Abstract
Purpose
Neonates and infants frequently undergo MRI examinations of the brain or head and neck in spontaneous respiration. This study aims to evaluate the patency of the upper airway and associated risk factors in spontaneously breathing neonates and infants undergoing MRI of head and neck.
Methods
Airway patency was assessed on sagittal and axial MRI images of the head and neck region for neonates and infants retrospectively. Anteroposterior diameters were measured at the soft palate and tongue levels as well as a lateral diameter at the tongue level for the patent airway. Chart review for risk factors was carried out.
Results
A total of 831 children between 0 and 12 months of age had an MRI. Eighty-two children with spontaneous ventilation were included. The airway was occluded in 29/82 (35 %) of children. Twenty-four out of 29 (83 %) children with airway occlusion had a depressed level of consciousness, 7/24 (29 %) of whom were sedated with a single dose of benzodiazepine and 17/24 (71 %) were on anti-epileptic therapy for an underlying seizure disorder and/or hypoxic ischemic encephalopathy. Forty-three out of 82 (65 %) of children had an open airway. The airway diameters (mean ± SD) were 5.9 ± 2 mm (anteroposterior (AP) at soft palate), 7.4 ± 2.9 mm (lateral at soft palate), and 6.3 mm ± 1.6 (AP at dorsum of tongue).
Conclusion
A significant proportion of spontaneously breathing neonates and infants with hypoxic ischemic encephalopathy or sedation show evidence of airway obstruction during MRI. Careful pre-MRI screening for decision of spontaneous breathing versus artificial airway support during MRI and robust airway monitoring during MRI are required for these vulnerable children.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Safar P, Escarraga LA, Chang F (1959) Upper airway obstruction in the unconscious patient. J Appl Physiol 14:760–764
Safar P (1958) Ventilatory efficacy of mouth-to-mouth artificial respiration; airway obstruction during manual and mouth-to-mouth artificial respiration. J Am Med Assoc 167:335–341
Cote CJ, Notterman DA, Karl HW, Weinberg JA, McCloskey C (2000) Adverse sedation events in pediatrics: a critical incident analysis of contributing factors. Pediatrics 105:805–814
Edwards AD, Arthurs OJ (2011) Paediatric MRI under sedation: is it necessary? What is the evidence for the alternatives? Pediatr Radiol 41:1353–1364
Elwood T, Hansen LD, Seely JM (2001) Oropharyngeal airway diameter during sedation in children with and without developmental delay. J Clin Anesth 13:482–485
Reber A, Paganoni R, Frei FJ (2001) Effect of common airway manoeuvres on upper airway dimensions and clinical signs in anaesthetized, spontaneously breathing children. Br J Anaesth 86:217–222
Montravers P, Dureuil B, Desmonts JM (1992) Effects of i.v. midazolam on upper airway resistance. Br J Anaesth 68:27–31
Sussman CB, Weiss MD (2013) While waiting: early recognition and initial management of neonatal hypoxic-ischemic encephalopathy. Adv Neonatal Care 13:415–423, quiz 424–415
Glass HC (2014) Neonatal seizures: advances in mechanisms and management. Clin Perinatol 41:177–190
Cote CJ, Karl HW, Notterman DA, Weinberg JA, McCloskey C (2000) Adverse sedation events in pediatrics: analysis of medications used for sedation. Pediatrics 106:633–644
Pirila-Parkkinen K, Lopponen H, Nieminen P, Tolonen U, Paakko E, Pirttiniemi P (2011) Validity of upper airway assessment in children: a clinical, cephalometric, and MRI study. Angle Orthod 81:433–439
Litman RS, Weissend EE, Shibata D, Westesson PL (2003) Developmental changes of laryngeal dimensions in unparalyzed, sedated children. Anesthesiology 98:41–45
Iwatani K, Matsuo K, Kawase S, Wakimoto N, Taguchi A, Ogasawara T (2013) Effects of open mouth and rubber dam on upper airway patency and breathing. Clin Oral Investig 17:1295–1299
Verin E, Series F, Locher C, Straus C, Zelter M, Derenne JP, Similowski T (2002) Effects of neck flexion and mouth opening on inspiratory flow dynamics in awake humans. J Appl Physiol (1985) 92:84–92
Sury MR, Hatch DJ, Deeley T, Dicks-Mireaux C, Chong WK (1999) Development of a nurse-led sedation service for paediatric magnetic resonance imaging. Lancet 353:1667–1671
Farrell MK, Drake GJ, Rucker D, Finkelstein M, Zier JL (2008) Creation of a registered nurse-administered nitrous oxide sedation program for radiology and beyond. Pediatr Nurs 34:29–35, quiz 35–26
Woodthorpe C, Trigg A, Alison G, Sury M (2007) Nurse led sedation for paediatric MRI: progress and issues. Paediatr Nurs 19:14–18
Kannikeswaran N, Chen X, Sethuraman U (2011) Utility of endtidal carbon dioxide monitoring in detection of hypoxia during sedation for brain magnetic resonance imaging in children with developmental disabilities. Paediatr Anaesth 21:1241–1246
Conflict of interest
All authors report no conflict of interest
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Bosemani, T., Hemani, M., Cruz, A. et al. Assessment of upper airway patency in spontaneously breathing non-intubated neonates and infants undergoing conventional MRI of head and neck. Childs Nerv Syst 31, 1521–1525 (2015). https://doi.org/10.1007/s00381-015-2785-4
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00381-015-2785-4