| 1 - 3 |
Current trends on porous inorganic materials for biomedical applications
Vallet-Regi M |
| 4 - 13 |
Mesoporous silicate materials as substrates for molecular machines and drug delivery
Angelos S, Liong M, Choi E, Zink JI |
| 14 - 22 |
Calcium carbonate microcapsules encapsulating biomacromolecules
Fujiwara M, Shiokawa K, Morigaki K, Zhu YC, Nakahara Y |
| 23 - 29 |
Biocompatible mesoporous silica nanoparticles with different morphologies for animal cell membrane, penetration
Trewyn BG, Nieweg JA, Zhao Y, Lin VSY |
| 30 - 37 |
Studies on MCM-41 mesoporous silica for drug delivery: Effect of particle morphology and amine functionalization
Manzano M, Aina V, Arean CO, Balas F, Cauda V, Colilla M, Delgado MR, Vallet-Regi M |
| 38 - 44 |
Comparative study of solid silica nanoparticles and hollow silica nanoparticles for the immobilization of lysozyme
Xiao QG, Tao X, Zou HK, Chen JF |
| 45 - 53 |
Synthesis and stealthing study of bare and PEGylated silica micro- and nanoparticles as potential drug-delivery vectors
Yague C, Moros M, Grazu V, Arruebo M, Santamaria J |
| 54 - 61 |
Synthesis and characterization of MCM-41 spheres inside bioactive glass-ceramic scaffold
Mortera R, Onida B, Fiorilli S, Cauda V, Brovarone CV, Baino F, Verne E, Garrone E |
| 62 - 71 |
Hydroxyapatite/beta-tricalcium phosphate/agarose macroporous scaffolds for bone tissue engineering
Sanchez-Salcedo S, Nieto A, Vallet-Regi M |
| 72 - 83 |
Nanostructured poly(vinyl alcohol)/bioactive glass and poly (vinyl alcohol)/chitosan/bioactive glass hybrid scaffolds for biomedical applications
Mansur HS, Costa HS |
| 84 - 96 |
Porous three-dimensional scaffolds made of mineralised collagen: Preparation and properties of a biomimetic nanocomposite material for tissue engineering of bone
Gelinsky M, Welzel PB, Simon P, Bernhardt A, Konig U |
| 97 - 101 |
Protein binding to peptide-imprinted porous silica scaffolds
Brown ME, Puleo DA |
| 102 - 121 |
In vivo and in vitro applications of collagen-GAG scaffolds
Harley BAC, Gibson LJ |
| 122 - 128 |
Synthesis and cytocompatibility of porous chitosan-silicate hybrids for tissue engineering scaffold application
Shirosaki Y, Okayama T, Tsuru K, Hayakawa S, Osaka A |
| 129 - 136 |
3D-glass-ceramic scaffolds with antibacterial properties for bone grafting
Vitale-Brovarone C, Miola M, Alagna CB, Verne E |
| 137 - 143 |
Continuous hollow alumina gel fibers by direct electrospinning of an alkoxide-based precursor
Maneeratana V, Sigmund WM |
| 144 - 153 |
Stimulated in vitro bone-like apatite formation by a novel laser processing technique
Pecheva E, Petrov T, Lungu C, Montgomery P, Pramatarova L |
| 154 - 161 |
Biomimetic calcium phosphate coating on electrospun poly (epsilon-caprolactone) scaffolds for bone tissue engineering
Yang F, Wolke JGC, Jansen JA |
| 162 - 172 |
Fabrication and chemical surface modification of mesoporous silicon for biomedical applications
Salonen J, Lehto VP |
| 173 - 179 |
Low-pressure synthesis and characterisation of hydroxyapatite derived from mineralise red algae
Walsh PJ, Buchanan FJ, Dring M, Maggs C, Bell S, Walker GM |
