Tissue-engineered endothelial and epithelial implants differentially and synergistically regulate airway repair

Zani, Brett G.; Kojima, Koji; Vacanti, Charles A.; Edelman, Elazer R.

doi:10.1073/pnas.0802463105

Cited by 61 publications

(52 citation statements)

References 33 publications

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“…In this study, the promotion of scar tissue formation using a fibrin hydrogel sealant and the resulting resizing of the lung enhanced the respiratory function without the major trauma usually associated with surgery. However, recent findings have shown that regeneration of the damaged airways is regulated by multiple cell types and processes, dependent on the synergistic interactions between the different cell types present in lung tissue (170). These results reinforce the concept that the use of adequate cell types displaying appropriate phenotype could improve engineered lung function and promote organotypic tissue regeneration.…”

Section: Increasing the Complexity Of Tissue-engineered Lung Modelssupporting

confidence: 74%

Computational and bioengineered lungs as alternatives to whole animal, isolated organ, and cell-based lung models

Patel

Gauvin

Absar

et al. 2012

American Journal of Physiology-Lung Cellular and Molecular Phys

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Development of lung models for testing a drug substance or delivery system has been an intensive area of research. However, a model that mimics physiological and anatomical features of human lungs is yet to be established. Although in vitro lung models, developed and fine-tuned over the past few decades, were instrumental for the development of many commercially available drugs, they are suboptimal in reproducing the physiological microenvironment and complex anatomy of human lungs. Similarly, intersubject variability and high costs have been major limitations of using animals in the development and discovery of drugs used in the treatment of respiratory disorders. To address the complexity and limitations associated with in vivo and in vitro models, attempts have been made to develop in silico and tissue-engineered lung models that allow incorporation of various mechanical and biological factors that are otherwise difficult to reproduce in conventional cell or organ-based systems. The in silico models utilize the information obtained from in vitro and in vivo models and apply computational algorithms to incorporate multiple physiological parameters that can affect drug deposition, distribution, and disposition upon administration via the lungs. Bioengineered lungs, on the other hand, exhibit significant promise due to recent advances in stem or progenitor cell technologies. However, bioengineered approaches have met with limited success in terms of development of various components of the human respiratory system. In this review, we summarize the approaches used and advancements made toward the development of in silico and tissue-engineered lung models and discuss potential challenges associated with the development and efficacy of these models. bioengineered lung; computational modeling; in silico; lung models; tissue engineering LUNG DISEASES ARE THE THIRD leading cause of deaths in the United States that translate into one in six deaths. More than 400,000 Americans die of lung disease every year and around 35 million are now living with chronic lung problems (1). Therefore, there is an important need to understand as to how a new drug entity or a novel formulation may influence the anatomy, physiology, and pathogenesis of lungs and vice versa.The human lung has an approximate volume of six liters, contains about 300 million alveoli, and provides a total surface area of 100 square meters as blood-air interface, which is packed into an elastic dynamic structure responsible for gas exchange (159). The human airway wall is a connective tissue that includes smooth muscle cells (SMC), mucus glands, blood vessels, and fibroblasts surrounded by a collagen-rich extracellular matrix (ECM). Epithelial cells, responsible for the efficient oxygen and carbon dioxide transfer, are at the interface between air and the connective tissue and are attached to an underlying basement membrane. The respiratory system is the site of a variety of pulmonary diseases such as asthma, bronchitis, pneumonia, cystic fibrosis, emphysema, a...

