OBJECTIVE: Intra-articular drug delivery systems still suffer from too short-lasting effects. Magnetic particles retained in the joint using an external magnetic field might prolong the local release of an anti-inflammatory drug. For the purpose, superparamagnetic iron oxide nanoparticles (SPIONs) and dexamethasone 21-acetate (DXM) were co-encapsulated into biodegradable microparticles. METHODS: Poly(D,L-lactide-co-glycolide) microparticles embedding both SPIONs and DXM were prepared by a double emulsion technique. The formulation was optimized in two steps, a screening design and a full factorial design, aiming at 10-microm particle diameter and high DXM encapsulation efficacy. RESULTS: The most significant parameters were the polymer concentration, the stirring speed during solvent extraction and the extractive volume. Increasing the polymer concentration from 200 to 300 mg ml(-1), both the microparticle mean diameter and the DXM encapsulation efficacy increased up to 12 microm and 90%, respectively. The microparticles could be retained with an external magnet of 0.8 T placed at 3 mm. Faster DXM release was obtained for smaller microparticles. CONCLUSION: The experimental set-up offered the tools for tailoring a formulation with magnetic retention properties and DXM release patterns corresponding to the required specifications for intra-articular administration.
OBJECTIVE:Intra-articular drug delivery systems still suffer from too short-lasting effects. Magnetic particles retained in the joint using an external magnetic field might prolong the local release of an anti-inflammatory drug. For the purpose, superparamagnetic iron oxide nanoparticles (SPIONs) and dexamethasone 21-acetate (DXM) were co-encapsulated into biodegradable microparticles. METHODS:Poly(D,L-lactide-co-glycolide) microparticles embedding both SPIONs and DXM were prepared by a double emulsion technique. The formulation was optimized in two steps, a screening design and a full factorial design, aiming at 10-microm particle diameter and high DXM encapsulation efficacy. RESULTS: The most significant parameters were the polymer concentration, the stirring speed during solvent extraction and the extractive volume. Increasing the polymer concentration from 200 to 300 mg ml(-1), both the microparticle mean diameter and the DXM encapsulation efficacy increased up to 12 microm and 90%, respectively. The microparticles could be retained with an external magnet of 0.8 T placed at 3 mm. Faster DXM release was obtained for smaller microparticles. CONCLUSION: The experimental set-up offered the tools for tailoring a formulation with magnetic retention properties and DXM release patterns corresponding to the required specifications for intra-articular administration.
Authors: Jeane Chen; Alexander Y Sheu; Weiguo Li; Zhuoli Zhang; Dong-Hyun Kim; Robert J Lewandowski; Reed A Omary; Lonnie D Shea; Andrew C Larson Journal: J Control Release Date: 2014-04-13 Impact factor: 9.776
Authors: Robert K DeLong; Uzma Akhtar; Michael Sallee; Brooke Parker; Stephanie Barber; Jie Zhang; Michael Craig; Richard Garrad; Anthony J Hickey; Eric Engstrom Journal: Biomaterials Date: 2009-09-01 Impact factor: 12.479
Authors: Blanca Tobar-Grande; Ricardo Godoy; Paulina Bustos; Carlos von Plessing; Elias Fattal; Nicolas Tsapis; Claudia Olave; Carolina Gómez-Gaete Journal: Int J Nanomedicine Date: 2013-05-27
Authors: Nicoleta Butoescu; Christian A Seemayer; Gaby Palmer; Pierre-André Guerne; Cem Gabay; Eric Doelker; Olivier Jordan Journal: Arthritis Res Ther Date: 2009-05-19 Impact factor: 5.156