Development of an injectable, in situ crosslinkable, degradable polymeric carrier for osteogenic cell populations. Part 1. Encapsulation of marrow stromal osteoblasts in surface crosslinked gelatin microparticles.

This study investigated the temporary encapsulation of rat marrow stromal osteoblasts in surface crosslinked gelatin microparticles. Cells were encapsulated in uncrosslinked gelatin microparticles of average diameter of 630 microm containing approximately 53 cells. Gelatin microparticles were crosslinked to shell thicknesses of approximately 75 microm via exposure to 1 mM dithiobis(succinimidylpropionate) (DSP) solution for 15 min or 5 mm DSP solution for 5 min for the production of microparticles dispersing approximately 60 min after placement into a physiologic fluid at 37 degrees C. Formed microparticles were placed into culture wells at a cell seeding density of 5.3 x 10(4) cells/cm2 and, following the degradation and/or dissolution of gelatin, the cells were cultured in the presence of osteogenic supplements for 28 days. Samples were taken at specified time points and analyzed by a DNA assay for cell number and a 3H-thymidine incorporation assay for proliferative potential. Samples were also obtained and analyzed at several time points by alkaline phosphatase, osteocalcin, and mineralization assays for early and late phenotypic expression markers of osteoblastic differentiation. The measurements from the different assays for encapsulated cells (EC) in uncrosslinked and crosslinked gelatin microparticles were normalized with the cell numbers from the DNA assay and compared with those for nonencapsulated control cells. The results demonstrated that the marrow stromal cells survived the encapsulation procedure in uncrosslinked gelatin microparticles and also retained their proliferative potential and osteoblastic phenotype over a 28 day period, although at a slightly lower level than the nonencapsulated cells. The results further showed that the marrow stromal cells survived the encapsulation in crosslinked gelatin microparticles prepared via exposure to 5mm DSP for 5 min and also retained their proliferative potential and osteoblastic phenotype over a 28 day period, but at a slightly lower level than the EC in uncrosslinked gelatin microparticles. In contrast, exposure to 1 mM DSP for 15 min led to severely limited cell viability and phenotypic expression probably due to the increased crosslinking time. These results suggest that temporary encapsulation of cells in gelatin microparticles may protect cells from short-term environmental effects such as those associated with the crosslinking of an injectable polymeric carrier for bone tissue engineering.

[1]  Y. Ikada,et al.  Bone regeneration by basic fibroblast growth factor complexed with biodegradable hydrogels. , 1998, Biomaterials.

[2]  Sung Wan Kim,et al.  Thermoreversible Gelation of PEG−PLGA−PEG Triblock Copolymer Aqueous Solutions , 1999 .

[3]  A. Mikos,et al.  Effects of biodegradable polymer particles on rat marrow-derived stromal osteoblasts in vitro. , 1998, Biomaterials.

[4]  R. Lanza,et al.  Xenotransplantation of cells using biodegradable microcapsules. , 1999, Transplantation.

[5]  Richard A. Johnson,et al.  Applied Multivariate Statistical Analysis , 1983 .

[6]  W. Hayes,et al.  The ingrowth of new bone tissue and initial mechanical properties of a degrading polymeric composite scaffold. , 1995, Tissue engineering.

[7]  A. Mikos,et al.  In vivo degradation of a poly(propylene fumarate)/beta-tricalcium phosphate injectable composite scaffold. , 1998, Journal of biomedical materials research.

[8]  A. Mikos,et al.  Osteoblastic phenotype of rat marrow stromal cells cultured in the presence of dexamethasone, β‐glycerolphosphate, and L‐ascorbic acid , 1998, Journal of cellular biochemistry.

[9]  M. Sefton,et al.  Polyacrylate Microcapsules for Cell Delivery , 1996 .

[10]  M J Yaszemski,et al.  Bone formation by three-dimensional stromal osteoblast culture in biodegradable polymer scaffolds. , 1997, Journal of Biomedical Materials Research.

[11]  Michael A. Barry,et al.  An optimized method for the chemiluminescent detection of alkaline phosphatase levels during osteodifferentiation by bone morphogenetic protein 2 , 2001, Journal of cellular biochemistry.

[12]  G. Stein,et al.  The developmental stages of osteoblast growth and differentiation exhibit selective responses of genes to growth factors (TGF beta 1) and hormones (vitamin D and glucocorticoids). , 1993, The Journal of oral implantology.

[13]  A. Mikos,et al.  In vitro degradation of a poly(propylene fumarate)/β-tricalcium phosphate composite orthopaedic scaffold , 1997 .

[14]  Smadar Cohen,et al.  Microparticulate Systems for the Delivery of Proteins and Vaccines , 2020 .

[15]  M. Sefton,et al.  Viability and protein secretion from human Hepatoma (HepG2) cells encapsulated in 400‐μm polyacrylate microcapsules by submerged nozzle–liquid jet extrusion , 1994, Biotechnology and bioengineering.

[16]  A. Mikos,et al.  Crosslinking characteristics of an injectable poly(propylene fumarate)/β‐tricalcium phosphate paste and mechanical properties of the crosslinked composite for use as a biodegradable bone cement , 1999 .

[17]  A. Mikos,et al.  Osteoblast function on synthetic biodegradable polymers. , 1994, Journal of biomedical materials research.

[18]  Y. Sakai,et al.  Non-antigenic and low allergic gelatin produced by specific digestion with an enzyme-coupled matrix. , 1998, Biological & pharmaceutical bulletin.