A Combinative Assembly Strategy Inspired Reversibly Borate-Bridged Polymeric Micelles for Lesion-Specific Rapid Release of Anti-Coccidial Drugs

A Combinative Assembly Strategy Inspired Reversibly Borate-Bridged Polymeric Micelles for Lesion-Specific Rapid Release of Anti-Coccidial Drugs

Highlights A combined assembly strategy from hydrophobicity-driving and reversible borate bridges is proposed for high drug-loading efficiency and superior stability. Intestinal environment-triggered drug delivery system represents an effective treatment for local infection due to the site-specific...

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Main Authors: Hao Cheng, Huaqing Zhang, Gujun Xu, Jin Peng, Zhen Wang, Bo Sun, Djamila Aouameur, Zhechen Fan, Wenxin Jiang, Jianping Zhou, Yang Ding
Format: Article
Language:English
Published: SpringerOpen 2020-07-01
Series:Nano-Micro Letters
Subjects:
Combinative assembly strategy
Borate-bridged micelles
Dual-stimuli-triggered release
Lesion-specific location
Coccidiosis control
Online Access:http://link.springer.com/article/10.1007/s40820-020-00495-1
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spelling doaj-3d5bafa3fdca41efa42753b2e9557e242020-11-25T02:58:33ZengSpringerOpenNano-Micro Letters2311-67062150-55512020-07-0112111910.1007/s40820-020-00495-1A Combinative Assembly Strategy Inspired Reversibly Borate-Bridged Polymeric Micelles for Lesion-Specific Rapid Release of Anti-Coccidial DrugsHao Cheng0Huaqing Zhang1Gujun Xu2Jin Peng3Zhen Wang4Bo Sun5Djamila Aouameur6Zhechen Fan7Wenxin Jiang8Jianping Zhou9Yang Ding10State Key Laboratory of Natural Medicines, Department of Pharmaceutics, China Pharmaceutical UniversityState Key Laboratory of Natural Medicines, Department of Pharmaceutics, China Pharmaceutical UniversityState Key Laboratory of Natural Medicines, Department of Pharmaceutics, China Pharmaceutical UniversityState Key Laboratory of Natural Medicines, Department of Pharmaceutics, China Pharmaceutical UniversityState Key Laboratory of Natural Medicines, Department of Pharmaceutics, China Pharmaceutical UniversityDepartment of Radiation Oncology, Lineberger Comprehensive Cancer Center, Carolina Center for Cancer Nanotechnology Excellence, Carolina Institute of Nanomedicine, University of North Carolina at Chapel HillState Key Laboratory of Natural Medicines, Department of Pharmaceutics, China Pharmaceutical UniversityState Key Laboratory of Natural Medicines, Department of Pharmaceutics, China Pharmaceutical UniversityState Key Laboratory of Natural Medicines, Department of Pharmaceutics, China Pharmaceutical UniversityState Key Laboratory of Natural Medicines, Department of Pharmaceutics, China Pharmaceutical UniversityState Key Laboratory of Natural Medicines, Department of Pharmaceutics, China Pharmaceutical UniversityHighlights A combined assembly strategy from hydrophobicity-driving and reversible borate bridges is proposed for high drug-loading efficiency and superior stability. Intestinal environment-triggered drug delivery system represents an effective treatment for local infection due to the site-specific targeting and shuttling of drugs. The reduced dosage brought by the drug-loading micelles could solve the problem of drug residue in breeding industry. Abstract Stimuli-triggered drug delivery systems hold vast promise in local infection treatment for the site-specific targeting and shuttling of drugs. Herein, chitosan conjugates (SPCS) installed with sialic acid (SA) and phenylboronic acid (PBA) were synthesized, of which SA served as targeting ligand for coccidium and reversible-binding bridge for PBA. The enhanced drug-loading capacity of SPCS micelles was attributed to a combination assembly from hydrophobicity-driving and reversible borate bridges. The drug-loaded SPCS micelles shared superior biostability in upper gastrointestinal tract. After reaching the lesions, the borate bridges were snipped by carbohydrates under a higher pH followed by accelerated drug release, while SA exposure on micellar surface facilitated drug cellular internalization to eliminate parasites inside. The drug-micelles revealed an enhanced anti-coccidial capacity with a higher index of 185.72 compared with commercial preparation. The dual-responsive combination of physicochemical assembly could provide an efficient strategy for the exploitation of stable, safe and flexible anti-infectious drug delivery systems.http://link.springer.com/article/10.1007/s40820-020-00495-1Combinative assembly strategyBorate-bridged micellesDual-stimuli-triggered releaseLesion-specific locationCoccidiosis control
