Aggregation-induced emission(AIE)is a photophysical phenomenon that a certain group of luminescent materials that become highly luminous when aggregated in a bad solvent or solid state.This year is the 20th anniversar...Aggregation-induced emission(AIE)is a photophysical phenomenon that a certain group of luminescent materials that become highly luminous when aggregated in a bad solvent or solid state.This year is the 20th anniversary since the AIE concept firstly proposed in 2001.Many advanced applications were gradually being explored,covering optics,electronics,energy,and bioscience and so on.At present,bibliometrics can enlighten the researchers with comprehensive sights of the achievements and trends of a specific field,which is critical for academic investigations.Herein,we presented a general bibliometric overview of AIE covering 20 years of evolution.With the assistance of Web of Science Core Collection database and several bibliometric software tools,the annual publication and citation,most influential countries/regions,most contributing authors,journals and institutions,second near-infrared(NIR-Ⅱ)related hotspots,as well as the forecast of frontiers were demonstrated and systematically analyzed.This study summarizes the current research status in AIE research field and provides a reference for future research directions.展开更多
Colorectal cancer(CRC) is one of the major causes of cancer-related mortality worldwide. Most near-infrared(NIR) agents used in clinical CRC treatment are at NIR-I(700–900 nm) window, which has limitations on deep ti...Colorectal cancer(CRC) is one of the major causes of cancer-related mortality worldwide. Most near-infrared(NIR) agents used in clinical CRC treatment are at NIR-I(700–900 nm) window, which has limitations on deep tissue, and fluorescent probes in the second NIR(1,000–1,700 nm) allow high-resolution bioimaging with deep tissue penetration. However, existing NIR-II fluorophores used in clinical are still rare. Herein, based on shielding-donor-acceptor-donor-shielding(S-D-A-D-S) scaffold, we developed an organic small-molecule fluorophore IR-BTGP with NIR-II emission for imaging-guided photothermal therapy(PTT) in CRC mice model. Amphiphilic IR-BTGP can be self-assembled into spherical nano-micelles, which presents reliable water solubility and photothermal conversion efficiency(30.2%). In vitro experiments indicate that cancer cells treated with IRBTGP were significantly killed upon 808 nm light irradiation. Furthermore, in vivo NIR-II fluorescence imaging confirms that IR-BTGP accumulates in the tumor region. Remarkably, a significant tumor inhibition rate(78.5%) was observed in tumorbearing mice when treated with IR-BTGP plus 808 nm irradiation. Therefore, this work shows that IR-BTGP holds great promise as an NIR-II fluorescence imaging-guided PTT platform for CRC in the future.展开更多
It is challenging to develop molecular fluorophores in the second near-infrared(NIR-Ⅱ)window with long wavelength emission and high brightness,which can improve the performance of biological imaging.Herein,we report ...It is challenging to develop molecular fluorophores in the second near-infrared(NIR-Ⅱ)window with long wavelength emission and high brightness,which can improve the performance of biological imaging.Herein,we report a molecular engineering approach to afford NIR-Ⅱ fluorophores with these merits based on fused-ring acceptor(FRA)molecules.Dioctyl 3,4-propylenedioxy thiophene(PDOT-C8)is utilized as the bridging donor to replace 3-ethylhexyloxy thiophene(3-EHOT),leading to more than 20 times enhancement of brightness.The nanofluorophores(NFs)based on the optimized CPTIC-4F molecule exhibit an emission peak of 1,110 nm with a fluorescence quantum yield(QY)of 0.39%(QY of IR-26 is 0.050%in dichloroethane as reference)and peak absorption coefficient of 14.5 x 10^4 M^-1·cm^-1 in aqueous solutions,which are significantly higher than those of 3-EHOT based COTIC-4F NFs.It is found that PDOT-C8 can weaken intermolecular aggregation,enhance protection of molecular backbone from water,and decrease backbone distortion,beneficial for the high brightness.Compared with indocyanine green with same injection dose,CPTIC-4F NFs show 10 times higher signal-to-background ratio for whole body vessels imaging at 1,300 nm long pass filters.展开更多
