Thermosensitive Nanocomposite Hydrogels for Intravitreal Delivery of Cefuroxime

• Main Authors: Simona Sapino, Elena Peira, Daniela Chirio, Giulia Chindamo, Stefano Guglielmo, Simonetta Oliaro-Bosso, Raffaella Barbero, Cristina Vercelli, Giovanni Re, Valentina Brunella, Chiara Riedo, Antonio Maria Fea, Marina Gallarate
• Format: Article
• Language: English
• Published: MDPI AG 2019-10-01
• Series: Nanomaterials
• Subjects: cefuroxime; endophthalmitis; nanocomposite thermosensitive hydrogels; vitreous humor; ocular flow cell
• Online Access: https://www.mdpi.com/2079-4991/9/10/1461

Endophthalmitis is a rare, but serious, intravitreal inflammatory disorder that can arise after cataract surgery. The intracameral injection of 1 mg cefuroxime (CEF) followed by three-times daily antibiotic topical administration for a week is generally recognized as the routine method of prophylaxis after cataract surgery. This procedure is controversial because of both the low efficacy and the low adherence to therapy by elderly patients. A unique slow release antibiotic intravitreal injection could solve these problems. The objective of the present study was to design ophthalmic nanocomposite delivery systems based on in situ gelling formulations that undergo sol-to-gel transition upon change in temperature to prolong the effect of CEF. Oil in water (O/W) microemulsion (&#181;E) and solid lipid nanoparticles (SLN), obtained with an innovative formulation technology called <i>cold microemulsion dilution</i>, were evaluated as ocular drug delivery systems for CEF. Drug entrapment efficiency up to 80% was possible by esterifying CEF with 1-dodecanol to obtain dodecyl-CEF (dCEF). Both dCEF-loaded SLN and &#181;E were then added with Pluronic&#174;F127 (20% <i>w</i>/<i>v</i>) to obtain a nanocomposite hydrogel-based long acting system. The prepared thermosensitive formulations were evaluated for their physical appearance, drug content, gelation temperature, injectability and rheological properties, in vitro release studies and stability studies. Moreover, cell proliferation assays on human retinal pigment epithelial ARPE-19 cells were performed to evaluate the influence of this innovative system on the cellular viability. In addition, minimal inhibitory concentration (MIC) was assessed for both CEF and dCEF, revealing the need of dCEF hydrolysis for the antimicrobial activity. Although further experimental investigations are required, the physico-chemical characterization of the nanocomposite hydrogels and the preliminary in vitro release studies highlighted the potential of these systems for the sustained release of CEF.