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Glycosaminoglycans Modulate the Angiogenic Ability of Type I Collagen-Based Scaffolds by Acting on Vascular Network Remodeling and Maturation.

Authors :
Salvante, Enrica Raffaella Grazia
Popoiu, Anca Voichita
Saxena, Amulya K.
Popoiu, Tudor Alexandru
Boia, Eugen Sorin
Cimpean, Anca Maria
Rus, Florina Stefania
Dorobantu, Florica Ramona
Chis, Monica
Source :
Bioengineering (Basel); May2024, Vol. 11 Issue 5, p423, 14p
Publication Year :
2024

Abstract

Type I collagen, prevalent in the extracellular matrix, is biocompatible and crucial for tissue engineering and wound healing, including angiogenesis and vascular maturation/stabilization as required processes of newly formed tissue constructs or regeneration. Sometimes, improper vascularization causes unexpected outcomes. Vascularization failure may be caused by extracellular matrix collagen and non-collagen components heterogeneously. This study compares the angiogenic potential of collagen type I-based scaffolds and collagen type I/glycosaminoglycans scaffolds by using the chick embryo chorioallantoic membrane (CAM) model and IKOSA digital image analysis. Two clinically used biomaterials, Xenoderm (containing type I collagen derived from decellularized porcine extracellular matrix) and a dual-layer collagen sponge (DLC, with a biphasic composition of type I collagen combined with glycosaminoglycans) were tested for their ability to induce new vascular network formation. The AI-based IKOSA app enhanced the research by calculating from stereomicroscopic images angiogenic parameters such as total vascular area, branching sites, vessel length, and vascular thickness. The study confirmed that Xenoderm caused a fast angiogenic response and substantial vascular growth, but was unable to mature the vascular network. DLC scaffold, in turn, produced a slower angiogenic response, but a more steady and organic vascular maturation and stabilization. This research can improve collagen-based knowledge by better assessing angiogenesis processes. DLC may be preferable to Xenoderm or other materials for functional neovascularization, according to the findings. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
23065354
Volume :
11
Issue :
5
Database :
Complementary Index
Journal :
Bioengineering (Basel)
Publication Type :
Academic Journal
Accession number :
177495954
Full Text :
https://doi.org/10.3390/bioengineering11050423