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Marine Structure Derived Calcium Phosphate–Polymer Biocomposites for Local Antibiotic Delivery

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dc.creator Macha, Innocent J
dc.creator Cazalbou, Sophie
dc.creator Ben-Nissan, Besim
dc.creator Harvey, Kate L
dc.creator Milthorpe, Bruce
dc.date 2019-02-14T18:54:11Z
dc.date 2019-02-14T18:54:11Z
dc.date 2015-01-20
dc.date.accessioned 2021-05-07T08:00:11Z
dc.date.available 2021-05-07T08:00:11Z
dc.identifier 1660-3397
dc.identifier http://hdl.handle.net/20.500.11810/5042
dc.identifier 10.3390/md13010666
dc.identifier.uri http://hdl.handle.net/20.500.11810/5042
dc.description Hydrothermally converted coralline hydroxyapatite (HAp) particles loaded with medically active substances were used to develop polylactic acid (PLA) thin film composites for slow drug delivery systems. The effects of HAp particles within PLA matrix on the gentamicin (GM) release and release kinetics were studied. The gentamicin release kinetics seemed to follow Power law Korsmeyer Peppas model with mainly diffusional process with a number of different drug transport mechanisms. Statistical analysis shows very significant difference on the release of gentamicin between GM containing PLA (PLAGM) and GM containing HAp microspheres within PLA matrix (PLAHApGM) devices, which PLAHApGM displays lower release rates. The use of HAp particles improved drug stabilization and higher drug encapsulation efficiency of the carrier. HAp is also the source of Ca2+ for the regeneration and repair of diseased bone tissue. The release profiles, exhibited a steady state release rate with significant antimicrobial activity against Staphylococcus aureus (S. aureus) (SH1000) even at high concentration of bacteria. The devices also indicated significant ability to control the growth of bacterial even after four weeks of drug release. Clinical release profiles can be easily tuned from drug-HAp physicochemical interactions and degradation kinetics of polymer matrix. The developed systems could be applied to prevent microbial adhesion to medical implant surfaces and to treat infections mainly caused by S. aureus in surgery.
dc.language en
dc.subject drug release; thin film composites; coral; hydroxyapatite; microbial adhesion; S. aureus
dc.title Marine Structure Derived Calcium Phosphate–Polymer Biocomposites for Local Antibiotic Delivery
dc.type Journal Article


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