Byung-Soo Kim

Manufacture of elastic biodegradable PLCL scaffolds for mechano-active vascular tissue engineering

A soft and very elastic poly(lactide-co-ε-caprolactone) (PLCL)(50:50, M n 185 × 103) was synthesized. Tubular scaffolds were prepared by an extrusion-particulate leaching method for mechano-active vascular tissue engineering. The copolymer was very flexible but completely rubber-like elastic. Even the high porous PLCL scaffolds (90% salt wt) exhibited 200% elongation, but recovery over 85% in a tensile test. Moreover, the PLCL scaffolds maintained their high elasticity also in culture media under cyclic mechanical strain conditions. The highly porous scaffold (90% salt wt) withstood for an initial 1 week without any deformation and sustained for 2 weeks in culture media under cyclic stress of 10% amplitude and at 1 Hz frequency which are similar to the natural vascular conditions. Vascular smooth muscle cells (VSMCs) were seeded on to the PLCL scaffolds. The cell adhesion and proliferation on the scaffolds of various pore-size were increased with increasing pore size. For the pore sizes of 50-100 μm, 100-150 μm, 150-200 μm and 200-250 μm, the ratios of cell numbers were about 1:1.2:1.9:2.2, respectively, at both 12 h and 5 days. Similarly, the higher porous scaffolds exhibited more cell adhesion and proliferation compared to lower porous one, where the effect was more pronounced in the longer proliferation period. SMC-seeded scaffolds were implanted subcutaneously in athymic nude mice to confirm the biocompatibility. Such a high elastic property and proper biocompatibility to SMCs of PLCL scaffolds prepared in this study will be very useful to engineer SM-containing tissues such as blood vessels under mechanically dynamic environments (mechano-active tissue engineering).

Cellular interactions and degradation of aliphatic poly(ester amide)s derived from glycine and/or 4-amino butyric acid

A series of poly(ester amide)s derived from amino acid (glycine or 4-amino butyric acid), diol (1,6-hexanediol or 1,4-butanediol) and sebacoyl chloride were prepared by interfacial polymerization. FT-IR analysis indicated that for poly(ester amide)s derived from glycine, only amide-amide hydrogen bonds and hydrogen-bonded C=O ester groups were established, whereas the poly(ester amide)s derived from 4-amino butyric acid contained amide-amide hydrogen bonds and amide-ester hydrogen bonds, including NH groups and C=O ester groups in free state. The biodegradability was estimated by weight residue of poly(ester amide) films in pH 6 buffer solution with papain at 37 degrees C. The poly(ester amide) films derived from glycine demonstrated significantly improved degradability compared to the poly(ester amide) films derived from 4-amino butyric acid. This difference of degradation rate could be explained by the bonding state in C=O ester groups. The cellular interaction of the poly(ester amide)s was studied by measuring the proliferation of human dermal fibroblasts on the polymer films. The cells proliferated significantly faster on poly(ester amide) films derived from 4-amino butyric acid than on poly(ester amide) films derived from glycine. These results suggest that the poly(ester amide) prepared in this study may serve as a potential cell-compatible biomedical material.

Stable hepatocyte transplantation using fibrin matrix

Fibrin matrix, a naturally derived biodegradable polymer matrix, was evaluated as a scaffold for hepatocyte transplantation in an athymic mouse model. One week after transplantation, opaque conglomerates of the transplanted hepatocytes and fibrin matrix were found on the intestinal mesentery, whereas no transplanted hepatocytes were observed in control groups (transplantation of hepatocytes suspended in culture medium). The hepatocytes in the conglomerates retained hepatocyte-specific functions, as examined with histochemical and immunohistochemical stainings. Stable hepatocyte engraftment may thus be achieved by hepatocyte transplantation using fibrin matrix.

Suspension culture of anchorage-dependent animal cells using nanospheres of the biodegradable polymer, poly(lactic-co-glycolic acid)

A novel method was developed for suspension culture of anchorage-dependent animal cells using biodegradable polymer nanospheres. The addition of poly(lactic-co-glycolic acid) nanospheres (907xa0nm average diam.) to the culture of human embryonic kidney 293 cells in stirred suspension bioreactors promoted the aggregate formation and cell growth (4.4-fold versus 2.2-fold growth for 7xa0d), compared to culture without nanospheres. This method may be useful for the culture of various types of anchorage-dependent animal cells in large-scale suspension bioreactors.