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Review
Impacts of magnetic resonance imaging noise on hearing function in fetus and infants
ZHAO Huifang  JIN Chao  YANG Jian 

Cite this article as: Zhao HF, Jin C, Yang J. Impacts of magnetic resonance imaging noise on hearing function in fetus and infants. Chin J Magn Reson Imaging, 2019, 10(7): 546-550. DOI:10.12015/issn.1674-8034.2019.07.013.


[Abstract] Magnetic resonance imaging (MRI) has been increasingly used for fetus and infants. The produced acoustic noise at MRI scan may cause hearing injury with improper hearing protection. Numerous studies have reported the auditory effects of MRI noise on adults. The fetus and infants present remarkably different auditory anatomy and function, and vulnerability to noise in contrast to adults. The systematic review concerning the impacts of MRI noise on this population is lacking. Thus, this article will introduce the auditory development, summarize the mechanism of noise-induced hearing impairment, and review the previous studies on the impact of MRI noise in fetus and infants for providing a useful reference in improving the safety of MRI examination.
[Keywords] noise;fetus;infant;auditory perception;magnetic resonance imaging

ZHAO Huifang Department of Radiology, the First Affiliated Hospital of Medical College, Xi’an Jiaotong University, Xi’an 710061, China

JIN Chao Department of Radiology, the First Affiliated Hospital of Medical College, Xi’an Jiaotong University, Xi’an 710061, China

YANG Jian* Department of Radiology, the First Affiliated Hospital of Medical College, Xi’an Jiaotong University, Xi’an 710061, China

*Correspondence to: Yang J, E-mail: cjr.yangjian@vip.163.com

Conflicts of interest   None.

ACKNOWLEDGMENTS  This study was supported by the National Key Research and Development Program of China No. 2016YFC0100300 National Natural Science Foundation of China No. 81471631, 81771810 and 51706178 the 2011 New Century Excellent Talent Support Plan of the Ministry of Education, China No. NCET-11-0438 China Postdoctoral Science Foundation No. 2017M613145 Shaanxi Provincial Natural Science Foundation for Youths of China No. 2017JQ8005 and the Clinical Research Award of the First Affiliated Hospital of Xi’an Jiaotong University No. XJTU1AF-CRF-2015-004
Received  2019-01-16
Accepted  2019-05-20
DOI: 10.12015/issn.1674-8034.2019.07.013
Cite this article as: Zhao HF, Jin C, Yang J. Impacts of magnetic resonance imaging noise on hearing function in fetus and infants. Chin J Magn Reson Imaging, 2019, 10(7): 546-550. DOI:10.12015/issn.1674-8034.2019.07.013.

