Application of magnetic resonance imaging-compatible incubator in cranial magnetic resonance imaging for neonates: a multicenter prospective randomized clinical trial
LIU Lian1, ZHANG Peng2, XIA Hong-Ping3, WANG Bin4, MA Xue-Ling1, CHENG Guo-Qiang2, SHI Yuan1
Department of Neonatology, Children's Hospital of Chongqing Medical University/National Clinical Research Center for Child Health and Disorders/Ministry of Education Key Laboratory of Child Development and Disorders/Chongqing Key Laboratory of Pediatrics, Chongqing 400014, China
Abstract:Objective To study the safety and efficacy of magnetic resonance imaging (MRI)-compatible incubator in cranial MRI examination for neonates. Methods A total of 120 neonates who were hospitalized in three hospitals and needed to undergo MRI examination were randomly divided into a control group and an experimental group, with 60 neonates in each group. The neonates in the experimental group were transferred with MRI-compatible incubator and underwent cranial MRI examination inside the MRI-compatible incubator, and those in the control group were transferred using a conventional neonatal transfer incubator and then underwent MRI examination outside the incubator. The two groups were compared in terms of the primary efficacy index (total examination time), secondary efficacy indices (times of examination, MRI completion rate on the first day of use), and safety indices (incidence rate of adverse events and vital signs). Results There were no significant differences in total examination time, times of examination, and MRI completion rate on the first day of use between the two groups (P > 0.05). There were also no significant differences between the two groups in the incidence rate of adverse events and vital signs such as respiratory rate, heart rate, blood pressure, and blood oxygen saturation rate at different time points before and after examination (P > 0.05). Conclusions The use of MRI-compatible incubator does not significantly shorten the examination time of cranial MRI, but it does provide a relatively stable environment for examination with acceptable safety. There is a need for further studies with a larger population.
LIU Lian,ZHANG Peng,XIA Hong-Ping et al. Application of magnetic resonance imaging-compatible incubator in cranial magnetic resonance imaging for neonates: a multicenter prospective randomized clinical trial[J]. CJCP, 2020, 22(12): 1251-1255.
Hintz SR, Vohr BR, Bann CM, et al. Preterm neuroimaging and school-age cognitive outcomes[J]. Pediatrics, 2018, 142(1):e20174058.
[3]
Duerden EG, Halani S, Ng K, et al. White matter injury predicts disrupted functional connectivity and microstructure in very preterm born neonates[J]. Neuroimage Clin, 2019, 21:101596.
[4]
Barnette AR, Horbar JD, Soll RF, et al. Neuroimaging in the evaluation of neonatal encephalopathy[J]. Pediatrics, 2014, 133(6):e1508-e1517.
[5]
Tocchio S, Kline-Fath B, Kanal E, et al. MRI evaluation and safety in the developing brain[J]. Semin Perinatol, 2015, 39(2):73-104.
[6]
Bekiesińska-Figatowska M, Szkudlińska-Pawlak S, Romaniuk-Doroszewska A, et al. First experience with neonatal examinations with the use of MR-compatible incubator[J]. Pol J Radiol, 2014, 79:268-274.
[7]
Cho HH, Kim IO, Cheon JE, et al. Changes in brain magnetic resonance imaging patterns for preterm infants after introduction of a magnetic resonance-compatible incubator coil system:5-year experience at a single institution[J]. Eur J Radiol, 2016, 85(9):1564-1568.
[8]
O'regan K, Filan P, Pandit N, et al. Image quality associated with the use of an MR-compatible incubator in neonatal neuroimaging[J]. Br J Radiol, 2012, 85(1012):363-367.
[9]
Müller F, Proquitté H, Herrmann KH, et al. Comparison of image quality in brain MRI with and without MR compatible incubator and predictive value of brain MRI at expected delivery date in preterm babies[J]. J Perinat Med, 2020, 48(7):733-743.
[10]
Bekiesińska-Figatowska M, Helwich E, Rutkowska M, et al. Magnetic resonance imaging of neonates in the magnetic resonance compatible incubator[J]. Arch Med Sci, 2016, 12(5):1064-1070.
[11]
Almadhoob A, Ohlsson A. Sound reduction management in the neonatal intensive care unit for preterm or very low birth weight infants[J]. Cochrane Database Syst Rev, 2020, 1(1):CD010333.
[12]
Groenendaal F, de Vries LS. Fifty years of brain imaging in neonatal encephalopathy following perinatal asphyxia[J]. Pediatr Res, 2017, 81(1-2):150-155.
[13]
Smyser CD, Wheelock MD, Limbrick DD Jr, et al. Neonatal brain injury and aberrant connectivity[J]. Neuroimage, 2019, 185:609-623.
[14]
Barkovich MJ, Li Y, Desikan RS, et al. Challenges in pediatric neuroimaging[J]. Neuroimage, 2019, 185:793-801.
[15]
Rona Z, Klebermass K, Cardona F, et al. Comparison of neonatal MRI examinations with and without an MR-compatible incubator:advantages in examination feasibility and clinical decision-making[J]. Eur J Paediatr Neurol, 2010, 14(5):410-417.
[16]
Sirin S, Goericke SL, Huening BM, et al. Evaluation of 100 brain examinations using a 3 Tesla MR-compatible incubator-safety, handling, and image quality[J]. Neuroradiology, 2013, 55(10):1241-1249.
