Aggregation-induced emission luminogens(AIEgens)exhibit viscosity-responsive behavior resembling those of molecular rotors;however,their response mechanisms are more complex and cannot be adequately described using si...Aggregation-induced emission luminogens(AIEgens)exhibit viscosity-responsive behavior resembling those of molecular rotors;however,their response mechanisms are more complex and cannot be adequately described using simple rotational models.AIEgens demonstrate intricate dynamics that are highly dependent on their molecular structures.In this study,we synthesized water-soluble derivatives of representative AIEgens,including tetraphenylethene(TPE),bis(N,N-dialkylamino)anthracene(BDAA),and bridged stilbene,and systematically investigated the dependence of their photophysical properties in water/glycerol mixed solvents on temperature and viscosity.To elucidate the origin of their viscosity responsiveness,quantum chemical calculations were conducted to analyze their potential energy surfaces(PESs).The results revealed that compared to typical molecular rotors,these AIEgens exhibit significantly higher sensitivity to viscosity in low-viscosity regions.Notably,for TPE and BDAA derivatives,the viscosity responsiveness was found to be governed not by the activation energy barrier(ΔE_(a))based on the PES,but rather by the viscosity-dependent constraints on molecular structural changes.Furthermore,molecules possessing multiple aromatic rings or large,flexible,rotatable moieties were found to exhibit enhanced sensitivity to viscosity due to increased frictional interactions in solutions.This study provides critical insights into the mechanistic origins of the viscosity responsiveness of AIEgens,thereby advancing the fundamental understanding of their behavior and expanding their potential application as viscositysensitive probes.展开更多
Diabetic liver injury is a widespread complication of diabetes and carries a high risk to liver function.Therefore,early diagnosis of diabetic liver injury is of great significance for providing quality of life for di...Diabetic liver injury is a widespread complication of diabetes and carries a high risk to liver function.Therefore,early diagnosis of diabetic liver injury is of great significance for providing quality of life for diabetic patients.Most of the activated dual-modal probes are usually activated by single factor stimulation,which greatly reduces the diagnostic accuracy of liver injury.Here,a novel cysteine(Cys)/homocysteine(Hcy)and viscosity-enhanced dual-modal probe DAL was developed for the first time to monitor diabetic liver injury and its repair process.In the presence of Cys/Hcy,the near-infrared fluorescence(NIRF)and photoacoustic(PA)signals of the probe DAL were activated,with further signal enhancement in high viscosity environments.This Cys/Hcy and viscosity cascade probe exhibits heightened sensitivity and enhanced anti-interference capabilities,contributing to the advancement of liver injury diagnosis accuracy.In addition,the probe DAL shows exceptional mitochondrial targeting ability,enabling sensitive monitoring of Cys/Hcy and viscosity alterations within mitochondria.Based on NIRF/PA dual-modal imaging technology,the probe was successfully used for the first time in a mouse diabetic liver injury model to evaluate the extent of liver damage and the repair process by tracking the levels of Cys/Hcy and viscosity.Therefore,the two-factor activated dual-modal probe developed in this study provides a powerful instrument for accurate diagnosis and efficacy evaluation of complications related to diabetes.展开更多
The transient vistosity response of a lubricant following the pressure charge in a EHDcontact is consideied in the line-contact isothermal elastohydrodynamic lubrication analyses. Soobtained pressure distribution and ...The transient vistosity response of a lubricant following the pressure charge in a EHDcontact is consideied in the line-contact isothermal elastohydrodynamic lubrication analyses. Soobtained pressure distribution and the oil film thickness are different from those obtained with equi-librium viscosity.展开更多
基金JSPS Research Fellowships for Young Scientistssupported in part by JST SPRING,Japan(Nos.JPMJSP2106 and JPMJSP2180,Takuya Tanaka.and Yuki Sawatari.)+1 种基金MEXT/JSPS KAKENHI grants(No.23H02036,Gen-ichi Konishi)Murata Science and Education Foundation(Gen-ichi Konishi)。
文摘Aggregation-induced emission luminogens(AIEgens)exhibit viscosity-responsive behavior resembling those of molecular rotors;however,their response mechanisms are more complex and cannot be adequately described using simple rotational models.AIEgens demonstrate intricate dynamics that are highly dependent on their molecular structures.In this study,we synthesized water-soluble derivatives of representative AIEgens,including tetraphenylethene(TPE),bis(N,N-dialkylamino)anthracene(BDAA),and bridged stilbene,and systematically investigated the dependence of their photophysical properties in water/glycerol mixed solvents on temperature and viscosity.To elucidate the origin of their viscosity responsiveness,quantum chemical calculations were conducted to analyze their potential energy surfaces(PESs).The results revealed that compared to typical molecular rotors,these AIEgens exhibit significantly higher sensitivity to viscosity in low-viscosity regions.Notably,for TPE and BDAA derivatives,the viscosity responsiveness was found to be governed not by the activation energy barrier(ΔE_(a))based on the PES,but rather by the viscosity-dependent constraints on molecular structural changes.Furthermore,molecules possessing multiple aromatic rings or large,flexible,rotatable moieties were found to exhibit enhanced sensitivity to viscosity due to increased frictional interactions in solutions.This study provides critical insights into the mechanistic origins of the viscosity responsiveness of AIEgens,thereby advancing the fundamental understanding of their behavior and expanding their potential application as viscositysensitive probes.
基金financially supported by the National Natural Science Foundation of China(Nos.21877048,22077048,and 22277014)Guangxi Natural Science Foundation(Nos.2021GXNSFDA075003,AD21220061)the Startup Fund of Guangxi University(No.A3040051003).
文摘Diabetic liver injury is a widespread complication of diabetes and carries a high risk to liver function.Therefore,early diagnosis of diabetic liver injury is of great significance for providing quality of life for diabetic patients.Most of the activated dual-modal probes are usually activated by single factor stimulation,which greatly reduces the diagnostic accuracy of liver injury.Here,a novel cysteine(Cys)/homocysteine(Hcy)and viscosity-enhanced dual-modal probe DAL was developed for the first time to monitor diabetic liver injury and its repair process.In the presence of Cys/Hcy,the near-infrared fluorescence(NIRF)and photoacoustic(PA)signals of the probe DAL were activated,with further signal enhancement in high viscosity environments.This Cys/Hcy and viscosity cascade probe exhibits heightened sensitivity and enhanced anti-interference capabilities,contributing to the advancement of liver injury diagnosis accuracy.In addition,the probe DAL shows exceptional mitochondrial targeting ability,enabling sensitive monitoring of Cys/Hcy and viscosity alterations within mitochondria.Based on NIRF/PA dual-modal imaging technology,the probe was successfully used for the first time in a mouse diabetic liver injury model to evaluate the extent of liver damage and the repair process by tracking the levels of Cys/Hcy and viscosity.Therefore,the two-factor activated dual-modal probe developed in this study provides a powerful instrument for accurate diagnosis and efficacy evaluation of complications related to diabetes.
文摘The transient vistosity response of a lubricant following the pressure charge in a EHDcontact is consideied in the line-contact isothermal elastohydrodynamic lubrication analyses. Soobtained pressure distribution and the oil film thickness are different from those obtained with equi-librium viscosity.
