RSS-Feed abonnieren
DOI: 10.1055/s-0040-1708883
Tidal Breathing Parameters Measured by Structured Light Plethysmography in Newborns: Is It Feasible in Neonatal Intensive Care Unit?
Abstract
Objective Structured light plethysmography (SLP) is a novel and noncontact respiratory assessment technique. It provides tidal breathing measurement in patients difficult to cooperate. In this study, we aimed to determine data for tidal breathing parameters measured by SLP in newborns.
Study Design Infants between 2 and 5 days of life without having any respiratory symptoms were eligible for this observational study. In total, 5 minutes of tidal breathing was recorded using SLP (Thora-3Di, PneumaCare Ltd, Cambridge, U.K.) in each infant. Various tidal breathing parameters including timing indices, flow-based parameters, and regional parameters were obtained from SLP data.
Results A total of 57 infants underwent measurements in the study. Evaluable recordings from 42 term and 11 late preterm infants were analyzed. Median gestational age and birthweight of the infants were 38 (37–39) weeks and 3,195 (2,790–3,585) g, respectively. In terms of flow-based parameters, “tidal inspiratory flow at 50% of inspiratory volume divided by tidal expiratory flow at 50% of expiratory volume” was 1.29 (1.13–1.53). Relative contribution of the thorax to each breath in percentage was measured as 38.67 (28.21–43.60). Median values of left–right hemithoracic asynchrony and thoraco-abdominal asynchrony were 6.92 (5.35–9.04) and 17.96 (12.98–36.44) degrees in the study population, respectively. There were no differences in tidal breathing parameters except “hemithoracic asynchrony” between term and late preterm infants. Hemithoracic asynchrony was significantly lower in term neonates than late preterms.
Conclusion SLP was found to be feasible to obtain measures of tidal breathing parameters in newborns and it could be performed successfully even in the first days of life.
Keywords
structured light plethysmography - tidal breathing parameters - neonatal intensive care unit - newborn - respiratory functionPublikationsverlauf
Eingereicht: 29. November 2019
Angenommen: 19. Februar 2020
Artikel online veröffentlicht:
10. April 2020
© 2020. Thieme. All rights reserved.
Thieme Medical Publishers
333 Seventh Avenue, New York, NY 10001, USA.
-
References
- 1 Reiterer F, Sivieri E, Abbasi S. Evaluation of bedside pulmonary function in the neonate: from the past to the future. Pediatr Pulmonol 2015; 50 (10) 1039-1050
- 2 Motamedi-Fakhr S, Iles R, Barney A. et al. Evaluation of the agreement of tidal breathing parameters measured simultaneously using pneumotachography and structured light plethysmography. Physiol Rep 2017; 5 (03) e13124
- 3 Lauhkonen E, Cooper BG, Iles R. Mini review shows that structured light plethysmography provides a non-contact method for evaluating breathing patterns in children. Acta Paediatr 2019; 108 (08) 1398-1405
- 4 Hmeidi H, Motamedi-Fakhr S, Chadwick E. et al. Tidal breathing parameters measured using structured light plethysmography in healthy children and those with asthma before and after bronchodilator. Physiol Rep 2017; 5 (05) e13168
- 5 Ghezzi M, Tenero L, Piazza M, Zaffanello M, Paiola G, Piacentini GL. Feasibility of structured light plethysmography for the evaluation of lung function in preschool children with asthma. Allergy Asthma Proc 2018; 39 (04) e38-e42
- 6 Hmeidi H, Motamedi-Fakhr S, Chadwick EK. et al. Tidal breathing parameters measured by structured light plethysmography in children aged 2-12 years recovering from acute asthma/wheeze compared with healthy children. Physiol Rep 2018; 6 (12) e13752
- 7 Hooper SB, TePas AB, Kitchen MJ. Respiratory transition in the newborn: a three-phase process. Arch Dis Child Fetal Neonatal Ed 2016; 101 (03) F266-F271
- 8 Seppä VP, Pelkonen AS, Kotaniemi-Syrjänen A, Viik J, Mäkelä MJ, Malmberg LP. Tidal flow variability measured by impedance pneumography relates to childhood asthma risk. Eur Respir J 2016; 47 (06) 1687-1696
- 9 Giordano K, Rodriguez E, Green N. et al. Pulmonary function tests in emergency department pediatric patients with acute wheezing/asthma exacerbation. Pulm Med 2012; 2012: 724139
- 10 Brown K, Aun C, Jackson E, Mackersie A, Hatch D, Stocks J. Validation of respiratory inductive plethysmography using the qualitative diagnostic calibration method in anaesthetized infants. Eur Respir J 1998; 12 (04) 935-943
- 11 Bates JH, Schmalisch G, Filbrun D, Stocks J. ; European Respiratory Society/American Thoracic Society. Tidal breath analysis for infant pulmonary function testing. ERS/ATS task force on standards for infant respiratory function Testing. Eur Respir J 2000; 16 (06) 1180-1192
- 12 Mortola JP. How to breathe? Respiratory mechanics and breathing pattern. Respir Physiol Neurobiol 2019; 261: 48-54
- 13 Motamedi-Fakhr S, Wilson RC, Iles R. Tidal breathing patterns derived from structured light plethysmography in COPD patients compared with healthy subjects. Med Devices (Auckl) 2016; 10 (10) 1-9
- 14 Konno K, Mead J. Measurement of the separate volume changes of rib cage and abdomen during breathing. J Appl Physiol 1967; 22 (03) 407-422
- 15 Gershon AS, Warner L, Cascagnette P, Victor JC, To T. Lifetime risk of developing chronic obstructive pulmonary disease: a longitudinal population study. Lancet 2011; 378 (9795): 991-996
- 16 Niérat MC, Dubé BP, Llontop C. et al. Measuring ventilatory activity with structured light plethysmography (SLP) reduces instrumental observer effect and preserves tidal breathing variability in healthy and COPD. Front Physiol 2017; 8: 316
- 17 Ghezzi M, Tenero L, Piazza M, Bodini A, Piacentini G. Structured light plethysmography (SLP): management and follow up of a paediatric patient with pneumonia. Respir Med Case Rep 2017; 22 (22) 67-69