OBJECTIVES: The persistent shortage of donor organs for lung transplantation illustrates the need for new strategies in organ replacement therapy. Pulmonary tissue engineering aims at developing viable hybrid tissue for patients with chronic respiratory failure. METHODS: Dual-chamber polymer constructs that mimic the characteristics of the pulmonary air-blood interface were fabricated by microfabrication techniques using the biocompatible polymer polydimethylsiloxane. One compartment ("vascular chamber") was designed as a capillary network to mimic the pulmonary microvasculature. The other compartment ("parenchymal chamber") was designed to permit gas exchange. Immortalized mouse lung epithelium cells (MLE-12) were cultured on the surface of polystyrene microcarrier beads. These beads were subsequently injected into the parenchymal chamber of the dual-chamber microsystems. The vascular compartment was perfused with cell culture medium in a bioreactor and the construct was maintained in culture for 1 week. RESULTS: The microcarriers evenly distributed MLE-12 cells on the parenchymal compartment surface. Confluent cell layers were confirmed by fluorescent and electron microscopy. Adequate proliferation of MLE-12 cells within the construct was monitored via the DNA content. Viability of the cells was maintained over 1 week. Finally, cellular specificity and functional capacity in situ were demonstrated by immunostaining for proSP-B and proSP-C (alveolar epithelium), and by using MLE-12 cells transfected to overexpress green fluorescent protein. CONCLUSION: We conclude that functional hybrid microsystems mimicking the basic building plan of alveolar tissue can be engineered in vitro.
OBJECTIVES: The persistent shortage of donor organs for lung transplantation illustrates the need for new strategies in organ replacement therapy. Pulmonary tissue engineering aims at developing viable hybrid tissue for patients with chronic respiratory failure. METHODS: Dual-chamber polymer constructs that mimic the characteristics of the pulmonary air-blood interface were fabricated by microfabrication techniques using the biocompatible polymerpolydimethylsiloxane. One compartment ("vascular chamber") was designed as a capillary network to mimic the pulmonary microvasculature. The other compartment ("parenchymal chamber") was designed to permit gas exchange. Immortalized mouse lung epithelium cells (MLE-12) were cultured on the surface of polystyrene microcarrier beads. These beads were subsequently injected into the parenchymal chamber of the dual-chamber microsystems. The vascular compartment was perfused with cell culture medium in a bioreactor and the construct was maintained in culture for 1 week. RESULTS: The microcarriers evenly distributed MLE-12 cells on the parenchymal compartment surface. Confluent cell layers were confirmed by fluorescent and electron microscopy. Adequate proliferation of MLE-12 cells within the construct was monitored via the DNA content. Viability of the cells was maintained over 1 week. Finally, cellular specificity and functional capacity in situ were demonstrated by immunostaining for proSP-B and proSP-C (alveolar epithelium), and by using MLE-12 cells transfected to overexpress green fluorescent protein. CONCLUSION: We conclude that functional hybrid microsystems mimicking the basic building plan of alveolar tissue can be engineered in vitro.
Authors: Barkan Sidar; Brittany R Jenkins; Sha Huang; Jason R Spence; Seth T Walk; James N Wilking Journal: Lab Chip Date: 2019-10-09 Impact factor: 6.799
Authors: Courtney M Sakolish; Mandy B Esch; James J Hickman; Michael L Shuler; Gretchen J Mahler Journal: EBioMedicine Date: 2016-02-13 Impact factor: 8.143
Authors: Benjamin O Murray; Carlos Flores; Corin Williams; Deborah A Flusberg; Elizabeth E Marr; Karolina M Kwiatkowska; Joseph L Charest; Brett C Isenberg; Jennifer L Rohn Journal: Front Cell Infect Microbiol Date: 2021-05-26 Impact factor: 5.293