Combined chondrocyte–copolymer implantation with slow release of basic fibroblast growth factor for tissue engineering an auricular cartilage construct

Isogai, Noritaka; Morotomi, Tadaaki; Hayakawa, Sumio; Munakata, Hiroshi; Tabata, Yasuhiko; Ikada, Yoshito; Kamiishi, Hiroshi

doi:10.1002/jbm.a.30343

Cited by 73 publications

(56 citation statements)

References 43 publications

(43 reference statements)

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“…Several previous studies have reported on how bFGF bonds to GMS and is slowly released from GMS (19)(20)(21)(22). We obtained bFGF impregnated-GMS through the same method described in these previous studies.…”

Section: Discussionmentioning

confidence: 99%

Vascular regeneration by pinpoint delivery of growth factors using a microcatheter reservoir system in a rabbit hind-limb ischemia model

Nitta

Nitta-Seko

Sonoda

et al. 2012

Experimental and Therapeutic Medicine

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Abstract. The purpose of this study was to compare the results of delivering low doses of growth factor iteratively (20 µg x5) via a reservoir system with results obtained following a single administration of 100 µg of growth factor. The delivery systems using gelatin microspheres (GMS) facilitate the controlled release of drugs. The controlled release of growth factors at specific sites is essential for vascular regeneration. An ischemic hind-limb model was established in nine rabbits. A reservoir system was implanted in each rabbit. GMS impregnated with basic fibroblast growth factor (bFGF) through an indwelling 2-Fr catheter was infused in the reservoir system. The rabbits were divided into three equal groups: group 1 received 20 µg iteratively (x5) via the reservoir, a single dose of 100 µg growth factor was administered to group 2 and group 3 was the saline control. The therapeutic effects were evaluated by measuring the thigh temperature, blood pressure and blood flow. An immunohistological analysis was also performed for CD31. No significant difference was observed between preand post-treatment (4 weeks following bFGF infusion) in the thigh temperature, blood pressure and blood flow results from each group. Pathological analysis revealed that the number of regenerated vessels was significantly higher in the group treated iteratively with low-dose bFGF.

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Section: Discussionmentioning

confidence: 99%

Vascular regeneration by pinpoint delivery of growth factors using a microcatheter reservoir system in a rabbit hind-limb ischemia model

Nitta

Nitta-Seko

Sonoda

et al. 2012

Experimental and Therapeutic Medicine

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“…Natural materials include gelatin [31,32], collagen [33], fibrin [34], heparin [35] and alginate. [36] Synthetic matrices have been generated from poly(ethylene glycol)-g-poly(lactic acid) [37], poly(lactic acid) [38], poly(lactic-co-glycolic acid) [39,40], and methylidene malonate polymers. [41] From a mechanical perspective, these scaffolds have ranged from relatively weak materials (e.g.…”

Section: Discussionmentioning

confidence: 99%

Biodegradable elastomeric scaffolds with basic fibroblast growth factor release

Guan

Stankus

Wagner

2007

Journal of Controlled Release

149

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Scaffolds that better approximate the mechanical properties of cardiovascular and other soft tissues might provide a more appropriate mechanical environment for tissue development or healing in vivo. An ability to induce local angiogenesis by controlled release of an angiogenic factor, such as basic fibroblast growth factor (bFGF), from a biodegradable scaffold with mechanical properties more closely approximating soft tissue could find application in a variety of settings. Toward this end biodegradable poly(ester urethane)urea (PEUU) scaffolds loaded with bFGF were fabricated by thermally induced phase separation. Scaffold morphology, mechanical properties, release kinetics, hydrolytic degradation and bioactivity of the released bFGF were assessed. The scaffolds had interconnected pores with porosities of 90% or greater and pore sizes ranging from 34-173 μm. Scaffolds had tensile strengths of 0.25-2.8 MPa and elongations at break of 81-443%. Incorporation of heparin into the scaffold increased the initial burst release of bFGF, while the initial bFGF loading content did not change release kinetics significantly. The released bFGF remained bioactive over 21 days as assessed by smooth muscle mitogenicity. Scaffolds loaded with bFGF showed slightly higher degradation rates than unloaded control scaffolds. Smooth muscle cells seeded into the scaffolds with bFGF showed higher cell densities than for control scaffolds after 7 days of culture. The bFGFreleasing PEUU scaffolds thus exhibited a combination of mechanical properties and bioactivity that might be attractive for use in cardiovascular and other soft tissue applications.

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“…Isogai et al developed a composite scaffold to fabricate a complicated 3D engineered auricular cartilage with a slow-release b-FGF system. 29,41,42 From *50 to 80 mg/cm 3 b-FGF had been impregnated onto gelatin sponges. The enhanced vascular networks 41 induced by slow-release b-FGF and the proliferated chondrocytes are involved in enhanced chondrogenesis and production of extracellular matrix in cartilage regeneration.…”

Section: Discussionmentioning

confidence: 99%

“…b-FGF-impregnated gelatin microspheres with slow release enhanced chondrogenesis in in situ engineered cartilage. 29,30 The relationship between the amount of regenerative cartilage that forms and the amount of b-FGF impregnated in gelatin microspheres has not been clarified. This study investigated the optimal amount of b-FGF with gelatin sponges to fabricate engineered cartilage.…”

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confidence: 99%

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Optimal Amount of Basic Fibroblast Growth Factor in Gelatin Sponges Incorporating β-Tricalcium Phosphate with Chondrocytes

Otani

Komura

et al. 2015

Tissue Engineering Part A

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Combined chondrocyte–copolymer implantation with slow release of basic fibroblast growth factor for tissue engineering an auricular cartilage construct

Cited by 73 publications

References 43 publications

Vascular regeneration by pinpoint delivery of growth factors using a microcatheter reservoir system in a rabbit hind-limb ischemia model

Vascular regeneration by pinpoint delivery of growth factors using a microcatheter reservoir system in a rabbit hind-limb ischemia model

Biodegradable elastomeric scaffolds with basic fibroblast growth factor release

Optimal Amount of Basic Fibroblast Growth Factor in Gelatin Sponges Incorporating β-Tricalcium Phosphate with Chondrocytes

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