Publication

Preclinical quantification of air leaks in a physiologic lung model: Effects of ventilation modality and staple design

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Last modified
  • 05/21/2025
Type of Material
Authors
    Chad E Eckert, Ethicon Inc.Jason L Harris, Ethicon Inc.Jordan B Wong, Ethicon Inc.Suzanne Thompson, Ethicon Inc.Edmund S Kassis, Ethicon Inc.Masahiro Tsuboi, National Cancer Center Hospital EastHarald C Ott, Massachusetts General HospitalSeth Force, Emory University
Language
  • English
Date
  • 2018-01-01
Publisher
  • Dove Medical Press
Publication Version
Copyright Statement
  • © 2018 Eckert et al.
License
Final Published Version (URL)
Title of Journal or Parent Work
ISSN
  • 1179-1470
Volume
  • 11
Start Page
  • 433
End Page
  • 442
Grant/Funding Information
  • This work was supported by Ethicon, Inc. Staplers and reloads were purchased by Ethicon.
Abstract
  • Thoracic air leaks are a common complication following pulmonary resections. Limitations in clinical studies and preclinical models have hindered efforts to understand the pathophysiology of air leaks. With an emphasis on staple-line specific air leaks, we hypothesize that ventilation modality – intraoperative positive pressure vs postoperative negative pressure – and stapler design may play a role in air leaks. Methods: Using a novel physiologic lung model, air leaks associated with graduated and uniform staple designs were evaluated under positive and negative pressure ventilation, simulating perioperative breathing in porcine lungs. Air leak incidence, air leak volume, and air leak rate were captured along with ventilation pressure and tidal volume. Results: In all cases, negative pressure ventilation was associated with a higher occurrence of leaks when compared to positive pressure ventilation. Lungs leaked more air and at a faster rate under negative pressure ventilation compared to positive pressure ventilation. Graduated staple designs were associated with higher occurrence of leaks as well as larger leak rates when compared to uniform staples. Tissue thickness was not associated with differences in air leaks when tested with appropriate staple heights. Conclusion: Using a novel lung model to investigate the pathophysiology of air leaks, we have identified breathing modality and staple design as two important variables that may impact air leaks. This work will help guide device design and drive future studies in human tissue, and it may help inform clinical practice to ultimately improve patient outcomes.
Author Notes
  • Correspondence: Chad E Eckert, Ethicon Inc., Research and Development, 4545 Creek Road, Cincinnati, OH 45150, USA, Tel +1 513 337 8827, Email ceckert1@its.jnj.com
Keywords
Research Categories
  • Health Sciences, Medicine and Surgery
  • Health Sciences, Oncology

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