一种可生物降解的纳米给药平台,用于米诺环素和壳聚糖的联合给药,实现高效安全的非手术牙周炎治疗。

Jinxin Yang, Jie Mou, Kexin Ding, Shaoyue Zhu, Zhe Sun, Yawen Cui, Sihan Meng, Guowei Qiang, Weisen Zhong, Zongxiang Liu
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引用次数: 0

摘要

导言:介孔二氧化硅纳米颗粒(MSN)作为理想的纳米载体被广泛应用于化疗药物的输送。然而,由于二氧化硅在生物体内降解缓慢,在大多数相关研究中保持高抗牙周炎活性和低生物毒性之间的平衡一直是个挑战:本研究将响应性羟基磷灰石(HAP)掺杂到MSN骨架中,将化疗药物盐酸米诺环素(MH)负载到MSN孔隙中,形成带负电荷的给药系统。阳离子壳聚糖(COS)是一种可生物降解的材料,具有很高的抗菌性能和良好的生物安全性。本研究通过稳定的电荷相互作用将 COS 固定在载药颗粒表面,构建了一种复合给药系统(MH@MSNion@COS):体外实验和细胞实验表明,纳米载药系统能有效降解药物并同步控制药物释放。值得注意的是,与单一的 MH 给药相比,该系统中 MH 和 COS 共同调节牙周炎相关炎症因子(TNF-α、IL-6、IL-1β 和 iNOS)的表达水平,能更好地抑制牙周炎的进展并诱导组织再生,同时不会对细胞产生明显的毒副作用:该系统为设计智能、高效、安全的抗牙周炎给药系统提供了一种可行的策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Biodegradable Nano-Drug Delivery Platform for Co-Delivery of Minocycline and Chitosan to Achieve Efficient and Safe Non-Surgical Periodontitis Therapy.

Introduction: Mesoporous silica nanoparticles (MSN) are widely used as ideal nanovehicles for the delivery of chemotherapeutic drugs. However, the balance between high anti-periodontitis activity and low biotoxicity has been challenging to maintain in most relevant studies owing to the slow degradation of silica in living organisms.

Method: In this study, -responsive hydroxyapatite (HAP) was doped into the MSN skeleton, and the chemotherapeutic drug minocycline hydrochloride (MH) was loaded into the pores of MSN, forming a negatively charged drug delivery system. Cationic chitosan (COS) is a biodegradable material with high antibacterial performance and good biosafety. In this study, COS was immobilized on the surface of the drug-loaded particles through stable charge interaction to construct a composite drug delivery system (MH@MSNion@COS).

Results: In vitro and cellular experiments demonstrated effective degradation of the nanocarrier system and synchronized controlled release of the drug. Notably, compared with single MH administration, this system, in which MH and COS jointly regulated the expression levels of periodontitis- associated inflammatory factors (TNF-α, IL-6, IL-1β, and iNOS), better inhibited the progress of periodontitis and induced tissue regeneration without showing significant toxic side effects in cells.

Conclusion: This system provides a promising strategy for the design of intelligent, efficient, and safe anti-periodontitis drug delivery systems.

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