A One-Stone-Two-Birds Strategy of Targeting Microbubbles with “Dual” Anti-Inflammatory and Blood–Brain Barrier “Switch” Function for Ischemic Stroke Treatment

IF 5.5 2区医学 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Biomaterials Science & Engineering Pub Date : 2024-02-29 DOI:10.1021/acsbiomaterials.3c01561

Zhongbin An, Qiong He, Ling Jiang, Yuan Wang, Yongyue Zhang, Yang Sun, Mengxin Wang, Shiyuan Yang, Lijie Huang, Huiwen Li, Yu Hao*, Xiaolong Liang* and Shumin Wang*,

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Abstract

Inflammation is considered to be the main target of the development of new stroke therapies. There are three key issues in the treatment of stroke inflammation: the first one is how to overcome the blood–brain barrier (BBB) to achieve drug delivery, the second one is how to select drugs to treat stroke inflammation, and the third one is how to achieve targeted drug delivery. In this study, we constructed hydrocortisone-phosphatidylserine microbubbles and combined them with ultrasound (US)-targeted microbubble destruction technology to successfully open the BBB to achieve targeted drug delivery. Phosphatidylserine on the microbubbles was used for its “eat me” effect to increase the targeting of the microvesicles. In addition, we found that hydrocortisone can accelerate the closure of the BBB, achieving efficient drug delivery while reducing the entry of peripheral toxins into the brain. In the treatment of stroke inflammation, it was found that hydrocortisone itself has anti-inflammatory effects and can also change the polarization of microglia from the harmful pro-inflammatory M1 phenotype to the beneficial anti-inflammatory M2 phenotype, thus achieving dual anti-inflammatory effects and enhancing the anti-inflammatory effects in ischemic areas after stroke, well reducing the cerebellar infarction volume by inhibiting the inflammatory response after cerebral ischemia. A confocal microendoscope was used to directly observe the polarization of microglial cells in living animal models for dynamic microscopic visualization detection showing the advantage of being closer to clinical work. Taken together, this study constructed a multifunctional targeted US contrast agent with the function of “one-stone-two-birds”, which can not only “on–off” the BBB but also have “two” anti-inflammatory functions, providing a new strategy of integrated anti-inflammatory targeted delivery and imaging monitoring for ischemic stroke treatment.

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具有 "双重 "抗炎和血脑屏障 "开关 "功能的靶向微气泡治疗缺血性脑卒中的 "一石二鸟 "策略。

炎症被认为是开发新中风疗法的主要靶点。治疗脑卒中炎症有三个关键问题：一是如何突破血脑屏障（BBB）实现给药；二是如何选择治疗脑卒中炎症的药物；三是如何实现靶向给药。在这项研究中，我们构建了氢化可的松-磷脂酰丝氨酸微泡，并将其与超声（US）靶向微泡破坏技术相结合，成功地打开了BBB，实现了靶向给药。微气泡上的磷脂酰丝氨酸具有 "吃掉我 "的效果，可提高微囊的靶向性。此外，我们还发现氢化可的松可以加速 BBB 的闭合，实现高效给药，同时减少外周毒素进入大脑。在治疗脑卒中炎症方面，我们发现氢化可的松本身具有抗炎作用，还能改变小胶质细胞的极化，使其从有害的促炎 M1 表型转变为有益的抗炎 M2 表型，从而达到双重抗炎效果，并增强脑卒中后缺血区域的抗炎效果，通过抑制脑缺血后的炎症反应减少小脑梗死体积。该研究利用共聚焦显微内窥镜直接观察活体动物模型中小胶质细胞的极化，进行动态显微可视化检测，显示出更贴近临床工作的优势。综上所述，本研究构建了一种具有 "一石二鸟 "功能的多功能靶向美国造影剂，它既能 "开关 "BBB，又具有 "两种 "抗炎功能，为缺血性脑卒中的治疗提供了一种抗炎靶向给药和成像监测一体化的新策略。

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来源期刊

ACS Biomaterials Science & Engineering Materials Science-Biomaterials

CiteScore

10.30

自引率

3.40%

发文量

413

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