Effect of cell density on mesenchymal stem cells aggregation in RGD-alginate 3D matrices under osteoinductive conditions. Macromolecular Bioscience, 14(6), 759 - 771.
(2014). Hydrogel depots for local co-delivery of osteoinductive peptides and mesenchymal stem cells. Journal of Controlled Release, 189, 158 - 168.
(2014). Injectable alginate hydrogels for cell delivery in tissue engineering. Acta Biomaterialia, 10(4), 1646 - 1662.
(2014). Injectable MMP-sensitive alginate hydrogels as hMSC delivery systems. Biomacromolecules, 15(1), 380 - 390.
(2014). Matrix-driven formation of mesenchymal stem cell-extracellular matrix microtissues on soft alginate hydrogels. Acta Biomaterialia, 10(7), 3197 - 3208.
(2014). Advanced biofabrication strategies for skin regeneration and repair. Nanomedicine, 8(4), 603 - 621.
(2013). Enzymatic, physicochemical and biological properties of MMP-sensitive alginate hydrogels. Soft Matter, 9(12), 3283 - 3292.
(2013). Functionalization of biomaterials with small osteoinductive moieties. Acta Biomaterialia, 9(11), 8773 - 8789.
(2013). Molecularly designed alginate hydrogels susceptible to local proteolysis as three-dimensional cellular microenvironments. Acta BiomaterialiaActa Biomater., 7(4), 1674 - 1682.
(2011). Characterization of polymeric solutions as injectable vehicles for hydroxyapatite microspheres. AAPS PharmSciTechAAPS PharmSciTech, 11(2), 852 - 858.
(2010). Immobilization of human mesenchymal stem cells within RGD-grafted alginate microspheres and assessment of their angiogenic potential. BiomacromoleculesBiomacromolecules, 11(8), 1956 - 1964.
(2010). The correlation between the adsorption of adhesive proteins and cell behaviour on hydroxyl-methyl mixed self-assembled monolayers. BiomaterialsBiomaterials, 30(3), 307 - 316.
(2009). Morphology and mechanical properties of injectable ceramic microspheres. Key Engineering MaterialsKey Eng Mat (Vol. 396-398, pp. 691 - 694).
(2009). Comparative study of nanohydroxyapatite microspheres for medical applications. Journal of Biomedical Materials Research - Part AJ. Biomed. Mater. Res. Part A, 86(2), 483 - 493.
(2008). Injectability of a bone filler system based on hydroxyapatite microspheres and a vehicle with in situ gel-forming ability. Journal of Biomedical Materials Research - Part B Applied BiomaterialsJ. Biomed. Mater. Res. Part B Appl. Biomater., 87(1), 49 - 58.
(2008). Upregulation of bone cell differentiation through immobilization within a synthetic extracellular matrix. BiomaterialsBiomaterials, 28(25), 3644 - 3655.
(2007). Calcium phosphate microspheres for localised delivery of a therapeutic enzyme. Key Engineering MaterialsKey Eng Mat (Vol. 309-311 II, pp. 903 - 906).
(2006). Biological evaluation of calcium alginate microspheres as a vehicle for the localized delivery of a therapeutic enzyme. Journal of Biomedical Materials Research - Part AJ. Biomed. Mater. Res. Part A, 74(4), 545 - 552.
(2005). Effect of calcium phosphate addition to alginate microspheres: modulation of enzyme release kinetics and improvement of cell adhesion. Key Engineering MaterialsKey Eng Mat (Vol. 284-286, pp. 689 - 692).
(2005). In vitro degradation behavior of a novel bioresorbable composite material based on PLA and a soluble CaP glass. Acta BiomaterialiaActa Biomater., 1(4), 411 - 419.
(2005). Polysaccharides as scaffolds for bone regeneration. ITBM-RBMITBM-RBM, 26(3), 212 - 217.
(2005). Proliferation, activity, and osteogenic differentiation of bone marrow stromal cells cultured on calcium titanium phosphate microspheres. Journal of Biomedical Materials Research - Part AJ. Biomed. Mater. Res. Part A, 72(1), 57 - 66.
(2005). Recombinant glucocerebrosidase uptake by Gaucher disease human osteoblast culture model. Blood Cells, Molecules, and DiseasesBlood Cells Mol. Dis., 35(3), 348 - 354.
(2005). Calcium phosphate-alginate microspheres as enzyme delivery matrices. BiomaterialsBiomaterials, 25(18), 4363 - 4373.
(2004).