Liu Sihui, Lu Di, Wang Xinchang, Ding Dan, Kong Deling, Wang Zheng, Zhao Yanjun
School of Pharmaceutical Science & Technology, Tianjin Key Laboratory for Modern Drug Delivery & High Efficiency, and Collaborative Innovation Center of Chemical Science and Engineering (Tianjin), Tianjin University, Tianjin 300072, China.
J Mater Chem B. 2017 Jul 7;5(25):4918-4925. doi: 10.1039/c7tb00954b. Epub 2017 May 31.
Both reactive oxygen species (ROS) and mitochondria are involved in many physiological and pathological processes. Herein, we employed curved corannulene with a large dipole moment for controlled ROS production and mitochondria targeting. Corannulene was solubilized in water via complexation with gamma-cyclodextrin (1 : 2). The complex could produce type I ROS in water in a dose- and irradiation time-dependent manner. The curvature-induced dipole moment aids electron transfer and hence enables ROS generation. As a consequence of electron delocalization, which facilitates mitochondrial uptake due to the large negative membrane potential of mitochondria, mitochondrial accumulation of corannulene was demonstrated. However, this is not valid for the flat perylene control. This discovery not only presents a new tool for controlled ROS production as well as mitochondria targeting in basic biomedical research, but also opens an avenue for the potential application of curved carbon materials as therapeutic agents.
活性氧(ROS)和线粒体都参与许多生理和病理过程。在此,我们使用具有大偶极矩的弯曲蒄来控制ROS的产生并靶向线粒体。通过与γ-环糊精(1∶2)络合,蒄可溶解于水中。该络合物能够以剂量和辐照时间依赖的方式在水中产生I型ROS。曲率诱导的偶极矩有助于电子转移,从而实现ROS的产生。由于电子离域作用,线粒体具有较大的负膜电位,这有利于线粒体摄取,因此证明了蒄在线粒体中的积累。然而,对于平面苝对照而言并非如此。这一发现不仅为基础生物医学研究中控制ROS产生以及靶向线粒体提供了一种新工具,而且还为弯曲碳材料作为治疗剂的潜在应用开辟了一条途径。
