Cartilage regeneration with highly-elastic three-dimensional scaffolds prepared from biodegradable poly(l-lactide-co-ε-caprolactone)

Youngmee Jung, Min Sung Park, jinwoo lee, Young Ha Kim, Sang Heon Kim, Soo Hyun Kim

Research output: Contribution to journalArticle

83 Citations (Scopus)

Abstract

Compressive mechanical stimuli are crucial in regenerating cartilage with tissue engineering, which creates a need for scaffolds that can maintain their mechanical integrity while delivering mechanical signals to adherent cells during strain applications. With these goals in mind, the aim of this study was to develop a mechano-active scaffold that facilitated effective cartilaginous tissue formation under dynamic physiological environments. Using a gel-pressing method, we fabricated a biodegradable and highly-elastic scaffold from poly(l-lactide-co-ε-caprolactone) (PLCL; 5:5), with 85% porosity and a 300-500-μm pore size, and we compared it to control scaffolds made of rigid polylactide (PLA) or poly(lactide-co-glycolide) (PLGA). After tensile mechanical tests and recovery tests confirmed the elasticity of the PLCL scaffolds, we seeded them with rabbit chondrocytes, cultured them in vitro, and subcutaneously implanted them into nude mice for up to eight weeks. The PLCL scaffolds possessed a completely rubber-like elasticity, were easily twisted and bent, and exhibited an almost complete (over 97%) recovery from applied strain (up to 500%); the control PLA scaffolds showed little recovery. In vitro and in vivo accumulations of extracellular matrix on the cell-PLCL constructs demonstrated that they could not only sustain but also significantly enhance chondrogenic differentiation. Moreover, the mechanical stimulation of the dynamic in vivo environment promoted deposition of the chondral extracellular matrix onto the PLCL. In contrast, on the PLA scaffolds, most of the chondrocytes had de-differentiated and formed fibrous tissues. In a rabbit defect model, the groups treated with PLCL scaffolds exhibited significantly enhanced cartilage regeneration compared to groups harboring an empty control or PLGA scaffolds. These results indicated that the mechano-active PLCL scaffolds effectively delivered mechanical signals associated with biological environments to adherent chondrocytes, suggesting that these elastic PLCL scaffolds could successfully be used for cartilage regeneration. Crown

Original languageEnglish
Pages (from-to)4630-4636
Number of pages7
JournalBiomaterials
Volume29
Issue number35
DOIs
Publication statusPublished - 2008 Dec 1

Fingerprint

Cartilage
Scaffolds
Regeneration
Chondrocytes
Elasticity
Extracellular Matrix
Rabbits
Polyglactin 910
Porosity
Rubber
Tissue Engineering
Crowns
Nude Mice
Gels
Recovery
poly(lactide)
caprolactone
dilactide
Tissue
Scaffolds (biology)

All Science Journal Classification (ASJC) codes

  • Bioengineering
  • Ceramics and Composites
  • Biophysics
  • Biomaterials
  • Mechanics of Materials

