Source: Eur Respir J, 52 (5) 1800876; 10.1183/13993003.00876-2018
Disease area: Airway diseases



Rating:

Share or cite this content

Citations should be made in the following way:
Konstantinos Gkatzis, Sara Taghizadeh, Dongeun Huh, Didier Y.R. Stainier, Saverio Bellusci. Use of three-dimensional organoids and lung-on-a-chip methods to study lung development, regeneration and disease. Eur Respir J, 52 (5) 1800876; 10.1183/13993003.00876-2018

Member's Comments

No comment yet.

Related content which might interest you: Use of biomaterials to tissue engineer 3D models with lung organoids for in-vitro disease modelling Source: Virtual Congress 2020 – Lung epithelial development and repair in three-dimensions Year: 2020 Human lung scaffolds to model lung disease and tissue regeneration Source: International Congress 2018 – Cell-matrix interactions in lung disease and regeneration Year: 2018 Acellular human lung scaffolds to model lung disease and tissue regeneration Source: Eur Respir Rev, 27 (148) 180021; 10.1183/16000617.0021-2018 Year: 2018 A 3D tissue-engineered airway model for the assessment of epithelial responses to novel nanotherapeutics Source: Virtual Congress 2021 – In vitro modelling of lung disease: reach out to the next dimension Year: 2021 Towards human lung regeneration in end-stage respiratory failure: genetically-modifiable 3D organoid culture of human embryonic lung stem cells enables for the first time the study of human lung development in vitro Source: ERS Lung Science Conference 2018 Year: 2018 Lung tissue bioengineering for transplantation and modelling of development, disease and regeneration Source: Eur Respir Monogr 2021; 91: 248-272 Year: 2021 3D tissue culture to study the mechanisms of lung repair in IPF Source: Virtual Congress 2020 – Human ex vivo models of interstitial lung disease Year: 2020 Watching the lung work: An in vitro 3-D microfluidic device to challenge pulmonary drug delivery strategies with high end microscopy Source: Annual Congress 2013 –Novel in vitro and animal models to study lung diseases Year: 2013 Preclinical validation and imaging of Wnt-induced repair in human 3D lung tissue cultures Source: Eur Respir J 2015; 46: 1150-1166 Year: 2015 Human α-defensin as a biosensor of interstitial lung diseases. An ex-vivo study Source: Eur Respir J 2006; 28: Suppl. 50, 336s Year: 2006 YI03 - Lung tissue engineering: generation and characterization of decellularized lung scaffolds for stem cell differentiation Source: Lung Science Conference 2012 - Rebuilding a diseased lung: Repair and regeneration Year: 2012 Computed-tomography-based radiomics features for staging of interstitial lung disease – transferability from experimental to human lung fibrosis - a proof-of-concept study Source: International Congress 2019 – Imaging for prognostication and disease characterisation: 2019 update Year: 2019 The development of a bioengineered composite 3D-printed scaffold for tracheal regeneration. Source: Virtual Congress 2021 – In vitro modelling of lung disease: reach out to the next dimension Year: 2021 The role of scaffolds in lung tissue regeneration Source: International Congress 2019 – From 2D to 3D models of human lung disease: novel developments to rebuild the lung Year: 2019 The host response to decellularised lung extracellular matrix reinforces bioinks for 3D bioprinting of lung tissue for transplantation Source: Virtual Congress 2021 – Repair and regeneration in chronic lung disease and lung cancer Year: 2021 PP236 – Elastin-like-recombinamer cryogel as a platform for lung regeneration Source: ERS Lung Science Conference 2021 Year: 2021 YI402 - Host response towards decellularised lung extracellular matrix reinforced bioinks for 3D bioprinting lung tissue for transplantation Source: ERS Lung Science Conference 2021 Year: 2021 Three-dimensional tissue-based models for translational lung stem cell research: precision-cut lung slices Source: Eur Respir Monogr 2021; 91: 222-231 Year: 2021 Lung organoids: powerful tools for studying lung stem cells and diseases Source: Eur Respir Monogr 2021; 91: 175-189 Year: 2021