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Section: Increasing the Complexity Of Tissue-engineered Lung Modelssupporting

confidence: 74%

Computational and bioengineered lungs as alternatives to whole animal, isolated organ, and cell-based lung models

Patel

Gauvin

Absar

et al. 2012

American Journal of Physiology-Lung Cellular and Molecular Phys

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“…50,51 A similar approach has been used in the vascularization of the epithelium. 52 In the case of the epithelium, the interactions between the mesenchymal and epithelial cells are essential for tissue function in most organs. For example, sequential and reciprocal interactions between the stem cells and the epithelial cells are required for tooth development.…”

Section: Effect Of Heterotypic Interactions On Epithelial Cellsmentioning

confidence: 99%

Engineering Functional Epithelium for Regenerative Medicine and In Vitro Organ Models: A Review

Vrana

Lavalle²,

Dokmeci³

et al. 2013

Tissue Engineering Part B: Reviews

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Recent advances in the fields of microfabrication, biomaterials, and tissue engineering have provided new opportunities for developing biomimetic and functional tissues with potential applications in disease modeling, drug discovery, and replacing damaged tissues. An intact epithelium plays an indispensable role in the functionality of several organs such as the trachea, esophagus, and cornea. Furthermore, the integrity of the epithelial barrier and its degree of differentiation would define the level of success in tissue engineering of other organs such as the bladder and the skin. In this review, we focus on the challenges and requirements associated with engineering of epithelial layers in different tissues. Functional epithelial layers can be achieved by methods such as cell sheets, cell homing, and in situ epithelialization. However, for organs composed of several tissues, other important factors such as (1) in vivo epithelial cell migration, (2) multicell-type differentiation within the epithelium, and (3) epithelial cell interactions with the underlying mesenchymal cells should also be considered. Recent successful clinical trials in tissue engineering of the trachea have highlighted the importance of a functional epithelium for long-term success and survival of tissue replacements. Hence, using the trachea as a model tissue in clinical use, we describe the optimal structure of an artificial epithelium as well as challenges of obtaining a fully functional epithelium in macroscale. One of the possible remedies to address such challenges is the use of bottom-up fabrication methods to obtain a functional epithelium. Modular approaches for the generation of functional epithelial layers are reviewed and other emerging applications of microscale epithelial tissue models for studying epithelial/mesenchymal interactions in healthy and diseased (e.g., cancer) tissues are described. These models can elucidate the epithelial/mesenchymal tissue interactions at the microscale and provide the necessary tools for the next generation of multicellular engineered tissues and organ-on-a-chip systems.

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“…Fortuitously, fibril formation can be replicated in a laboratory environment, 5 which can aid development of synthetic collagen-based scaffolds for tissue repair and regeneration applications. 6,7 Strategies for developing such scaffolds require controlled collagen assembly for reliable function, including control over packing density, elastic deformability, and the final size of the construct. These factors can affect bioactivity through mechanical response, or as a result of bioavailability issues arising from the porosity of the material.…”

Section: Introductionmentioning

confidence: 99%

Correlating Mechanical Properties with Aggregation Processes in Electrochemically Fabricated Collagen Membranes

Poduska

2009

Biomacromolecules

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We show that mechanical stiffness is a useful metric for characterizing complex collagen assemblies, providing insight about aggregation products and pathways in collagen-based materials.This study focuses on mechanically robust collagenous membranes produced by an electrochemical synthesis process. Changing the duration of the applied electric field, or adjusting the electrolyte composition (by adding Ca 2+ , K + , Na + or by changing pH), produces membranes with a range of Young's moduli as determined from force-displacement measurements with an atomic force microscope. The structural organization -characterized by UV-visible spectroscopy, Raman spectroscopy, optical microscopy and atomic force microscopy -correlates with the mechanical stiffness. These data provide insights into the relative importance of different aggregation pathways enabled by our multi-parameter electrochemically-induced collagen assembly process.

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Tissue-engineered endothelial and epithelial implants differentially and synergistically regulate airway repair

Cited by 61 publications

References 33 publications

Computational and bioengineered lungs as alternatives to whole animal, isolated organ, and cell-based lung models

Computational and bioengineered lungs as alternatives to whole animal, isolated organ, and cell-based lung models

Engineering Functional Epithelium for Regenerative Medicine and In Vitro Organ Models: A Review

Correlating Mechanical Properties with Aggregation Processes in Electrochemically Fabricated Collagen Membranes

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