Integration of porosity and bio-functionalization to form a 3D scaffold: cell culture studies and in vitro degradation

In this study, porous poly(lactide-co-glycolide) (PLGA) (50/50) microspheres have been fabricated by the gas-foaming technique using ammonium bicarbonate as a gas-foaming agent. Microspheres of different porosities have been formulated by varying the concentration of the gas-foaming agent (0%, 5%, 10% and 15% w/v). These microspheres were characterized for particle size, porosity and average pore size, morphology, water uptake ratio and surface area and it was found that the porosity, pore size and surface area increased on increasing the concentration of the gas-foaming agent. Further, the effect of porosity on degradation behavior was evaluated over a 12 week period by measuring changes in mass, pH, molecular weight and morphology. Porosity was found to have an inverse relationship with degradation rate. To render the surface of the microspheres biomimetic, peptide P-15 was coupled to the surface of these microspheres. In vitro cell viability, proliferation and morphological evaluation were carried out on these microsphere scaffolds using MG-63 cell line to study the effect of the porosity and pore size of scaffolds and to evaluate the effect of P-15 on cell growth on porous scaffolds. MTT assay, actin, alizarin staining and SEM revealed the potential of biomimetic porous PLGA (50/50) microspheres as scaffolds for tissue engineering. As shown in graphical representation, an attempt has been made to correlate the cell behavior on the scaffolds (growth, proliferation and cell death) with the concurrent degradation of the porous microsphere scaffold as a function of time.

[1]  L G Griffith,et al.  Integration of surface modification and 3D fabrication techniques to prepare patterned poly(L-lactide) substrates allowing regionally selective cell adhesion. , 1998, Journal of biomaterials science. Polymer edition.

[2]  Chad Johnson,et al.  The effect of scaffold degradation rate on three-dimensional cell growth and angiogenesis. , 2004, Biomaterials.

[3]  Linbo Wu,et al.  Effects of porosity and pore size on in vitro degradation of three-dimensional porous poly(D,L-lactide-co-glycolide) scaffolds for tissue engineering. , 2005, Journal of biomedical materials research. Part A.

[4]  Buddy D Ratner,et al.  Generation of porous microcellular 85/15 poly (DL-lactide-co-glycolide) foams for biomedical applications. , 2004, Biomaterials.

[5]  N. Kawazoe,et al.  In vitro evaluation of biodegradation of poly(lactic-co-glycolic acid) sponges. , 2008, Biomaterials.

[6]  E. Sachlos,et al.  Making tissue engineering scaffolds work. Review: the application of solid freeform fabrication technology to the production of tissue engineering scaffolds. , 2003, European cells & materials.

[7]  J. Qian,et al.  Design of biomimetic habitats for tissue engineering with P-15, a synthetic peptide analogue of collagen. , 1999, Tissue engineering.

[8]  Linbo Wu,et al.  A comparative study of porous scaffolds with cubic and spherical macropores , 2005 .

[9]  S. Hollister,et al.  Optimal design and fabrication of scaffolds to mimic tissue properties and satisfy biological constraints. , 2002, Biomaterials.

[10]  B. Atkinson,et al.  Comparison of cell viability on anorganic bone matrix with or without P-15 cell binding peptide. , 2004, Biomaterials.

[11]  Song Li,et al.  Enhanced cell attachment and osteoblastic activity by P-15 peptide-coated matrix in hydrogels. , 2003, Biochemical and biophysical research communications.

[12]  Dietmar W. Hutmacher,et al.  Scaffold design and fabrication technologies for engineering tissues — state of the art and future perspectives , 2001, Journal of biomaterials science. Polymer edition.

[13]  Robert Langer,et al.  Preparation and characterization of poly(l-lactic acid) foams , 1994 .

[14]  Xiaoyan Yuan,et al.  A nanofibrous composite membrane of PLGA-chitosan/PVA prepared by electrospinning , 2006 .

[15]  T. Park,et al.  Gas foamed open porous biodegradable polymeric microspheres. , 2006, Biomaterials.

[16]  K. Leong,et al.  Fabrication of controlled release biodegradable foams by phase separation. , 1995, Tissue engineering.

[17]  Kevin E. Healy,et al.  A novel method to fabricate bioabsorbable scaffolds , 1995 .

[18]  S. Verma,et al.  Surface modified poly(L-lactide-co-ε-caprolactone) microspheres as scaffold for tissue engineering , 2007 .

[19]  D. Mooney,et al.  Hydrogels for tissue engineering: scaffold design variables and applications. , 2003, Biomaterials.

[20]  L. Bonassar,et al.  A Novel Injectable Approach for Cartilage Formation in Vivo Using PLG Microspheres , 2004, Annals of Biomedical Engineering.

[21]  R Langer,et al.  Stabilized polyglycolic acid fibre-based tubes for tissue engineering. , 1996, Biomaterials.

[22]  Allan S Hoffman,et al.  Hydrogels for biomedical applications. , 2002, Advanced drug delivery reviews.

[23]  Linbo Wu,et al.  In vitro degradation of three-dimensional porous poly(D,L-lactide-co-glycolide) scaffolds for tissue engineering. , 2004, Biomaterials.

[24]  Tae Gwan Park,et al.  Highly open porous biodegradable microcarriers: in vitro cultivation of chondrocytes for injectable delivery. , 2008, Tissue engineering. Part A.

[25]  F. Gomar,et al.  P-15 small peptide bone graft substitute in the treatment of non-unions and delayed union. A pilot clinical trial , 2007, International Orthopaedics.

[26]  J. Yoon,et al.  Degradation behaviors of biodegradable macroporous scaffolds prepared by gas foaming of effervescent salts. , 2001, Journal of biomedical materials research.

[27]  R Langer,et al.  Novel approach to fabricate porous sponges of poly(D,L-lactic-co-glycolic acid) without the use of organic solvents. , 1996, Biomaterials.