[1]
Moore JK, Linthicum FH. The human auditory system: a timeline of development. Int J Audiol, 2007, 46(9): 460-478.
[2]
Birnholz JC, Benacerraf BR. The development of human fetal hearing. Science, 1983, 222(4623): 516-518.
[3]
Gerhardt KJ, Abrams RM. Fetal Exposures to Sound and Vibroacoustic Stimulation. J perinatol, 2000, 20 (Supl 1): 21-30.
[4]
Le TN, Straatman LV, Jane Lea, et al. Current insights in noise-induced hearing loss: a literature review of the underlying mechanism, pathophysiology, asymmetry, and management options. J Otolaryngol Head Neck Surg, 2017, 46(1): 41.
[5]
Rabinowitz PM, Deron G, Slade MD, et al. Audiogram notches in noise-exposed workers. Ear Hear, 2006, 27(6): 742-750.
[6]
Pierson LL, Gerhardt KJ, Rodriguez GP, et al. Relationship between outer ear resonance and permanent noise-induced hearing loss. Am J Otolaryngol, 1994, 15(1): 37-40.
[7]
Emmerich E, Richter F, Linss V, et al. Frequency-specific cochlear damage in guinea pig after exposure to different types of realistic industrial noise. Hear Res, 2005, 201(1-2): 90-98.
[8]
Suvorov G, Denisov E, Antipin V, et al. Effects of peak levels and number of impulses to hearing among forge hammering workers. Appl Occup Environ Hyg, 2001, 16(8): 816-822.
[9]
Saunders JC, Chen CS. Sensitive periods of susceptibility to auditory trauma in mammals. Environ Health Perspect, 1982, 44: 63-66.
[10]
Lenoir M. Supra-normal susceptibility to acoustic trauma of the rat pup cochlea. Physiol, 1979, 75(5): 521-524.
[11]
宋军芬,谯凤英.噪声性听力损失及防范措施.职业与健康, 2016, 32(14): 2009-2012.
[12]
Slepecky N. Overview of mechanical damage to the inner ear: noise as a tool to probe cochlear function. Hear Res, 1986, 22(1): 307-321.
[13]
Yamane H, Nakai Y, Takayama M, et al. Appearance of free radicals in the guinea pig inner ear after noise-induced acoustic trauma. Eur Arch Oto-Rhino-Laryngol, 1995, 252(8): 504-508.
[14]
Orrenius S, Zhivotovsky B, Nicotera P. Regulation of cell death: the calcium-apoptosis link. Nat Rev Mol Cell Biol, 2003, 4(7): 552-565.
[15]
Lynn S, Heidi S. Beyond newborn screening: early diagnosis and management of hearing loss in infants. J Nat Associ Neonat Nurses, 2005, 5(2): 104-112.
[16]
Starr AR, Amlie RN, Martin WH, et al. Development of auditory function in newborn infants revealed by auditory brainstem potentials. Pediatrics, 1978, 60(6): 831-839.
[17]
Seixas, SN. Predictors of hearing threshold levels and distortion product otoacoustic emissions among noise exposed young adults. Occupat Environ Med, 2004, 61(11): 899-907.
[18]
Sisto R, Chelotti S, Moriconi L, et al. Otoacoustic emission sensitivity to low levels of noise-induced hearing loss. J Acousti Society Am, 2007, 122(1): 387-401.
[19]
Job A, Raynal M, Kossowski M, et al. Otoacoustic detection of risk of early hearing loss in ears with normal audiograms: a 3-year follow-up study. Hear Res, 2009, 251(1-2): 10-16.
[20]
Margolis RH, Bass-Ringdahl S, Hanks WD, et al. Tympanometry in Newborn Infants 1 kHz Norms. J Am Academy Audiol, 2003, 14(7): 383.
[21]
Cho ZH, Park SH, Kim JH, et al. Analysis of acoustic noise in MRI. Magn Reson Imaging, 1997, 15(7): 815-822.
[22]
Hurwitz R, Lane SR, Bell RA, et al. Acoustic analysis of gradient-coil noise in MR imaging. Radiology, 1989, 173(2): 545-548.
[23]
Hattori Y, Fukatsu H, Ishigaki T. Measurement and evaluation of the acoustic noise of a 24.3 Tesla MR scanner. Nagoya J Med Sci, 2007, 69(1-2): 23-28.
[24]
Shellock FG, Ziarati M, Atkinson D, et al. Determination of gradient magnetic field-induced acoustic noise associated with the use of echo planar and three-dimensional, fast spin echo techniques. J Magn Reson Imaging, 1998, 8(5): 1154-1157.
[25]
Price DL, Wilde JP, Papadaki AM, et al. Investigation of acoustic noise on 15 MRI scanners from 0.2 T to 3 T. J Magn Reson Imaging, 2001, 13(2): 288-293.
[26]
Gierke V. Acoustics—determination of occupational noise exposure and estimation of noise-induced hearing impairment. ISO/DIS 1999. Am J Hospice Palliat Care, 1990, 38(9): 1001-1008.
[27]
David G. Safety guidelines for magnetic resonance imaging equipment in clinical use. Med Health Prod Regulat Agency, 2016: 14-14.
