Degradation, Intra-Articular Biocompatibility, Drug Release, and Bioactivity of Tacrolimus-Loaded Poly(d - L -lactide-PEG)- b-poly(l -lactide) Multiblock Copolymer-Based Monospheres
ACS Biomaterials Science and Engineering , Volume 4 - Issue 7 p. 2390- 2403
The aim of this study was to develop a formulation with a sustained intra-articular release of the anti-inflammatory drug tacrolimus. Drug release kinetics from the prepared tacrolimus loaded monodisperse biodegradable microspheres based on poly(d-l-lactide-PEG)-b-poly(l-lactide) multiblock copolymers were tunable by changing polymer composition, particularly hydrophobic-hydrophilic block ratio. The monospheres were 30 μm and released the drug, depending on the formulation, in 7 to >42 days. The formulation exhibiting sustained release for 1 month was selected for further in vivo evaluation. Rat knees were injected with three different doses of tacrolimus (10 wt %) loaded monospheres (2.5, 5.0, and 10 mg), contralateral control knees with saline. Micro-CT and histology showed no negative changes on cartilage, indicating good biocompatibility. Minor osteophyte formation was seen in a dose dependent fashion, suggesting local drug release and therapeutic action thereof. To investigate in vivo drug release, tacrolimus monospheres were injected into horse joints, after which multiple blood and synovial fluid samples were taken. Sustained intra-articular release was seen during the entire four-week follow-up, with negligible systemic drug concentrations (<1 ng/mL), confirming the feasibility of local intra-articular drug delivery without provoking systemic effects. Intra-articular injection of unloaded monospheres led to a transient inflammatory reaction, measured by total synovial leucocyte count (72 h). This reaction was significantly lower in joints injected with tacrolimus loaded monospheres, showing not only the successful local tacrolimus delivery but also local anti-inflammatory action. This local anti-inflammatory potential without systemic side-effects can be beneficial in the treatment of inflammatory joint diseases, among which is osteoarthritis.
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|ACS Biomaterials Science and Engineering|
|Organisation||Department of Orthopaedics|
Sandker, M, Duque, L.F. (Luisa F.), Redout, E.M, Klijnstra, E, Steendam, R, Kops, N, … Weinans, H.H. (2018). Degradation, Intra-Articular Biocompatibility, Drug Release, and Bioactivity of Tacrolimus-Loaded Poly(d - L -lactide-PEG)- b-poly(l -lactide) Multiblock Copolymer-Based Monospheres. ACS Biomaterials Science and Engineering, 4(7), 2390–2403. doi:10.1021/acsbiomaterials.8b00116