Cite this

Jung, Youngmee ; Park, Min Sung ; lee, jinwoo ; Kim, Young Ha ; Kim, Sang Heon ; Kim, Soo Hyun. / Cartilage regeneration with highly-elastic three-dimensional scaffolds prepared from biodegradable poly(l-lactide-co-ε-caprolactone). In: Biomaterials. 2008 ; Vol. 29, No. 35. pp. 4630-4636.
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abstract = "Compressive mechanical stimuli are crucial in regenerating cartilage with tissue engineering, which creates a need for scaffolds that can maintain their mechanical integrity while delivering mechanical signals to adherent cells during strain applications. With these goals in mind, the aim of this study was to develop a mechano-active scaffold that facilitated effective cartilaginous tissue formation under dynamic physiological environments. Using a gel-pressing method, we fabricated a biodegradable and highly-elastic scaffold from poly(l-lactide-co-ε-caprolactone) (PLCL; 5:5), with 85{\%} porosity and a 300-500-μm pore size, and we compared it to control scaffolds made of rigid polylactide (PLA) or poly(lactide-co-glycolide) (PLGA). After tensile mechanical tests and recovery tests confirmed the elasticity of the PLCL scaffolds, we seeded them with rabbit chondrocytes, cultured them in vitro, and subcutaneously implanted them into nude mice for up to eight weeks. The PLCL scaffolds possessed a completely rubber-like elasticity, were easily twisted and bent, and exhibited an almost complete (over 97{\%}) recovery from applied strain (up to 500{\%}); the control PLA scaffolds showed little recovery. In vitro and in vivo accumulations of extracellular matrix on the cell-PLCL constructs demonstrated that they could not only sustain but also significantly enhance chondrogenic differentiation. Moreover, the mechanical stimulation of the dynamic in vivo environment promoted deposition of the chondral extracellular matrix onto the PLCL. In contrast, on the PLA scaffolds, most of the chondrocytes had de-differentiated and formed fibrous tissues. In a rabbit defect model, the groups treated with PLCL scaffolds exhibited significantly enhanced cartilage regeneration compared to groups harboring an empty control or PLGA scaffolds. These results indicated that the mechano-active PLCL scaffolds effectively delivered mechanical signals associated with biological environments to adherent chondrocytes, suggesting that these elastic PLCL scaffolds could successfully be used for cartilage regeneration. Crown",
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Cartilage regeneration with highly-elastic three-dimensional scaffolds prepared from biodegradable poly(l-lactide-co-ε-caprolactone). / Jung, Youngmee; Park, Min Sung; lee, jinwoo; Kim, Young Ha; Kim, Sang Heon; Kim, Soo Hyun.

In: Biomaterials, Vol. 29, No. 35, 01.12.2008, p. 4630-4636.

Research output: Contribution to journalArticle

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AU - Jung, Youngmee

AU - Park, Min Sung

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AU - Kim, Young Ha

AU - Kim, Sang Heon

AU - Kim, Soo Hyun

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AB - Compressive mechanical stimuli are crucial in regenerating cartilage with tissue engineering, which creates a need for scaffolds that can maintain their mechanical integrity while delivering mechanical signals to adherent cells during strain applications. With these goals in mind, the aim of this study was to develop a mechano-active scaffold that facilitated effective cartilaginous tissue formation under dynamic physiological environments. Using a gel-pressing method, we fabricated a biodegradable and highly-elastic scaffold from poly(l-lactide-co-ε-caprolactone) (PLCL; 5:5), with 85% porosity and a 300-500-μm pore size, and we compared it to control scaffolds made of rigid polylactide (PLA) or poly(lactide-co-glycolide) (PLGA). After tensile mechanical tests and recovery tests confirmed the elasticity of the PLCL scaffolds, we seeded them with rabbit chondrocytes, cultured them in vitro, and subcutaneously implanted them into nude mice for up to eight weeks. The PLCL scaffolds possessed a completely rubber-like elasticity, were easily twisted and bent, and exhibited an almost complete (over 97%) recovery from applied strain (up to 500%); the control PLA scaffolds showed little recovery. In vitro and in vivo accumulations of extracellular matrix on the cell-PLCL constructs demonstrated that they could not only sustain but also significantly enhance chondrogenic differentiation. Moreover, the mechanical stimulation of the dynamic in vivo environment promoted deposition of the chondral extracellular matrix onto the PLCL. In contrast, on the PLA scaffolds, most of the chondrocytes had de-differentiated and formed fibrous tissues. In a rabbit defect model, the groups treated with PLCL scaffolds exhibited significantly enhanced cartilage regeneration compared to groups harboring an empty control or PLGA scaffolds. These results indicated that the mechano-active PLCL scaffolds effectively delivered mechanical signals associated with biological environments to adherent chondrocytes, suggesting that these elastic PLCL scaffolds could successfully be used for cartilage regeneration. Crown

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