[28]
Expert Panel on MR Safety, Kanal E, Barkovich AJ, et al. ACR guidance document on MR safe practices: 2013. J Magn Reson Imaging, 2013, 37(3): 501-530.
[29]
Lalande NM, Hétu R, Lambert J. Is occupational noise exposure during pregnancy a risk factor of damage to the auditory system of the fetus? Am J Industr Med, 2010, 10(4): 427-435.
[30]
Macnab A, Chen Y, Gagnon F, et al. Vibration and noise in pediatric emergency transport vehicles: a potential cause of morbidity? Aviat Space Environment Med, 1995, 66(3): 212.
[31]
Philbin MK, Evans JB. Standards for the acoustic environment of the newborn ICU. J Perinatol, 2006, 26 (Supl 3): 27-30.
[32]
Glover P, Hykin J, Gowland P, et al. Assessment of the intrauterine sound intensity level during obstetric echo-planar magnetic resonance imaging. Br J Radiol, 1995, 68(814): 1090-1094.
[33]
Gerhardt KJ, Abrams RM, Kovaz BM, et al. Intrauterine noise levels produced in pregnant ewes by sound applied to the abdomen. Am J Obstetr Gynecol, 1988, 159(1): 228-232.
[34]
Ray JG, Vermeulen MJ, Bharatha A, et al. Association between mri exposure during pregnancy and fetal and childhood outcomes. JAMA, 2016, 316(9): 952.
[35]
Clements H, Duncan KR, Fielding K, et al. Infants exposed to MRI in utero have a normal paediatric assessment at 9 months of age. Br J Radiol, 2000, 73(866): 190-194.
[36]
Bouyssi-Kobar M, Du Plessis AJ, Robertson RL, et al. Fetal magnetic resonance imaging: exposure times and functional outcomes at preschool age. Pediatr Radiol, 2015, 45(12), 1823-1830.
[37]
Baker PN, Johnson IR, Harvey PR, et al. A three-year follow-up of children imaged in utero with echo-planar magnetic resonance. Am J Obstetr Gynecol, 1994, 170(1): 32-33.
[38]
Kok RD, de Vries MM, Heerschap A, et al. Absence of harmful effects of magnetic resonance exposure at 1.5 T in utero during the third trimester of pregnancy: a follow-up study. Magn Reson Imaging, 2004, 22(6): 851-854.
[39]
Reeves MJ, Brandreth M, Whitby EH, et al. Neonatal cochlear function: measurement after exposure to acoustic noise during in utero MR imaging. Int J Med Radiol, 2011, 257(3): 802-809.
[40]
Strizek B, Jani JC, Mucyo E, et al. Safety of MR Imaging at 1.5 T in Fetuses: a retrospective case-control study of birth weights and the effects of acoustic noise. Radiology, 2015, 275(2): 530-537.
[41]
Jaimes C, Delgado J, Cunnane MB, et al. Does 3-T fetal MRI induce adverse acoustic effects in the neonate? A preliminary study comparing postnatal auditory test performance of fetuses scanned at 1.5 and 3 T. Pediatr Radiol, 2019, 49(1): 37-45.
[42]
Gerhardt KJ, Abrams RM, Kovaz BM, et al. Intrauterine noise levels produced in pregnant ewes by sound applied to the abdomen. Am J Obstetr Gynecol, 1988, 159(1): 228-232.
[43]
王华伟,吴冰,刘敬,等. 3.0T磁共振对新生儿听力的影响.中华实用儿科临床杂志, 2015, 30(2): 99-101.
[44]
Sininger YS, Abdala C. Hearing threshold as measured by auditory brain stem response in human neonates. Ear Hear, 1996, 17(5): 395-401.
[45]
Sedat A, Mika V, Wei S, et al. Acoustic noise reduction in MRI using silent scan: an initial experience. Diagn Intervent Radiol, 2014, 20(4): 360-363.
[46]
Katsunuma A, Takamori H, Sakakura Y, et al. Quiet MRI with novel acoustic noise reduction. Magn Reson Materials Phys Biol Med, 2001, 13(3): 139-144.
[47]
Ravicz ME, Melcher JR. Isolating the auditory system from acoustic noise during functional magnetic resonance imaging: examination of noise conduction through the ear canal, head, and body. J Acoust Societ Am, 2001, 109(1): 216-231.
[48]
Nordell A, Lundh M, Horsch S, et al. The acoustic hood: a patient-independent device improving acoustic noise protection during neonatal magnetic resonance imaging. Acta Peadiatr, 2009, 98(8): 1278-1283.
[49]
Tkach JA, Li Y, Pratt RG, et al. Characterization of acoustic noise in a neonatal intensive care unit MRI system. Pediatr Radiol, 2014, 44(8): 1011-1019.
[50]
Mcjury M, Shellock FG. Auditory noise associated with mr procedures. J Magn Reson Imaging, 2000, 12(1): 37-45.

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