] (2012). Biosynthesis of highly pure poly-γ-glutamic acid for biomedical applications. Journal of Materials Science: Materials in MedicineJ. Mater. Sci. Mater. Med., 23(7), 1583 - 1591.
(2010). In vivo evaluation of highly macroporous ceramic scaffolds for bone tissue engineering. Journal of Biomedical Materials Research - Part AJ. Biomed. Mater. Res. Part A, 93(2), 567 - 575.
(2010). Protein matrices for improved wound healing: Elastase inhibition by a synthetic peptide model. BiomacromoleculesBiomacromolecules, 11(9), 2213 - 2220.
(2008). Surface characterization and cell response of a PLA/CaP glass biodegradable composite material. Journal of Biomedical Materials Research - Part AJ. Biomed. Mater. Res. Part A, 85(2), 477 - 486.
(2006). In vivo performance of biodegradable calcium phosphate glass ceramics using the rabbit model: Histological and SEM observation. Journal of Biomaterials ApplicationsJ. Biomater. Appl., 20(3), 253 - 266.
(2005). Biocatalytic synthesis of highly ordered degradable dextran-based hydrogels. BiomaterialsBiomaterials, 26(23), 4707 - 4716.
(2005). In vitro studies of calcium phosphate glass ceramics with different solubility with the use of human bone marrow cells. Journal of Biomedical Materials Research - Part AJ. Biomed. Mater. Res. Part A, 74(3), 347 - 355.
(2004). Biological Activity of Two Glass Ceramics in the Meta- and Pyrophosphate Region: A Comparative Study. ()Key Engineering MaterialsKey Eng Mat (Vol. 254-256, pp. 825 - 828).
(2004). Bonelike®/PLGA hybrid materials for bone regeneration: In vivo evaluation. ()Materials Science ForumMater Sci Forum (Vol. 455-456, pp. 374 - 377).
(2004). Crystallisation studies of biodegradable CaO-P 2O
5 glass with MgO and TiO
2 for bone regeneration applications
. Glass TechnologyGlass Technol, 45(2), 78 - 79.
(2004). In Vivo Behaviour of Bonelike®/PLGA Hybrid: Histological Analysis and Peripheral Quantitative Computed Tomography (pQ-CT) Evaluation. ()Key Engineering MaterialsKey Eng Mat (Vol. 254-256, pp. 565 - 568).
(2004). Protein adsorption effect on in vitro acellular biodegradation of CaO-P 2O
5 glass ceramics
. ()Materials Science ForumMater Sci Forum (Vol. 455-456, pp. 398 - 401).
(2004). Protein electrostatic self-assembly on poly(DL-lactide) scaffold to promote osteoblast growth. Journal of Biomedical Materials Research - Part B Applied BiomaterialsJ. Biomed. Mater. Res. Part B Appl. Biomater., 71(1), 159 - 165.
(2004). The Valences of Egg White for Designing Smart Porous Bloceramics: As Foaming and Consolidation Agent. ()Key Engineering MaterialsKey Eng Mat (Vol. 254-256, pp. 1045 - 1048).
(1998). Decreased consumption of Ca and P during in vitro biomineralization and biologically induced deposition of Ni and Cr in presence of stainless steel corrosion products. Journal of Biomedical Materials ResearchJ. Biomed. Mater. Res., 42(2New York, NY, United States), 199 - 212.
(1998). New starch-based thermoplastic hydrogels for use as bone cements or drug-delivery carriers. Journal of Materials Science: Materials in MedicineJ. Mater. Sci. Mater. Med., 9(12), 825 - 833.
(1997). Processing and in vitro degradation of starch/EVOH thermoplastic blends. Polymer InternationalPolym. Int., 43(4), 347 - 352.
(1997). Structure development and control of injection-molded hydroxylapatite-reinforced starch/EVOH composites. Advances in Polymer TechnologyAdv Polym Technol, 16(4), 263 - 277.
(1996). In vitro calcium phosphate formation on SiO 2-Na
2O-CaO-P
2O
5 glass reinforced hydroxyapatite composite: A study by XPS analysis
. Journal of Materials Science: Materials in MedicineJ. MATER. SCI. MATER. MED., 7(3London, United Kingdom), 181 - 185.