A bilayer swellable drug-eluting ureteric stent : localized drug delivery to treat urothelial diseases

A bilayer swellable drug-eluting ureteric stent : localized drug delivery to treat urothelial diseases

A bilayer swellable drug-eluting ureteric stent (BSDEUS) is engineered and implemented, as a sustained drug delivery platform technology that enhances localized drug delivery to the highly impermeable urothelium, for the treatment of urothelial diseases such as strictures and carcinomas. On deployme...

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Bibliographic Details
Main Authors: Lim, Wei Shan, Chen, Kenneth, Chong, Tsung Wen, Xiong, Gordon Minru, Birch, William R., Pan, Jisheng, Lee, Bae Hoon, Er, Pei Shan, Salvekar, Abhijit Vijay, Venkatraman, Subbu S., Huang, Yingying
Other Authors: School of Materials Science & Engineering
Format: Article
Language:English
Published: 2019
Subjects:
DRNTU::Engineering::Materials
Urological Diseases
Drug-Eluting Stent
Online Access:https://hdl.handle.net/10356/85858
http://hdl.handle.net/10220/48293
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Institution: Nanyang Technological University
Language: English
Description
Summary:A bilayer swellable drug-eluting ureteric stent (BSDEUS) is engineered and implemented, as a sustained drug delivery platform technology that enhances localized drug delivery to the highly impermeable urothelium, for the treatment of urothelial diseases such as strictures and carcinomas. On deployment, the device swells to co-apt with the ureteric wall and ensure drug availability to these tissues. BSDEUS consists of a stent spray-coated with a polymeric drug containing polylactic acid-cocaprolactone (PLC) layer which is overlaid by a swellable polyethylene glycol diacrylate (PEGDA) based hydrogel. In-vitro quantification of released drug demonstrated a tunable time-profile, indicating sustained delivery over 1-month. The PEGDA hydrogel overlayer enhanced drug release and transport into explanted porcine ureteric tissues ex-vivo, under a simulated dynamic fluid flow. A preliminary pilot invivo feasibility study, in a porcine model, demonstrated that the swollen hydrogel co-apts with the urothelium and thus enables localized drug delivery to the target tissue section. Kidney functions remained unaffected and device did not result in either hydronephrosis or systemic toxicity. This successful engineering of a bilayer coated stent prototype, demonstrates its feasibility, thus offering a unique solution for drug-based urological therapy.

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