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Abstract

While transplantation is a viable treatment option for end-stage lung diseases, this option is highly constrained by the availability of organs and postoperative complications. A potential solution is the use of bioengineered lungs generated from repopulated acellular scaffolds. Effective recellularization, however, remains a challenge. In this proof-of-concept study, mice lung scaffolds were decellurized and recellurized using human bronchial epithelial cells (BEAS2B). We present a novel liquid ventilation protocol enabling control over tidal volume and high rates of ventilation. The use of a physiological tidal volume (300 μL) for mice and a higher ventilation rate (40 breaths per minute vs. 1 breath per minute) resulted in higher cell numbers and enhanced cell surface coverage in mouse lung scaffolds as determined via histological evaluation, genomic polymerase chain reaction (PCR) analysis, and immunohistochemistry. A biomimetic lung bioreactor system was designed to include the new ventilation protocol and allow for simultaneous vascular perfusion. We compared the lungs cultured in our dual system to lungs cultured with a bioreactor allowing vascular perfusion only and showed that our system significantly enhances cell numbers and surface coverage. In summary, our results demonstrate the importance of the physical environment and forces for lung recellularization.

Impact statement

New bioreactor systems are required to further enhance the regeneration process of bioengineered lungs. This proof-of-concept study describes a novel ventilation protocol that allows for control over ventilation parameters such as rate and tidal volume. Our data show that a higher rate of ventilation is correlated with higher cell numbers and increased surface coverage. We designed a new biomimetic bioreactor system that allows for ventilation and simultaneous perfusion. Compared to a traditional perfusion only system, recellularization was enhanced in lungs recellularized with our new biomimetic bioreactor.

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References

McCurry

K.R.

, Shearon

, Edwards

L.B.

, et al. Lung transplantation in the United States, 1998–2007. Am J Transplant, 9(4p2), 942, 2009.

Nathan

S.D.

The future of lung transplantation. Chest, 147, 309, 2015.

Shi

, McAllister

D.A.

, O'Brien

K.L.

, et al. Global, regional, and national disease burden estimates of acute lower respiratory infections due to respiratory syncytial virus in young children in 2015: a systematic review and modelling study. Lancet, 390, 946, 2017.

Sacreas

, Yang

J.Y.

, Vanaudenaerde

B.M.

, et al. The common rejection module in chronic rejection post lung transplantation. PLoS One, 13, e0205107, 2018.

Gilbert

T.W.

, Sellaro

T.L.

, and Badylak

S.F.

Decellularization of tissues and organs. Biomaterials, 27, 3675, 2006.

Tsuchiya

, Sivarapatna

, Rocco

, Nanashima

, Nagayasu

, and Niklason

L.E.

Future prospects for tissue engineered lung transplantation: decellularization and recellularization-based whole lung regeneration. Organogenesis, 10, 196, 2014.

Ott

H.C.

, Clippinger

, Conrad

, et al. Regeneration and orthotopic transplantation of a bioartificial lung. Nat Med, 16, 927, 2010.

Petersen

T.H.

, Calle

E.A.

, Zhao

, et al. Tissue-engineered lungs for in vivo implantation. Science, 329, 538, 2010.

Nichols

J.E.

, La Francesca

, Niles

J.A.

, et al. Production and transplantation of bioengineered lung into a large-animal model. Sci Transl Med, 10, eaao3926, 2018.

10.

Wanczyk

, Jensen

, Weiss

D.J.

, and Finck

Advanced single cell technologies to guide the development of bioengineered lungs. Am J Physiol Lung Cell Mol Physiol, 320, L1101, 2021.

11.

Moser

P.T.

, and Ott

H.C.

Recellularization of organs: what is the future for solid organ transplantation? Curr Opin Organ Transplant, 19, 603, 2014.

12.

Gilpin

S.E.

, Guyette

J.P.

, Gonzalez

, et al. Perfusion decellularization of human and porcine lungs: bringing the matrix to clinical scale. J Heart Lung Transplant, 33, 298, 2014.

13.

Price

A.P.

, England

K.A.

, Matson

A.M.

, Blazar

B.R.

, and Panoskaltsis-Mortari

Development of a decellularized lung bioreactor system for bioengineering the lung: the matrix reloaded. Tissue Eng Part A, 16, 2581, 2010.

