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核壳水凝胶支架单次给药的双释放动力学

Dual release kinetics in a single dosage from core-shell hydrogel scaffolds.

作者信息

Khan Finaz, Bera Debbethi, Palchaudhuri Santanu, Bera Rajesh, Mukhopadhyay Madhumita, Dey Anindita, Goswami Soumyabrata, Das Susmita

机构信息

Amity Institute of Applied Sciences, Department of Chemistry, Amity University Kolkata Major Arterial Road, Action Area II, Kadampukur Village, Rajarhat Newtown West Bengal 700135 India

Department of Physics, Jadavpur University Kolkata West Bengal 700032 India.

出版信息

RSC Adv. 2018 Sep 21;8(57):32695-32706. doi: 10.1039/c8ra05358h. eCollection 2018 Sep 18.

DOI:10.1039/c8ra05358h
PMID:35547714
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9086265/
Abstract

The development of drug delivery systems with microencapsulated therapeutic agents is a promising approach to the sustained and controlled delivery of various drug molecules. The incorporation of dual release kinetics to such delivery devices further adds to their applicability. Herein, novel core-shell scaffolds composed of sodium deoxycholate and trishydroxymethylaminomethane (NaDC-Tris) have been developed with the aim of delivering two different drugs with variable release rates using the same delivery vehicle. Data obtained from XRD studies, sol-gel transition temperature measurement, rheology and fluorescence studies of the core-shell systems indicate a significant alteration in the core and the shell microstructural properties in a given system as compared to the pure hydrogels of identical compositions. The release of the model drugs Fluorescein (FL) and Rhodamine B (RhB) from the shell and the core, respectively, of the two core-shell designs studied exhibited distinctly different release kinetics. In the 25@250 core-shell system, 100% release of FL from the shell and 19% release of RhB from the core was observed within the first 5 hours, while 24.5 hours was required for the complete release of RhB from the core. For the 100@250 system, similar behaviour was observed with varied release rates and a sigmoidal increase in the core release rate upon disappearance from the shell. Cell viability studies suggested the minimal toxicity of the developed delivery vehicles towards NMuMG and WI-38 cells in the concentration range investigated. The reported core-shell systems composed of a single low molecular weight gelator with dual release kinetics may be designed as per the desired application for the consecutive release of therapeutic agents as required, as well as combination therapy commonly used to treat diseases such as diabetes and cancer.

摘要

开发具有微囊化治疗剂的药物递送系统是一种有前景的方法,可实现各种药物分子的持续和可控递送。将双释放动力学纳入此类递送装置进一步增加了它们的适用性。在此,已开发出由脱氧胆酸钠和三羟甲基氨基甲烷(NaDC-Tris)组成的新型核壳支架,目的是使用同一递送载体以可变释放速率递送两种不同的药物。从核壳系统的XRD研究、溶胶-凝胶转变温度测量、流变学和荧光研究获得的数据表明,与相同组成的纯水凝胶相比,给定系统中核和壳的微观结构性质有显著改变。在所研究的两种核壳设计中,模型药物荧光素(FL)和罗丹明B(RhB)分别从壳和核中的释放表现出明显不同的释放动力学。在25@250核壳系统中,在最初5小时内观察到壳中FL的100%释放和核中RhB的19%释放,而RhB从核中完全释放需要24.5小时。对于100@250系统,观察到类似的行为,释放速率不同,并且从壳中消失后核释放速率呈S形增加。细胞活力研究表明,在所研究的浓度范围内,所开发的递送载体对NMuMG和WI-38细胞的毒性最小。所报道的由具有双释放动力学的单一低分子量凝胶剂组成的核壳系统可根据所需应用进行设计,以按需连续释放治疗剂,以及用于治疗糖尿病和癌症等疾病的联合疗法。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1914/9086265/da16e1e37b5b/c8ra05358h-f8.jpg
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