Endothelialization and Flow Conditioning of Fibrin-Based Media-Equivalents

Isenberg, Brett C.; Williams, Chrysanthi; Tranquillo, Robert T.

doi:10.1007/s10439-006-9101-0

Cited by 88 publications

(69 citation statements)

References 65 publications

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“…They have been investigated for the development of many tissues including cartilage, [15] heart valves, [9] and bioartificial arteries. [10,23] However, the mechanical strength of fibrin hydrogel constructs is initially weak. Promising in-vitro studies performed by Jockenhoevel et al using typical fibrin hydrogels in cardiovascular tissue engineering have been conducted, however, disadvantages were noted.…”

Section: Discussionmentioning

confidence: 99%

A fibrinogen-based precision microporous scaffold for tissue engineering

2007

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Section: Discussionmentioning

confidence: 99%

A fibrinogen-based precision microporous scaffold for tissue engineering

2007

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“…Vascular perfusion bioreactors typically focus on producing a tissue-engineered blood vessel, not on vascularizing another tissue type. Using pulsatile conditions typically found in vivo, functional arteries may be grown in vitro [83][84][85][86][87] Only recently have vessels been used as a means of perfusing a larger tissue, such as the abdominal aorta of a rat as a core perfusion element within an artificial myocardial matrix of collagen and neonatal rat cardiomyocytes. 88 The perfused tissues displayed enhanced cell viability and increased metabolic activity when compared to nonperfused controls.…”

Section: Perfusion Bioreactorsmentioning

confidence: 99%

Vascularization Strategies for Tissue Engineering

Lovett

Lee

Edwards

et al. 2009

Tissue Engineering Part B: Reviews

783

685

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Tissue engineering is currently limited by the inability to adequately vascularize tissues in vitro or in vivo. Issues of nutrient perfusion and mass transport limitations, especially oxygen diffusion, restrict construct development to smaller than clinically relevant dimensions and limit the ability for in vivo integration. There is much interest in the field as researchers have undertaken a variety of approaches to vascularization, including material functionalization, scaffold design, microfabrication, bioreactor development, endothelial cell seeding, modular assembly, and in vivo systems. Efforts to model and measure oxygen diffusion and consumption within these engineered tissues have sought to quantitatively assess and improve these design strategies. This review assesses the current state of the field by outlining the prevailing approaches taken toward producing vascularized tissues and highlighting their strengths and weaknesses.

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“…Attempts to specifically engineer such organization into tissue engineered arteries have met with differing degrees of success. While biopolymer-based tissues have been shown to possess the proper alignment of matrix components [9][10][11] and exhibit mechanical anisotropy [12], their overall mechanical properties are not sufficient for implantation [13]. On the other hand, tissue engineered grafts made solely from cell-secreted ECM, using a "self-assembly" or cell sheet-based approach, could support high burst pressures and have shown success in vivo, yet lacked the desired organization [14].…”

Section: Introductionmentioning

confidence: 99%

A thermoresponsive, microtextured substrate for cell sheet engineering with defined structural organization

et al. 2008

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The proper function of many tissues depends critically on the structural organization of the cells and matrix of which they are comprised. Therefore, in order to engineer functional tissue equivalents that closely mimic the unique properties of native tissues it is necessary to develop strategies for reproducing the complex, highly organized structure of these tissues. To this end, we sought to develop a simple method for generating cell sheets that have defined ECM/cell organization using microtextured, thermoresponsive polystyrene substrates to guide cell organization and tissue growth. The patterns consisted of large arrays of alternating grooves and ridges (50 μm wide, 5 μm deep). Vascular smooth muscle cells cultured on these substrates produced intact sheets consisting of cells that exhibited strong alignment in the direction of the micropattern. These sheets could be readily transferred from patterned substrates to non-patterned substrates without the loss of tissue organization. Ultimately, such sheets will be layered to form larger tissues with defined ECM/cell organization that spans multiple length scales.

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Endothelialization and Flow Conditioning of Fibrin-Based Media-Equivalents

Cited by 88 publications

References 65 publications

A fibrinogen-based precision microporous scaffold for tissue engineering

A fibrinogen-based precision microporous scaffold for tissue engineering

Vascularization Strategies for Tissue Engineering

A thermoresponsive, microtextured substrate for cell sheet engineering with defined structural organization

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