14.

Price

A.P.

, Godin

L.M.

, Domek

, et al. Automated decellularization of intact, human-sized lungs for tissue engineering. Tissue Eng Part C Methods, 21, 94, 2015.

15.

Wallis

J.M.

, Borg

Z.D.

, Daly

A.B.

, et al. Comparative assessment of detergent-based protocols for mouse lung de-cellularization and re-cellularization. Tissue Eng Part C Methods, 18, 420, 2012.

16.

Petersen

T.H.

, Calle

E.A.

, Colehour

M.B.

, and Niklason

L.E.

Matrix composition and mechanics of decellularized lung scaffolds. Cells Tissues Organs, 195, 222, 2012.

17.

Tsuchiya

, Balestrini

J.L.

, Mendez

, Calle

E.A.

, Zhao

, and Niklason

L.E.

Influence of pH on extracellular matrix preservation during lung decellularization. Tissue Eng Part C Methods, 20, 1028, 2014.

18.

Doi

, Tsuchiya

, Mitsutake

, et al. Transplantation of bioengineered rat lungs recellularized with endothelial and adipose-derived stromal cells. Sci Rep, 7, 1, 2017.

19.

Hillebrandt

K.H.

, Everwien

, Haep

, Keshi

, Pratschke

, and Sauer

I.M.

Strategies based on organ decellularization and recellularization. Transpl Int, 32, 571, 2019.

20.

Sohn

, Buskirk

M.V.

, Buckenmeyer

M.J.

, Londono

, and Faulk

Whole organ engineering: approaches, challenges, and future directions. Appl Sci, 10, 4277, 2020.

21.

Scarritt

M.E.

, Pashos

N.C.

, and Bunnell

B.A.

A review of cellularization strategies for tissue engineering of whole organs. Front Bioeng Biotechnol, 3, 43, 2015.

22.

Badylak

S.F.

, Weiss

D.J.

, Caplan

A.L.

, and Macchiarini

Engineered whole organs and complex tissues. The Ethical Challenges of Emerging Medical Technologies. New York, Routledge, 2020, pp. 317–326.

23.

Kitano

, Ohata

, Economopoulos

K.P.

, et al. Orthotopic transplantation of human bioartificial lung grafts in a porcine model: a feasibility study. Semin Thorac Cardiovasc Surg 2021 [Epub ahead of print]. DOI:10.1053/j.semtcvs.2021.03.006.

24.

Ahmadipour

, Duchesneau

, Taniguchi

, Waddell

T.K.

, and Karoubi

Negative pressure cell delivery augments recellularization of decellularized lungs. Tissue Eng Part C Methods, 27, 1, 2021.

25.

Daly

A.B.

, Wallis

J.M.

, Borg

Z.D.

, et al. Initial binding and recellularization of decellularized mouse lung scaffolds with bone marrow-derived mesenchymal stromal cells. Tissue Eng Part A, 18, 1, 2012.

26.

Thammanomai

, Majumdar

, Bartolák-Suki

, and Suki

Effects of reduced tidal volume ventilation on pulmonary function in mice before and after acute lung injury. J Appl Physiol, 103, 1551, 2007.

27.

Bonvillain

R.W.

, Scarritt

M.E.

, Pashos

N.C.

, et al. Nonhuman primate lung decellularization and recellularization using a specialized large-organ bioreactor. J Vis Exp e50825, 2013.

28.

Ghaedi

, Calle

E.A.

, Mendez

J.J.

, et al. Human iPS cell–derived alveolar epithelium repopulates lung extracellular matrix. J Clin Invest, 123, 4950, 2013.

29.

Ghaedi

, Le

A.V.

, Hatachi

, et al. Bioengineered lungs generated from human i PSC s-derived epithelial cells on native extracellular matrix. J Tissue Eng Regen Med, 12, e1623, 2018.

30.

Gilpin

S.E.

, Li

, Evangelista-Leite

, et al. Fibrillin-2 and Tenascin-C bridge the age gap in lung epithelial regeneration. Biomaterials, 140, 212, 2017.

31.

Mendez

J.J.

, Ghaedi

, Steinbacher

, and Niklason

L.E.

