Jeroen Pieper scite author profile

Poly(ether ester) block-copolymer scaffolds of different pore size were implanted into the dorsal skinfold chamber of balb/c mice. Using intravital fluorescent microscopy, the temporal course of neovascularization into these scaffolds was quantitatively analyzed. Three scaffold groups (diameter, 5 mm; 220 -260 thickness, m; n ϭ 30) were implanted. Different pore sizes were evaluated: small (20 -75 m), medium (75-212 m) and large pores (250 -300 m). Measurements were performed on days 8, 12, 16, and 20 in the surrounding normal tissue, in the border zone, and in the center of the scaffold. Standard microcirculatory parameters were assessed (plasma leakage, vessel diameter, red blood cell velocity, and functional vessel density). The largepored scaffolds showed significantly higher functional vessel density in the border zone and in the center (days 8 and 12) compared with the scaffold with the small and mediumsized pores. These data correlated with a larger vessel diameter and a higher red blood cell velocity in the largepored scaffold group. Interestingly, during the evaluation period the microcirculatory parameters on the edge of the scaffolds returned to values similar to those found in the surrounding tissue. In the center of the scaffold, however, neovascularization was still active 20 days after implantation. Plasma leakage and vessel diameter were higher in the center of the scaffold. Red blood cell velocity and functional vessel density were 50% lower than in the surrounding tissue. In conclusion, the dorsal skinfold chamber model in mice allows long-term study of blood vessel growth and remodeling in porous biomedical materials. The rate of vessel ingrowth into poly(ether ester) block-copolymer scaffolds is influenced by pore size and was highest in the scaffold with the largest pores. The data generated with this model contribute to knowledge about the development of functional vessels and tissue ingrowth into biomaterials.

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Loading of collagen‐heparan sulfate matrices with bFGF promotes angiogenesis and tissue generation in rats

Pieper¹,

Hafmans²,

Wachem

et al. 2002

J. Biomed. Mater. Res.

195

138

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The loading of biocompatible matrices with growth factors offers the opportunity to induce specific cell behavior. The attachment of heparan sulfate (HS) to these matrices may promote the binding, modulation, and sustained release of signaling molecules. In this study, basic fibroblast growth factor (bFGF) was bound to crosslinked collagenous matrices with and without covalently attached HS. The tissue response to these matrices was evaluated after subcutaneous implantation in rats. Attachment of HS to collagen matrices increased the bFGF binding capacity threefold and resulted in a more gradual and sustained release of the growth factor in vitro. bFGF primarily was located at the matrix margins. In vivo, the presence of HS without bFGF resulted in a transient vascularization, predominantly at the matrix periphery. Angiogenesis was further enhanced by combining HS with bFGF. In contrast to collagen-HS and collagen/bFGF matrices, collagen-HS/bFGF matrices remained highly vascularized throughout the matrix during the 10-week implantation period. In addition, these latter matrices revealed an intense and prolonged tissue response and considerably promoted the generation of new tissue. Foreign body reactions were only observed sporadically at this time interval. It is concluded that bFGF loading of collagen-HS matrices has additional value for those tissue-engineering applications that require enhanced angiogenesis and generation of new tissue.

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Cross-linked type I and type II collagenous matrices for the repair of full-thickness articular cartilage defects—A study in rabbits

Buma¹,

Pieper²,

Tienen³

et al. 2003

Biomaterials

142

103

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Linkage of chondroitin-sulfate to type I collagen scaffolds stimulates the bioactivity of seeded chondrocytes in vitro

Susante

Pieper

Buma³

et al. 2001

Biomaterials

182

102

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Attachment of glycosaminoglycans to collagenous matrices modulates the tissue response in rats

Pieper

Wachem²,

Luyn³

et al. 2000

Biomaterials

145

102

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Jeroen Pieper

Preparation and characterization of porous crosslinked collagenous matrices containing bioavailable chondroitin sulphate

Development of tailor-made collagen–glycosaminoglycan matrices: EDC/NHS crosslinking, and ultrastructural aspects

Immobilization of heparin to EDC/NHS-crosslinked collagen. Characterization and in vitro evaluation

Neovascularization of poly(ether ester) block‐copolymer scaffolds in vivo: Long‐term investigations using intravital fluorescent microscopy

Loading of collagen‐heparan sulfate matrices with bFGF promotes angiogenesis and tissue generation in rats

Cross-linked type I and type II collagenous matrices for the repair of full-thickness articular cartilage defects—A study in rabbits

Linkage of chondroitin-sulfate to type I collagen scaffolds stimulates the bioactivity of seeded chondrocytes in vitro

Attachment of glycosaminoglycans to collagenous matrices modulates the tissue response in rats

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