One-step solid-oil-water emulsion for sustained bioactive ranibizumab release
Background: The advent of therapeutic proteins highlights the need for delivery systems that protect and extend the duration of its action. Ranibizumab-VEGF is one such drug used for treating wet AMD. This paper describes a facile method to sustain bioactive ranibizumab release from PLGA-based parti...
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sg-ntu-dr.10356-1406112020-06-01T10:43:37Z One-step solid-oil-water emulsion for sustained bioactive ranibizumab release Chua, Hui Yee Lui, Yuan Siang Bhuthalingam, Ramya Agrawal, Rupesh Wong, Tina Preiser, Peter Rainer Venkatraman, Subbu School of Materials Science & Engineering School of Biological Sciences Interdisciplinary Graduate School (IGS) Institute for Health Technologies Engineering::Materials Bioactive PLGA Background: The advent of therapeutic proteins highlights the need for delivery systems that protect and extend the duration of its action. Ranibizumab-VEGF is one such drug used for treating wet AMD. This paper describes a facile method to sustain bioactive ranibizumab release from PLGA-based particles. Methods: Two emulsion techniques were explored namely: water-in-oil-in-water (WOW) and solid-in-oil-in-water (SOW) emulsion. The bioactivity of ranibizumab was evaluated by comparing its binding capability to VEGF, measured with ELISA to total protein measured by microBCA. Results: During the emulsion process, contact of ranibizumab with the water-oil interface is the main destabilizing factor and this can be prevented with the use of amphiphilic PVA and solid-state protein in WOW and SOW emulsion respectively. In vitro release of the ranibizumab-loaded particles indicated that a 15-day release could be achieved with SOW particles while the WOW particles generally suffered from a burst release. Released ranibizumab was capable of inhibiting endothelial cell growth indicating its retention of bioactivity. The suppression of burst release from the SOW particles was attributed to the relatively smooth surface morphology of the SOW microparticles. Conclusions: The use of SOW encapsulation in modulating ranibizumab release while maintaining their bioactivity has been highlighted. MOE (Min. of Education, S’pore) 2020-06-01T02:10:44Z 2020-06-01T02:10:44Z 2018 Journal Article Chua, H. Y., Lui, Y. S., Bhuthalingam, R., Agrawal, R., Wong, T., Preiser, P. R., & Venkatraman, S. (2018). One-step solid-oil-water emulsion for sustained bioactive ranibizumab release. Expert Opinion on Drug Delivery, 15(12), 1143-1156. doi:10.1080/17425247.2018.1538209 1742-5247 https://hdl.handle.net/10356/140611 10.1080/17425247.2018.1538209 30354700 2-s2.0-85055436709 12 15 1143 1156 en Expert Opinion on Drug Delivery © 2018 Informa UK Limited, trading as Taylor & Francis Group. All rights reserved. |
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Engineering::Materials Bioactive PLGA |
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Engineering::Materials Bioactive PLGA Chua, Hui Yee Lui, Yuan Siang Bhuthalingam, Ramya Agrawal, Rupesh Wong, Tina Preiser, Peter Rainer Venkatraman, Subbu One-step solid-oil-water emulsion for sustained bioactive ranibizumab release |
| description |
Background: The advent of therapeutic proteins highlights the need for delivery systems that protect and extend the duration of its action. Ranibizumab-VEGF is one such drug used for treating wet AMD. This paper describes a facile method to sustain bioactive ranibizumab release from PLGA-based particles. Methods: Two emulsion techniques were explored namely: water-in-oil-in-water (WOW) and solid-in-oil-in-water (SOW) emulsion. The bioactivity of ranibizumab was evaluated by comparing its binding capability to VEGF, measured with ELISA to total protein measured by microBCA. Results: During the emulsion process, contact of ranibizumab with the water-oil interface is the main destabilizing factor and this can be prevented with the use of amphiphilic PVA and solid-state protein in WOW and SOW emulsion respectively. In vitro release of the ranibizumab-loaded particles indicated that a 15-day release could be achieved with SOW particles while the WOW particles generally suffered from a burst release. Released ranibizumab was capable of inhibiting endothelial cell growth indicating its retention of bioactivity. The suppression of burst release from the SOW particles was attributed to the relatively smooth surface morphology of the SOW microparticles. Conclusions: The use of SOW encapsulation in modulating ranibizumab release while maintaining their bioactivity has been highlighted. |
| author2 |
School of Materials Science & Engineering |
| author_facet |
School of Materials Science & Engineering Chua, Hui Yee Lui, Yuan Siang Bhuthalingam, Ramya Agrawal, Rupesh Wong, Tina Preiser, Peter Rainer Venkatraman, Subbu |
| format |
Article |
| author |
Chua, Hui Yee Lui, Yuan Siang Bhuthalingam, Ramya Agrawal, Rupesh Wong, Tina Preiser, Peter Rainer Venkatraman, Subbu |
| author_sort |
Chua, Hui Yee |
| title |
One-step solid-oil-water emulsion for sustained bioactive ranibizumab release |
| title_short |
One-step solid-oil-water emulsion for sustained bioactive ranibizumab release |
| title_full |
One-step solid-oil-water emulsion for sustained bioactive ranibizumab release |
| title_fullStr |
One-step solid-oil-water emulsion for sustained bioactive ranibizumab release |
| title_full_unstemmed |
One-step solid-oil-water emulsion for sustained bioactive ranibizumab release |
| title_sort |
one-step solid-oil-water emulsion for sustained bioactive ranibizumab release |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/140611 |
| _version_ |
1681059065172590592 |