Epithelial cell differentiation of human mesenchymal stromal cells in decellularized lung scaffolds. Tissue Eng Part A, 20, 1735, 2014.

32.

Zhou

, Kitano

, Ren

, et al. Bioengineering human lung grafts on porcine matrix. Ann Surg, 267, 590, 2018.

33.

Bonenfant

N.R.

, Sokocevic

, Wagner

D.E.

, et al. The effects of storage and sterilization on de-cellularized and re-cellularized whole lung. Biomaterials, 34, 3231, 2013.

34.

Platz

, Bonenfant

N.R.

, Uhl

F.E.

, et al. Comparative decellularization and recellularization of wild-type and alpha 1, 3 galactosyltransferase knockout pig lungs: a model for ex vivo xenogeneic lung bioengineering and transplantation. Tissue Eng Part C Methods, 22, 725, 2016.

35.

Crosby

, Simendinger

, Grange

, Ferrante

, Bernier

, and Stanen

Immunohistochemistry protocol for paraffin-embedded tissue section-advertisement. Cell Signal Technol, 10, 5064, 2016.

36.

Calle

E.A.

, Petersen

T.H.

, and Niklason

L.E.

Procedure for lung engineering. J Vis

Exp

. 2651, 2011.

37.

Petersen

T.H.

, Calle

E.A.

, Colehour

M.B.

, and Niklason

L.E.

Bioreactor for the long-term culture of lung tissue. Cell Transplant, 20, 1117, 2011.

38.

Gorman

D.E.

, Wu

, Gilpin

S.E.

, and Ott

H.C.

A fully automated high-throughput bioreactor system for lung regeneration. Tissue Eng Part C Methods, 24, 671, 2018.

39.

Raredon

M.S.B.

, Rocco

K.A.

, Gheorghe

C.P.

, et al. Biomimetic culture reactor for whole-lung engineering. Biores Open Access, 5, 72, 2016.

40.

Song

J.J.

, Kim

S.S.

, Liu

, et al. Enhanced in vivo function of bioartificial lungs in rats. Ann Thorac Surg, 92, 998, 2011.

41.

LaRanger

, Peters-Hall

J.R.

, Coquelin

, et al. Reconstituting mouse lungs with conditionally reprogrammed human bronchial epithelial cells. Tissue Eng Part A, 24, 559, 2018.

42.

Stabler

C.T.

, Caires

L.C.

Jr ., Mondrinos

M.J.

, et al. Enhanced re-endothelialization of decellularized rat lungs. Tissue Eng Part C Methods, 22, 439, 2016.

43.

Han

, Na

, Wu

, and Yuan

B.-Z.

Human lung epithelial BEAS-2B cells exhibit characteristics of mesenchymal stem cells. PLoS One, 15, e0227174, 2020.

44.

Guo

, Karoubi

, Duchesneau

, et al. Interrupted reprogramming of alveolar type II cells induces progenitor-like cells that ameliorate pulmonary fibrosis. NPJ Regen Med, 3, 1, 2018.

45.

Soleas

J.P.

, D'Arcangelo

, Huang

, et al. Assembly of lung progenitors into developmentally-inspired geometry drives differentiation via cellular tension. Biomaterials, 254, 120128, 2020.

46.

Kotton

D.N.

, and Morrisey

E.E.

Lung regeneration: mechanisms, applications and emerging stem cell populations. Nat Med, 20, 822, 2014.

47.

Kim

, Guenthart

, O'Neill

J.D.

, Dorrello

N.V.

, Bacchetta

, and Vunjak-Novakovic

Controlled delivery and minimally invasive imaging of stem cells in the lung. Sci Rep, 7, 1, 2017.

48.

Gilpin

, Guyette

, Ren

, et al. Up-scaling decellularization and whole organ culture for human lung regeneration. J Heart Lung Transplant, 32, S69, 2013.

49.

Sanchez-Esteban

, Cicchiello

L.A.

, Wang

, et al. Mechanical stretch promotes alveolar epithelial type II cell differentiation. J Appl Physiol, 91, 589, 2001.

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Use of High-Rate Ventilation Results in Enhanced Recellularization of Bioengineered Lung Scaffolds

Abstract

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