PURPOSE: Our goal is to develop a novel drug delivery system that can potentially improve clinical outcomes compared to current methods of dosing drugs such as dexamethasone or gentamicin. This system focuses on a single local application to the inner ear via the round window membrane. HYPOTHESIS: A chitosan-glycerophosphate (CGP)-hydrogel based drug delivery system can be engineered to provide local and sustained drug release to the inner ear. STUDY DESIGN: In vitro: drug release and (CGP)-hydrogel matrix degradation were characterized using dexamethasone as a model drug. In vivo: dexamethasone laden CGP-hydrogel was placed in the round window niche of mice. Perilymph samples were obtained from the oval window and analyzed for dexamethasone. The impact of CGP-hydrogel on auditory function was evaluated. RESULTS: In vitro: A CGP-hydrogel was designed to release 92% of the dexamethasone load over 4 consecutive days with concurrent degradation of the hydrogel matrix. In vivo: After surgical placement of CGP-hydrogel to the round window niche, we detected elevated levels of dexamethasone in perilymph for 5 days. Auditory function testing revealed a temporary hearing loss in the immediate postoperative period, which resolved by the 10th postoperative day. CONCLUSIONS: We report the development of CGP-hydrogel, a biodegradable matrix that achieves local, sustained delivery of dexamethasone to the inner ear. There were no significant complications resulting from the surgical procedure or the administration of CGP-hydrogel to our murine model.
PURPOSE: Our goal is to develop a novel drug delivery system that can potentially improve clinical outcomes compared to current methods of dosing drugs such as dexamethasone or gentamicin. This system focuses on a single local application to the inner ear via the round window membrane. HYPOTHESIS: A chitosan-glycerophosphate (CGP)-hydrogel based drug delivery system can be engineered to provide local and sustained drug release to the inner ear. STUDY DESIGN: In vitro: drug release and (CGP)-hydrogel matrix degradation were characterized using dexamethasone as a model drug. In vivo: dexamethasone laden CGP-hydrogel was placed in the round window niche of mice. Perilymph samples were obtained from the oval window and analyzed for dexamethasone. The impact of CGP-hydrogel on auditory function was evaluated. RESULTS: In vitro: A CGP-hydrogel was designed to release 92% of the dexamethasone load over 4 consecutive days with concurrent degradation of the hydrogel matrix. In vivo: After surgical placement of CGP-hydrogel to the round window niche, we detected elevated levels of dexamethasone in perilymph for 5 days. Auditory function testing revealed a temporary hearing loss in the immediate postoperative period, which resolved by the 10th postoperative day. CONCLUSIONS: We report the development of CGP-hydrogel, a biodegradable matrix that achieves local, sustained delivery of dexamethasone to the inner ear. There were no significant complications resulting from the surgical procedure or the administration of CGP-hydrogel to our murine model.
Authors: Young Ho Kim; Kyung Tae Park; Byung Yoon Choi; Min Hyun Park; Jun Ho Lee; Seung-Ha Oh; Sun O Chang Journal: Eur Arch Otorhinolaryngol Date: 2011-12-08 Impact factor: 2.503
Authors: Mohammad N Kayyali; Julian R A Wooltorton; Andrew J Ramsey; Mei Lin; Tiffany N Chao; Andrew Tsourkas; Bert W O'Malley; Daqing Li Journal: J Control Release Date: 2018-04-16 Impact factor: 9.776
Authors: Andrew A McCall; Erin E Leary Swan; Jeffrey T Borenstein; William F Sewell; Sharon G Kujawa; Michael J McKenna Journal: Ear Hear Date: 2010-04 Impact factor: 3.570
Authors: Hongzhuo Liu; Liang Feng; Gaurav Tolia; Mark R Liddell; Jinsong Hao; S Kevin Li Journal: Drug Dev Ind Pharm Date: 2013-04-30 Impact factor: 3.225