David M. Hoganson scite author profile

Acellular scaffolds from complex whole organs such as lung are being increasingly studied for ex vivo organ generation and for in vitro studies of cell-extracellular matrix interactions. We have established effective methods for efficient de- and recellularization of large animal and human lungs including techniques which allow multiple small segments (∼1–3cm3) to be excised that retain 3-dimensional lung structure. Coupled with the use of a synthetic pleural coating, cells can be selectively physiologically inoculated via preserved vascular and airway conduits. Inoculated segments can be further sliced for high throughput studies. Further, we demonstrate thermography as a powerful noninvasive technique for monitoring perfusion decellularization and for evaluating preservation of vascular and airway networks following human and porcine lung decellularization. Collectively, these techniques are a significant step forward as they allow high throughput in vitro studies from a single lung or lobe in a more biologically relevant, three-dimensional acellular scaffold.

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The retention of extracellular matrix proteins and angiogenic and mitogenic cytokines in a decellularized porcine dermis

Hoganson

et al. 2010

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Lung assist device technology with physiologic blood flow developed on a tissue engineered scaffold platform

et al. 2011

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There is no technology available to support failing lung function for patients outside the hospital. An implantable lung assist device would augment lung function as a bridge to transplant or possible destination therapy. Utilizing biomimetic design principles, a microfluidic vascular network was developed for blood inflow from the pulmonary artery and blood return to the left atrium. Computational fluid dynamics analysis was used to optimize blood flow within the vascular network. A micro milled variable depth mold with 3D features was created to achieve both physiologic blood flow and shear stress. Gas exchange occurs across a thin silicone membrane between the vascular network and adjacent alveolar chamber with flowing oxygen. The device had a surface area of 23.1 cm(2) and respiratory membrane thickness of 8.7 ± 1.2 μm. Carbon dioxide transfer within the device was 156 ml min(-1) m(-2) and the oxygen transfer was 34 ml min(-1) m(-2). A lung assist device based on tissue engineering architecture achieves gas exchange comparable to hollow fiber oxygenators yet does so while maintaining physiologic blood flow. This device may be scaled up to create an implantable ambulatory lung assist device.

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Preserved extracellular matrix components and retained biological activity in decellularized porcine mesothelium

et al. 2010

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David M. Hoganson

Three-dimensional scaffolds of acellular human and porcine lungs for high throughput studies of lung disease and regeneration

The retention of extracellular matrix proteins and angiogenic and mitogenic cytokines in a decellularized porcine dermis

Lung assist device technology with physiologic blood flow developed on a tissue engineered scaffold platform

Preserved extracellular matrix components and retained biological activity in decellularized porcine mesothelium

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