| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 1429718 | Materials Science and Engineering: C | 2011 | 5 Pages |
Limited blood circulation to the skeletal tissue is a major cause of reduced therapeutic effects seen with drugs administered by conventional systemic ways. To resolve this issue and obtain a sufficiently high local concentration to induce therapeutic effects, several implanted drug delivery systems have been developed for hard tissues using biomaterials.We have designed a drug delivery device based on hydroxylapatite (HA) and tested it in vitro using metronidazol and chloramphenicol as model compounds. Porous HA ceramics were prepared with two different shapes (cylindrical and spherical). Known amounts of drugs were introduced inside a drilled hole and sealed with wax. The ceramics were then suspended in stirred distilled water in closed polypropylene vials. Drug release was observed during several weeks.A mathematical model used to describe drug release from HA was elaborated based on the expressions of Fick's laws. The experimental kinetic results could be related to ceramic constitution and to drug localization.
Research highlights► Sustained release of drugs loaded into hydroxyapatite ceramics was observed. ► Drug release rates depend on drug location in ceramic. ► Drug-release kinetics were modelled by adapted mathematical equations.
