise Vibr. Active Vontrol. 23,1, 71–76.
  • 111.Rosenlund M. i in. (2001) Increased prevalence of hypertension in a population exposed to air-craft noise. Occupational Environ Med. 58, 769–773.
  • 112.Rozporządzenie Rady Ministrów z dnia 30 lipca 2002 r. w sprawie wykazu prac wzbronionych młodocianym. DzU nr 127, poz. 1091; zm.: DzU 2005, nr 136, poz. 1145.
  • 113.Rozporządzenie Rady Ministrów z dnia 10 września 1996 r. w sprawie wykazu prac wzbronionych kobietom. DzU nr 114, poz. 545; zm.: DzU 2002, nr 127, poz. 1092.
  • 114.Rozporządzenie ministra pracy i polityki socjalnej z dnia 1 grudnia 1989 r. w sprawie najwyższych dopuszczalnych stężeń i natężeń czynników szkodliwych dla zdrowia w środowisku pra-cy. DzU nr 69, poz 417.
  • 115.Rozporządzenie ministra pracy i polityki socjalnej z dnia 23 grudnia 1994 r. i obwieszczenie z dnia 17 maja 1995 r. w sprawie najwyższych dopuszczalnych stężeń i natężeń czynników szko-dliwych dla zdrowia w środowisku pracy. DzU nr 3, poz. 16; z 1995 r. DzU nr 69, poz. 351. Rozporządzenie ministra pracy i polityki socjalnej z dnia 2 stycznia 2001 r. i z dnia 3 grudnia 2002 r. w sprawie najwyższych dopuszczalnych stężeń i natężeń czynników szkodliwych dla zdrowia w środowisku pracy. DzU nr 4, poz. 36; z 2002 r. nr 217, poz. 1832.
  • 116.Sandberg U. (1983) Combined effects of noise, infrasound and vibration on drivers perfor-mance. [W:] Proceedings of Inter-noise 887–890.
  • 117.Schust M. (2004) Effects of low frequency noise up tp 100 Hz. Noise and Health 6, 23, 73–85.
  • 118.Stark J. i in. (1994) The effetc of low frequency noise on postural stability. ACES 6(1-2), 83–88.
  • 119.Stepanow V. (2001) Biological effcta of low frequency acoustic oscillations and their hygienic regulation. Final report. Moskawa, State Research Center.
  • 120.Szelenberger W. (1982) Psycholofizjologiczne reakcje czlowieka na działanie fal infradźwiękowych. Materiały do Studiów i Badań nr 62. Warszawa, CIOP 31–43.
  • 121.Takahashi Y., Harada N. (2007) A consideration of an evaluation index for high – level low-frequency noise by taking into account the effect of human body vibration. J. Low. Freq. Noise Vibration&Active Control 26(1), 15–27.
  • 122.Takahashi Y. i in. (2005) A study on the realtionship between subjective unpleasantness and body surfuce vibration induced by high-level low-frequency pure tone. Industrial Heath 4, 580–587.
  • 123.Takahashi Y. i in. (1997) An infrasonic experiment for industrial hygiene. Industrial Heath 35, 480–488.
  • 124.Takahashi Y. i in. (1999) A pilot study on the human body vibration induced by low frequency noise. Industrial Health 37, 28–35.
  • 125.Tang S.K., Wong M.Y. (2004) On noise indices for domestic air conditioners 274, 1–12.
  • 126.Tempest W., Bryan M.E. (1972) Low frequency noise measurement in vehicles. Applied Acoustics 5, 133139.
  • 127.Tempest W. (1976) Infrasound and low frequency vibration. London, Academic Press.
  • 128.The largest organ in the wold [http://www.theatreorgan.com/atlcity/index2.htm wersja z 20.08.2008].
  • 129.Van der Berg (2005, wersja z 20.08.2008) Influence of low frequency noise on health and well-being. Informal Draft No GBR-41-8.
  • 130.Van der Berg M., Passhier-Vermeer W. (1999) Assessment of low frequency noise complaints. Proceed. Inter. Noise, Fort Lauderdale.
  • 131.Van Kempen E.E. i in. (2002) The association between noise exposure and blood pressure and ischemic heart disease: a meta-analysis. Environmental Health Perpectives 110, 3, 307–317.
  • 132.Von Gierke H.E., Nixon C. (1976) Effects of intense infrasound on man. [W:] Infrasound and Low Frequency Vibration. New York, Academic Press 197–203.
  • 133.Watanabe T., Moller H. (1990) Low frequency hearing threshold in pressure and in free field. J. of Low Frequency Noise and Vibration 9(3), 106–115.
  • 134.Waye K.P. (2005) Adverse effcts of moderate levels of low frequency noise in the occupational environment ASHRAE Transaction 111, Career and Technical Education 672–683.
  • 135.WHO, World Health Organization (1980) Environmental Health Criteria 12 – Noise. Infrasound (2001) Brief Review of Toxicological Literature 51.
  • 136.Yamada S. i in. (1983) Body sensation of low frequency noise of ordinary persons and pro-foundly deaf persons. J. Low Freq. Noise and Vibr. 2, 32–36.
  • 137.Yamazaki K., Tokita Y. (1984) Effects of infra and low frequency sound on sleep stage. Proceed-ings of Internoise 929–932.
  • 138.Yeowart N.S., Evens M.J. (1974) Threshold of audibility for very low frequency pure tones. JA-SA 55, 814–818.
  • 139.Yeowart N.S., Bryan M.E., Tempest W. (1967) Low frequency noise thresholds. J. of Sound and Vibration 9, 447–453.
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