Tissue responses to novel tissue engineering biodegradable cryogel scaffolds: An animal model

Nimet Bolgen; Ibrahim Vargel; Petek Korkusuz; Elif Guzel; Fatima Plieva; Igor Galaev; Bo Matiasson; Erhan Piskin

doi:10.1002/jbm.a.32193

Tissue responses to novel tissue engineering biodegradable cryogel scaffolds: An animal model

Nimet Bolgen, Ibrahim Vargel, Petek Korkusuz, Elif Guzel, Fatima Plieva, Igor Galaev, Bo Matiasson, Erhan Piskin

Research output: Contribution to journal › Article › peer-review

Abstract

Biodegradable macroporous cryogels with highly open and interconnected pore structures were produced from dextran modified with oligo L-lactide bearing hydroxyethylmethacrylate (HEMA) end groups in moderately frozen solutions. Tissue responses to these novel scaffolds were evaluated in rats after dorsal subcutaneous implantation, iliac submuscular implantation, auricular implantation, or in calvarial defect model. In no case, either necrosis or foreign body reaction was observed during histological studies. The cryogel scaffolds integrated with the surrounding tissue and the formation of a new tissue were accompanied with significant ingrowth of connective tissue cells and new blood vessels into the cryogel. The tissue responses were significantly lower in auricular and calvarial implantations when compared with the subcutanous and the submuscular implantations. The degradation of the scaffold was slower in bone comparing to soft tissues. The biodegradable cryogels are highly biocompatible and combine extraordinary properties including having soft and elastic nature, open porous structure, and very rapid and controllable swelling. Therefore, the cryogels could be promising candidates for further clinical applications in tissue regeneration. (C) 2008 Wiley Periodicals, Inc. J Biomed Mater Res 91 A: 60-68, 2009

Original language	English
Pages (from-to)	60-68
Journal	Journal of Biomedical Materials Research. Part A
Volume	91A
Issue number	1
DOIs	https://doi.org/10.1002/jbm.a.32193
Publication status	Published - 2009

Subject classification (UKÄ)

Industrial Biotechnology

Free keywords

HEMA-L-lactide-dextran
biodegradable
tissue-engineering scaffolds
cryogels
animal model
tissue reponses

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10.1002/jbm.a.32193

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title = "Tissue responses to novel tissue engineering biodegradable cryogel scaffolds: An animal model",

abstract = "Biodegradable macroporous cryogels with highly open and interconnected pore structures were produced from dextran modified with oligo L-lactide bearing hydroxyethylmethacrylate (HEMA) end groups in moderately frozen solutions. Tissue responses to these novel scaffolds were evaluated in rats after dorsal subcutaneous implantation, iliac submuscular implantation, auricular implantation, or in calvarial defect model. In no case, either necrosis or foreign body reaction was observed during histological studies. The cryogel scaffolds integrated with the surrounding tissue and the formation of a new tissue were accompanied with significant ingrowth of connective tissue cells and new blood vessels into the cryogel. The tissue responses were significantly lower in auricular and calvarial implantations when compared with the subcutanous and the submuscular implantations. The degradation of the scaffold was slower in bone comparing to soft tissues. The biodegradable cryogels are highly biocompatible and combine extraordinary properties including having soft and elastic nature, open porous structure, and very rapid and controllable swelling. Therefore, the cryogels could be promising candidates for further clinical applications in tissue regeneration. (C) 2008 Wiley Periodicals, Inc. J Biomed Mater Res 91 A: 60-68, 2009",

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author = "Nimet Bolgen and Ibrahim Vargel and Petek Korkusuz and Elif Guzel and Fatima Plieva and Igor Galaev and Bo Matiasson and Erhan Piskin",

year = "2009",

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AU - Bolgen, Nimet

AU - Vargel, Ibrahim

AU - Korkusuz, Petek

AU - Guzel, Elif

AU - Plieva, Fatima

AU - Galaev, Igor

AU - Matiasson, Bo

AU - Piskin, Erhan

PY - 2009

Y1 - 2009

N2 - Biodegradable macroporous cryogels with highly open and interconnected pore structures were produced from dextran modified with oligo L-lactide bearing hydroxyethylmethacrylate (HEMA) end groups in moderately frozen solutions. Tissue responses to these novel scaffolds were evaluated in rats after dorsal subcutaneous implantation, iliac submuscular implantation, auricular implantation, or in calvarial defect model. In no case, either necrosis or foreign body reaction was observed during histological studies. The cryogel scaffolds integrated with the surrounding tissue and the formation of a new tissue were accompanied with significant ingrowth of connective tissue cells and new blood vessels into the cryogel. The tissue responses were significantly lower in auricular and calvarial implantations when compared with the subcutanous and the submuscular implantations. The degradation of the scaffold was slower in bone comparing to soft tissues. The biodegradable cryogels are highly biocompatible and combine extraordinary properties including having soft and elastic nature, open porous structure, and very rapid and controllable swelling. Therefore, the cryogels could be promising candidates for further clinical applications in tissue regeneration. (C) 2008 Wiley Periodicals, Inc. J Biomed Mater Res 91 A: 60-68, 2009

AB - Biodegradable macroporous cryogels with highly open and interconnected pore structures were produced from dextran modified with oligo L-lactide bearing hydroxyethylmethacrylate (HEMA) end groups in moderately frozen solutions. Tissue responses to these novel scaffolds were evaluated in rats after dorsal subcutaneous implantation, iliac submuscular implantation, auricular implantation, or in calvarial defect model. In no case, either necrosis or foreign body reaction was observed during histological studies. The cryogel scaffolds integrated with the surrounding tissue and the formation of a new tissue were accompanied with significant ingrowth of connective tissue cells and new blood vessels into the cryogel. The tissue responses were significantly lower in auricular and calvarial implantations when compared with the subcutanous and the submuscular implantations. The degradation of the scaffold was slower in bone comparing to soft tissues. The biodegradable cryogels are highly biocompatible and combine extraordinary properties including having soft and elastic nature, open porous structure, and very rapid and controllable swelling. Therefore, the cryogels could be promising candidates for further clinical applications in tissue regeneration. (C) 2008 Wiley Periodicals, Inc. J Biomed Mater Res 91 A: 60-68, 2009

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KW - tissue-engineering scaffolds

KW - cryogels

KW - animal model

KW - tissue reponses

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DO - 10.1002/jbm.a.32193

M3 - Article

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JF - Journal of Biomedical Materials Research. Part A

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ER -

Tissue responses to novel tissue engineering biodegradable cryogel scaffolds: An animal model

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Subject classification (UKÄ)

Free keywords

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