Despite the rapid development of probes for targeting single organelle, the construction of robust dual-organelle targeting probes with multicolor emission was rarely reported. Herein, two dual-emissive aggregation-in...Despite the rapid development of probes for targeting single organelle, the construction of robust dual-organelle targeting probes with multicolor emission was rarely reported. Herein, two dual-emissive aggregation-induced emission luminogens(AIEgens)with donor-π-acceptor structures were designed and synthesized, namely QT-1 and QF-2. Both two AIEgens exhibited excitation wavelength-dependence defying the Kasha's rule, and could stain lipid droplets(LDs) and mitochondria in blue and red fluorescence, respectively. Moreover, thanks to the near-infrared emission and abundant reactive oxygen species(ROS) generation efficiency of QT-1, it was chosen as a photodynamic therapy agent to selectively kill cancer cells from normal cells. Upon light irradiation, an obvious decrease of mitochondrial membrane potential(MMP) and serious change of mitochondrial shape in cells were observed, which corresponded to the efficient inhibition of tumor growth in vivo. This work afforded a promising strategy for the construction of multicolor emission by tuning anti-Kasha behaviors and expanding their application in dualorganelle targeting-based phototheranostics.展开更多
Azulene,an isomer of naphthalene,has become one of hot chemical structures in the research field of functional materials,due to its anti-Kasha's rule emissions and unusual physicochemical properties(e.g.,photophys...Azulene,an isomer of naphthalene,has become one of hot chemical structures in the research field of functional materials,due to its anti-Kasha's rule emissions and unusual physicochemical properties(e.g.,photophysical,electrochemical,and photoelectrochemical properties).In the past,the synthesis of azulene-based compounds is relatively inconvenient.Recently,there have been more and more reports about the synthesis strategies of the azulene-based compounds for finely tuning the physicochemical properties.In this article,we introduce several synthetic methods for kinds of azulene-based compounds which has unusual physicochemical properties.With these convenient methods and unique physicochemical properties,azulene-based compounds can be applied into many fields such as specific bioimaging,advanced molecular switches,organic field-effect transistor(OFET),organic light emitting diode(OLED),solar cells,and so forth.And these properties are also summarized here.展开更多
Kasha’s rule,which states that all exciton emissions occur from the lowest excited state and are independent of excitation energy,makes high-energy excitons difficult to use and severely hinders the widespread applic...Kasha’s rule,which states that all exciton emissions occur from the lowest excited state and are independent of excitation energy,makes high-energy excitons difficult to use and severely hinders the widespread applications of organic photoluminescent materials in the real world.For decades,scientists have tried to break this rule to unleash the power of high-energy excitons,but only minimal progress has been achieved,with no rational guiding principles provided,and few applications developed.So far,breaking Kasha’s rule has remained a purely academic concept.In this paper,we introduce a design principle for a purely organic anti-Kasha system and synthesise a series of compounds based on the design rule.As predicted,these compounds all display evident S_(2) emissions in dilute solutions.In addition,we introduce a highly accurate(over 90%)convolutional neural network as an assistant for the classification of cells using anti-Kasha luminogens,thereby providing a new application direction for anti-Kasha systems.展开更多
基金supported by the National Natural Science Foundation of China (52173152, 21805002)Guangdong Basic and Applied Basic Research Foundation (2020A1515110476)+7 种基金the Fund of the Rising Stars of Shaanxi Province (2021KJXX-48)the Shenzhen Science and Technology Program (KQTD20210811090115019)the Major Instrumentation Development Program of the Chinese Academy of Sciences(ZDKYYQ20220008)Shenzhen Basic Research (key project)(China)(JCYJ20210324120011030)the Scientific and Technological Innovation Team of Shaanxi Province (2022TD-36)the National Key R&D Programs(China)(2021YFA0910001)Shaanxi Fundamental Science Research Project for Chemistry&Biology (22JHQ078)the Scientific Research Program Funded by Shaanxi Provincial Education Department (22JK0247)。
文摘Despite the rapid development of probes for targeting single organelle, the construction of robust dual-organelle targeting probes with multicolor emission was rarely reported. Herein, two dual-emissive aggregation-induced emission luminogens(AIEgens)with donor-π-acceptor structures were designed and synthesized, namely QT-1 and QF-2. Both two AIEgens exhibited excitation wavelength-dependence defying the Kasha's rule, and could stain lipid droplets(LDs) and mitochondria in blue and red fluorescence, respectively. Moreover, thanks to the near-infrared emission and abundant reactive oxygen species(ROS) generation efficiency of QT-1, it was chosen as a photodynamic therapy agent to selectively kill cancer cells from normal cells. Upon light irradiation, an obvious decrease of mitochondrial membrane potential(MMP) and serious change of mitochondrial shape in cells were observed, which corresponded to the efficient inhibition of tumor growth in vivo. This work afforded a promising strategy for the construction of multicolor emission by tuning anti-Kasha behaviors and expanding their application in dualorganelle targeting-based phototheranostics.
基金supported by the National Natural Science Foundation of China(No.21644005)National Program for Thousand Young Talents of China
文摘Azulene,an isomer of naphthalene,has become one of hot chemical structures in the research field of functional materials,due to its anti-Kasha's rule emissions and unusual physicochemical properties(e.g.,photophysical,electrochemical,and photoelectrochemical properties).In the past,the synthesis of azulene-based compounds is relatively inconvenient.Recently,there have been more and more reports about the synthesis strategies of the azulene-based compounds for finely tuning the physicochemical properties.In this article,we introduce several synthetic methods for kinds of azulene-based compounds which has unusual physicochemical properties.With these convenient methods and unique physicochemical properties,azulene-based compounds can be applied into many fields such as specific bioimaging,advanced molecular switches,organic field-effect transistor(OFET),organic light emitting diode(OLED),solar cells,and so forth.And these properties are also summarized here.
基金National Natural Science Foundation of China,Grant/Award Number:51903052Shanghai Pujiang Project,Grant/Award Number:19PJ1400700+4 种基金Zhejiang Provincial Natural Science Foundation of China,Grant/Award Number:LR17F050001the National Science Foundation of China,Grant/Award Numbers:21788102,21805002,61735016,61975172the Research Grants Council of Hong Kong,Grant/Award Numbers:16305518,16304819,N-HKUST609/19,A-HKUST605/16,C6009-17GInnovation and Technology Commission,Grant/Award Numbers:ITC-CNERC14SC01,ITCPD/17-9Science and Technology Plan of Shenzhen,Grant/Award Number:JCYJ20200109110608167。
文摘Kasha’s rule,which states that all exciton emissions occur from the lowest excited state and are independent of excitation energy,makes high-energy excitons difficult to use and severely hinders the widespread applications of organic photoluminescent materials in the real world.For decades,scientists have tried to break this rule to unleash the power of high-energy excitons,but only minimal progress has been achieved,with no rational guiding principles provided,and few applications developed.So far,breaking Kasha’s rule has remained a purely academic concept.In this paper,we introduce a design principle for a purely organic anti-Kasha system and synthesise a series of compounds based on the design rule.As predicted,these compounds all display evident S_(2) emissions in dilute solutions.In addition,we introduce a highly accurate(over 90%)convolutional neural network as an assistant for the classification of cells using anti-Kasha luminogens,thereby providing a new application direction for anti-Kasha systems.
