Kara R Gouwens1,2, Nara S Higano2,3,4,5, Kaitlyn T Marks1, Julia N Stimpfl1, Erik B Hysinger2,3,4,5,6, Jason C Woods2,3,4,5,6,7, Paul S Kingma1,2,3,4,5,6. 1. The Perinatal Institute. 2. Cincinnati Bronchopulmonary Dysplasia Center. 3. Center for Pulmonary Imaging Research. 4. Department of Radiology, and. 5. Division of Pulmonary Medicine, Cincinnati Children's Hospital Medical Center, Cincinnati, Ohio; and. 6. Department of Pediatrics and. 7. Department of Radiology, University of Cincinnati College of Medicine, Cincinnati, Ohio.
Abstract
Rationale: Bronchopulmonary dysplasia is a heterogeneous lung disease characterized by regions of cysts and fibrosis, but methods for evaluating lung function are limited to whole lung rather than specific regions of interest. Objectives: Respiratory-gated, ultrashort echo time magnetic resonance imaging was used to test the hypothesis that cystic regions of the lung will exhibit a quantifiable Vt that will correlate with ventilator settings and clinical outcomes. Methods: Magnetic resonance images of 17 nonsedated, quiet-breathing infants with severe bronchopulmonary dysplasia were reconstructed into end-inspiration and end-expiration images. Cysts were identified and measured by using density threshold combined with manual identification and segmentation. Regional Vts were calculated by subtracting end-expiration from end-inspiration volumes in total lung, noncystic lung, total-cystic lung, and individual large cysts.Measurements and Main Results: Cystic lung areas averaged larger Vts than noncystic lung when normalized by volume (0.8 ml Vt/ml lung vs. 0.1 ml Vt/ml lung, P < 0.002). Cyst Vt correlates with cyst size (P = 0.012 for total lung cyst and P < 0.002 for large cysts), although there was variability between individual cyst Vt, with 22% of cysts demonstrating negative Vt. Peak inspiratory pressure positively correlated with total lung Vt (P = 0.027) and noncystic Vt (P = 0.015) but not total lung cyst Vt (P = 0.8). Inspiratory time and respiratory rate did not improve Vt of any analyzed lung region.Conclusions: Cystic lung has greater normalized Vt when compared with noncystic lung. Ventilator pressure increases noncystic lung Vt, but inspiratory time does not correlate with Vt of normal or cystic lung.
Rationale: Bronchopulmonary dysplasia is a heterogeneous lung disease characterized by regions of cysts and fibrosis, but methods for evaluating lung function are limited to whole lung rather than specific regions of interest. Objectives: Respiratory-gated, ultrashort echo time magnetic resonance imaging was used to test the hypothesis that cystic regions of the lung will exhibit a quantifiable Vt that will correlate with ventilator settings and clinical outcomes. Methods: Magnetic resonance images of 17 nonsedated, quiet-breathing infants with severe bronchopulmonary dysplasia were reconstructed into end-inspiration and end-expiration images. Cysts were identified and measured by using density threshold combined with manual identification and segmentation. Regional Vts were calculated by subtracting end-expiration from end-inspiration volumes in total lung, noncystic lung, total-cystic lung, and individual large cysts.Measurements and Main Results: Cystic lung areas averaged larger Vts than noncystic lung when normalized by volume (0.8 ml Vt/ml lung vs. 0.1 ml Vt/ml lung, P < 0.002). Cyst Vt correlates with cyst size (P = 0.012 for total lung cyst and P < 0.002 for large cysts), although there was variability between individual cyst Vt, with 22% of cysts demonstrating negative Vt. Peak inspiratory pressure positively correlated with total lung Vt (P = 0.027) and noncystic Vt (P = 0.015) but not total lung cyst Vt (P = 0.8). Inspiratory time and respiratory rate did not improve Vt of any analyzed lung region.Conclusions: Cystic lung has greater normalized Vt when compared with noncystic lung. Ventilator pressure increases noncystic lung Vt, but inspiratory time does not correlate with Vt of normal or cystic lung.
Entities:
Keywords:
neonatal; premature; respiratory physiology; tidal volume; ultrashort echo time
Authors: Stephanie L Merhar; Jean A Tkach; Jason C Woods; Andrew P South; Emily L Wiland; Mantosh S Rattan; Charles L Dumoulin; Beth M Kline-Fath Journal: Pediatr Radiol Date: 2017-05-03
Authors: Laura L Walkup; David J Roach; Chase S Hall; Nishant Gupta; Robert P Thomen; Zackary I Cleveland; Francis X McCormack; Jason C Woods Journal: Ann Am Thorac Soc Date: 2019-08
Authors: Laura L Walkup; Jean A Tkach; Nara S Higano; Robert P Thomen; Sean B Fain; Stephanie L Merhar; Robert J Fleck; Raouf S Amin; Jason C Woods Journal: Am J Respir Crit Care Med Date: 2015-11-15 Impact factor: 21.405
Authors: Erik A Jensen; Kevin Dysart; Marie G Gantz; Scott McDonald; Nicolas A Bamat; Martin Keszler; Haresh Kirpalani; Matthew M Laughon; Brenda B Poindexter; Andrea F Duncan; Bradley A Yoder; Eric C Eichenwald; Sara B DeMauro Journal: Am J Respir Crit Care Med Date: 2019-09-15 Impact factor: 21.405
Authors: Chamindu C Gunatilaka; Andreas Schuh; Nara S Higano; Jason C Woods; Alister J Bates Journal: Comput Biol Med Date: 2020-11-01 Impact factor: 4.589
Authors: Erick Forno; Steven H Abman; Jagdev Singh; Mary E Robbins; Hiran Selvadurai; Paul T Schumacker; Paul D Robinson Journal: Am J Respir Crit Care Med Date: 2021-08-01 Impact factor: 30.528
Authors: Chamindu C Gunatilaka; Erik B Hysinger; Andreas Schuh; Deep B Gandhi; Nara S Higano; Qiwei Xiao; Andrew D Hahn; Sean B Fain; Robert J Fleck; Jason C Woods; Alister J Bates Journal: Chest Date: 2021-06-19 Impact factor: 9.410