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Literature DB >> 21799708

Perfusion systems that minimize vascular volume fraction in engineered tissues.

Abstract

This study determines the optimal vascular designs for perfusing engineered tissues. Here, "optimal" describes a geometry that minimizes vascular volume fraction (the fractional volume of a tissue that is occupied by vessels) while maintaining oxygen concentration above a set threshold throughout the tissue. Computational modeling showed that optimal geometries depended on parameters that affected vascular fluid transport and oxygen consumption. Approximate analytical expressions predicted optima that agreed well with the results of modeling. Our results suggest one basis for comparing the effectiveness of designs for microvascular tissue engineering.

Entities: Chemical

Year: 2011 PMID： 21799708 PMCID： PMC3145227 DOI： 10.1063/1.3576926

Source DB: PubMed Journal: Biomicrofluidics ISSN： 1932-1058 Impact factor: 2.800

29 in total

1. Effect of mechanical factors on the function of engineered human blood microvessels in microfluidic collagen gels.

Authors: Gavrielle M Price; Keith H K Wong; James G Truslow; Alexander D Leung; Chitrangada Acharya; Joe Tien
Journal: Biomaterials Date: 2010-05-26 Impact factor: 12.479

2. Mimicking nature by codelivery of stimulant and inhibitor to create temporally stable and spatially restricted angiogenic zones.

Authors: William W Yuen; Nan R Du; Chun H Chan; Eduardo A Silva; David J Mooney
Journal: Proc Natl Acad Sci U S A Date: 2010-10-04 Impact factor: 11.205

Review 5. Microfluidic Biomaterials.

Authors: Joe Tien; Yoseph W Dance
Journal: Adv Healthc Mater Date: 2020-09-06 Impact factor: 9.933

5 in total

Perfusion systems that minimize vascular volume fraction in engineered tissues.

1. Effect of mechanical factors on the function of engineered human blood microvessels in microfluidic collagen gels.

2. Mimicking nature by codelivery of stimulant and inhibitor to create temporally stable and spatially restricted angiogenic zones.

3. Fabrication of microfluidic hydrogels using molded gelatin as a sacrificial element.

4. Microfluidic scaffolds for tissue engineering.

5. Model of oxygen transport limitations in hollow fiber bioreactors.

6. Optimum fiber spacing in a hollow fiber bioreactor.

7. Optimality principles in arterial branching.

8. Multilayer microfluidic PEGDA hydrogels.

9. Computational design of drainage systems for vascularized scaffolds.

10. The vascularity of cutaneous melanoma: a quantitative histological study of lesions 0.85-1.25 mm in thickness.

1. Preface to Special Topic: Microfluidics in cell biology and tissue engineering.

2. A standalone perfusion platform for drug testing and target validation in micro-vessel networks.

3. Design principles for lymphatic drainage of fluid and solutes from collagen scaffolds.

4. Artificial lymphatic drainage systems for vascularized microfluidic scaffolds.

Review 5. Microfluidic Biomaterials.