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Development of alginate and gelatin-based pleural and tracheal sealants

Gasek, Nathan ; Park, Heon E. ; Uriarte, Juan J. ; Uhl, Franziska E. LU ; Pouliot, Robert A. ; Riveron, Alexander ; Moss, Tovah ; Phillips, Zachary ; Louie, Jessica and Sharma, Ishna , et al. (2021) In Acta Biomaterialia 131. p.222-235
Abstract

Pleural and tracheal injuries remain significant problems, and an easy to use, effective pleural or tracheal sealant would be a significant advance. The major challenges are requirements for adherence, high strength and elasticity, dynamic durability, appropriate biodegradability, and lack of cell or systemic toxicity. We designed and evaluated two sealant materials comprised respectively of alginate methacrylate and of gelatin methacryloyl, each functionalized by conjugation with dopamine HCl. Both compounds are cross-linked into easily applied as pre-formed hydrogel patches or as in situ hydrogels formed at the wound site utilizing FDA-approved photo-initiators and oxidants. Material testing demonstrates appropriate adhesiveness,... (More)

Pleural and tracheal injuries remain significant problems, and an easy to use, effective pleural or tracheal sealant would be a significant advance. The major challenges are requirements for adherence, high strength and elasticity, dynamic durability, appropriate biodegradability, and lack of cell or systemic toxicity. We designed and evaluated two sealant materials comprised respectively of alginate methacrylate and of gelatin methacryloyl, each functionalized by conjugation with dopamine HCl. Both compounds are cross-linked into easily applied as pre-formed hydrogel patches or as in situ hydrogels formed at the wound site utilizing FDA-approved photo-initiators and oxidants. Material testing demonstrates appropriate adhesiveness, tensile strength, burst pressure, and elasticity with no significant cell toxicity in vitro assessments. Air-leak was absent after sealant application to experimentally-induced injuries in ex-vivo rat lung and tracheal models and in ex vivo pig lungs. Sustained repair of experimentally-induced pleural injury was observed for up to one month in vivo rat models and for up to 2 weeks in vivo rat tracheal injury models without obvious air leak or obvious toxicities. The alginate-based sealant worked best in a pre-formed hydrogel patch whereas the gelatin-based sealant worked best in an in situ formed hydrogel at the wound site thus providing two potential approaches. These studies provide a platform for further pre-clinical and potential clinical investigations. Statement of significance: Pneumothorax and pleural effusions resulting from trauma and a range of lung diseases and critical illnesses can result in lung collapse that can be immediately life-threatening or result in chronic leaking (bronchopleural fistula) that is currently difficult to manage. This leads to significantly increased morbidity, mortality, hospital stays, health care costs, and other complications. We have developed sealants originating from alginate and gelatin biomaterials, each functionalized by methacryloylation and by dopamine conjugation to have desired mechanical characteristics for use in pleural and tracheal injuries. The sealants are easily applied, non-cytotoxic, and perform well in vitro and in vivo model systems of lung and tracheal injuries. These initial proof of concept investigations provide a platform for further studies.

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organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Alginate, Dopamine conjugation, Gelatin, Lung, Methacryloyl, Pleura, Sealant, Trachea
in
Acta Biomaterialia
volume
131
pages
14 pages
publisher
Elsevier
external identifiers
  • pmid:34245891
  • scopus:85110448080
ISSN
1742-7061
DOI
10.1016/j.actbio.2021.06.048
language
English
LU publication?
yes
id
22c4a34c-03b3-47a7-8c3c-3db9dbb22d0c
date added to LUP
2021-09-07 10:55:16
date last changed
2024-06-15 15:47:31
@article{22c4a34c-03b3-47a7-8c3c-3db9dbb22d0c,
  abstract     = {{<p>Pleural and tracheal injuries remain significant problems, and an easy to use, effective pleural or tracheal sealant would be a significant advance. The major challenges are requirements for adherence, high strength and elasticity, dynamic durability, appropriate biodegradability, and lack of cell or systemic toxicity. We designed and evaluated two sealant materials comprised respectively of alginate methacrylate and of gelatin methacryloyl, each functionalized by conjugation with dopamine HCl. Both compounds are cross-linked into easily applied as pre-formed hydrogel patches or as in situ hydrogels formed at the wound site utilizing FDA-approved photo-initiators and oxidants. Material testing demonstrates appropriate adhesiveness, tensile strength, burst pressure, and elasticity with no significant cell toxicity in vitro assessments. Air-leak was absent after sealant application to experimentally-induced injuries in ex-vivo rat lung and tracheal models and in ex vivo pig lungs. Sustained repair of experimentally-induced pleural injury was observed for up to one month in vivo rat models and for up to 2 weeks in vivo rat tracheal injury models without obvious air leak or obvious toxicities. The alginate-based sealant worked best in a pre-formed hydrogel patch whereas the gelatin-based sealant worked best in an in situ formed hydrogel at the wound site thus providing two potential approaches. These studies provide a platform for further pre-clinical and potential clinical investigations. Statement of significance: Pneumothorax and pleural effusions resulting from trauma and a range of lung diseases and critical illnesses can result in lung collapse that can be immediately life-threatening or result in chronic leaking (bronchopleural fistula) that is currently difficult to manage. This leads to significantly increased morbidity, mortality, hospital stays, health care costs, and other complications. We have developed sealants originating from alginate and gelatin biomaterials, each functionalized by methacryloylation and by dopamine conjugation to have desired mechanical characteristics for use in pleural and tracheal injuries. The sealants are easily applied, non-cytotoxic, and perform well in vitro and in vivo model systems of lung and tracheal injuries. These initial proof of concept investigations provide a platform for further studies.</p>}},
  author       = {{Gasek, Nathan and Park, Heon E. and Uriarte, Juan J. and Uhl, Franziska E. and Pouliot, Robert A. and Riveron, Alexander and Moss, Tovah and Phillips, Zachary and Louie, Jessica and Sharma, Ishna and Mohammed, Benefsha and Dearborn, Jacob and Lee, Patrick C. and Jensen, Todd and Garner, John and Finck, Christine and Weiss, Daniel J.}},
  issn         = {{1742-7061}},
  keywords     = {{Alginate; Dopamine conjugation; Gelatin; Lung; Methacryloyl; Pleura; Sealant; Trachea}},
  language     = {{eng}},
  month        = {{09}},
  pages        = {{222--235}},
  publisher    = {{Elsevier}},
  series       = {{Acta Biomaterialia}},
  title        = {{Development of alginate and gelatin-based pleural and tracheal sealants}},
  url          = {{http://dx.doi.org/10.1016/j.actbio.2021.06.048}},
  doi          = {{10.1016/j.actbio.2021.06.048}},
  volume       = {{131}},
  year         = {{2021}},
}