collection DOAJ
language English
format Article
sources DOAJ
author Hao Cheng
Huaqing Zhang
Gujun Xu
Jin Peng
Zhen Wang
Bo Sun
Djamila Aouameur
Zhechen Fan
Wenxin Jiang
Jianping Zhou
Yang Ding
spellingShingle Hao Cheng
Huaqing Zhang
Gujun Xu
Jin Peng
Zhen Wang
Bo Sun
Djamila Aouameur
Zhechen Fan
Wenxin Jiang
Jianping Zhou
Yang Ding
A Combinative Assembly Strategy Inspired Reversibly Borate-Bridged Polymeric Micelles for Lesion-Specific Rapid Release of Anti-Coccidial Drugs
Nano-Micro Letters
Combinative assembly strategy
Borate-bridged micelles
Dual-stimuli-triggered release
Lesion-specific location
Coccidiosis control
author_facet Hao Cheng
Huaqing Zhang
Gujun Xu
Jin Peng
Zhen Wang
Bo Sun
Djamila Aouameur
Zhechen Fan
Wenxin Jiang
Jianping Zhou
Yang Ding
author_sort Hao Cheng
title A Combinative Assembly Strategy Inspired Reversibly Borate-Bridged Polymeric Micelles for Lesion-Specific Rapid Release of Anti-Coccidial Drugs
title_short A Combinative Assembly Strategy Inspired Reversibly Borate-Bridged Polymeric Micelles for Lesion-Specific Rapid Release of Anti-Coccidial Drugs
title_full A Combinative Assembly Strategy Inspired Reversibly Borate-Bridged Polymeric Micelles for Lesion-Specific Rapid Release of Anti-Coccidial Drugs
title_fullStr A Combinative Assembly Strategy Inspired Reversibly Borate-Bridged Polymeric Micelles for Lesion-Specific Rapid Release of Anti-Coccidial Drugs
title_full_unstemmed A Combinative Assembly Strategy Inspired Reversibly Borate-Bridged Polymeric Micelles for Lesion-Specific Rapid Release of Anti-Coccidial Drugs
title_sort combinative assembly strategy inspired reversibly borate-bridged polymeric micelles for lesion-specific rapid release of anti-coccidial drugs
publisher SpringerOpen
series Nano-Micro Letters
issn 2311-6706
2150-5551
publishDate 2020-07-01
description Highlights A combined assembly strategy from hydrophobicity-driving and reversible borate bridges is proposed for high drug-loading efficiency and superior stability. Intestinal environment-triggered drug delivery system represents an effective treatment for local infection due to the site-specific targeting and shuttling of drugs. The reduced dosage brought by the drug-loading micelles could solve the problem of drug residue in breeding industry. Abstract Stimuli-triggered drug delivery systems hold vast promise in local infection treatment for the site-specific targeting and shuttling of drugs. Herein, chitosan conjugates (SPCS) installed with sialic acid (SA) and phenylboronic acid (PBA) were synthesized, of which SA served as targeting ligand for coccidium and reversible-binding bridge for PBA. The enhanced drug-loading capacity of SPCS micelles was attributed to a combination assembly from hydrophobicity-driving and reversible borate bridges. The drug-loaded SPCS micelles shared superior biostability in upper gastrointestinal tract. After reaching the lesions, the borate bridges were snipped by carbohydrates under a higher pH followed by accelerated drug release, while SA exposure on micellar surface facilitated drug cellular internalization to eliminate parasites inside. The drug-micelles revealed an enhanced anti-coccidial capacity with a higher index of 185.72 compared with commercial preparation. The dual-responsive combination of physicochemical assembly could provide an efficient strategy for the exploitation of stable, safe and flexible anti-infectious drug delivery systems.
topic Combinative assembly strategy
Borate-bridged micelles
Dual-stimuli-triggered release
Lesion-specific location
Coccidiosis control
url http://link.springer.com/article/10.1007/s40820-020-00495-1
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