Ovarian cancer is a global problem,and is typically diagnosed in the middle or late stages,with a mysterious abdominal mass or atypical abdominal metastases due to the lack of specific initial diagnostic methods.Dual-...Ovarian cancer is a global problem,and is typically diagnosed in the middle or late stages,with a mysterious abdominal mass or atypical abdominal metastases due to the lack of specific initial diagnostic methods.Dual-modal near-infrared Ⅱ(NIR-Ⅱ,1,000–1,700 nm)fluorescence/photoacoustic imaging has great potential in early ovarian cancer diagnosis and image-guided surgery due to its high sensitivity and deep penetration.Herein,we report a novel organic NIR-Ⅱ dye(H10)with excellent aggregation-induced-emission(AIE)characteristics(I/I0>1.6)utilizing a selenadiazolo-[3,4-f]benzo[c][1,2,5]thiadiazole(ST)-based building block.Then,water-soluble and biocompatible H10@follicle-stimulating hormone(H10@FSH)dots with superior optical/photoacoustic properties and a tenfold increase in ovarian-specific targeting ability were synthesized.Finally,for the first time,in vivo dual-mode NIR-Ⅱ fluorescent/photoacoustic(PA)imaging and image-guided surgery of patient-derived tumor xenograft(PDTX)and micro-metastatic abdominal ovarian cancer lesions were investigated.This novel strategy will establish a new method for early detection of ovarian cancer and significantly improve the prognosis of ovarian cancer patients.展开更多
近红外二区(900~1 880 nm,the Second Near-Infrared Region,NIR-Ⅱ)荧光宽场显微成像技术是当前大深度活体成像的一大研究热点,在基础研究和临床应用方面都拥有巨大的潜力。对比可见光(360~760 nm)和近红外一区(760~900 nm,the First N...近红外二区(900~1 880 nm,the Second Near-Infrared Region,NIR-Ⅱ)荧光宽场显微成像技术是当前大深度活体成像的一大研究热点,在基础研究和临床应用方面都拥有巨大的潜力。对比可见光(360~760 nm)和近红外一区(760~900 nm,the First Near-Infrared Region,NIR-Ⅰ)的成像,NIR-Ⅱ荧光宽场显微成像技术在活体层面具有更高的清晰度和更深的组织穿透。在NIR-Ⅱ宏观成像基础上,对组织微结构清晰成像的需求迫使成像试剂持续发展,成像系统不断精进。目前,NIR-Ⅱ荧光宽场显微成像技术在脉管显微造影、肿瘤精确分析、炎症准确追踪等生物应用上都获得一系列突破,相关研究对象包含啮齿类动物(如小鼠,大鼠)及灵长类动物(如狨猴,猕猴)等。将来随着仪器商业化和国产化突破,成像试剂安全性逐步提高,NIR-Ⅱ荧光宽场显微成像应用价值将不断攀升。本文从NIR-Ⅱ荧光成像的机制及优势展开讨论,综述NIR-Ⅱ荧光宽场显微成像的系统特点和演进历史,以及其在不同生物模型上活体成像方面的最新探索和前景展望,以期推动NIR-Ⅱ荧光宽场显微成像技术进一步普及。展开更多
基金National Key Research and Development Project,Grant/Award Number:2017YFC0110802Zhejiang province Key Research and Development Project,Grant/Award Number:2020C01059+3 种基金National Natural Science Foundation of China,Grant/Award Numbers:81874059,82102105,61975172,61735016Zhejiang Engineering Research Center of Cognitive Healthcare,Grant/Award Number:2017E10011National Key Scientific Instrument and Equipment Development Project,Grant/Award Number:81827804Fundamental Research Funds for the Central Universities,Grant/Award Number:2020-KYY-511108-0007。
文摘Aggregation-induced emission(AIE)is a photophysical phenomenon that a certain group of luminescent materials that become highly luminous when aggregated in a bad solvent or solid state.This year is the 20th anniversary since the AIE concept firstly proposed in 2001.Many advanced applications were gradually being explored,covering optics,electronics,energy,and bioscience and so on.At present,bibliometrics can enlighten the researchers with comprehensive sights of the achievements and trends of a specific field,which is critical for academic investigations.Herein,we presented a general bibliometric overview of AIE covering 20 years of evolution.With the assistance of Web of Science Core Collection database and several bibliometric software tools,the annual publication and citation,most influential countries/regions,most contributing authors,journals and institutions,second near-infrared(NIR-Ⅱ)related hotspots,as well as the forecast of frontiers were demonstrated and systematically analyzed.This study summarizes the current research status in AIE research field and provides a reference for future research directions.
基金supported by the National Natural Science Foundation of China (22374065)the Science and Technology Innovation Program of Hunan Province “Huxiang Young Talents Plan”(2021RC3106)the Key Research and Development Program of Hunan Province,China (2022SK2053)。
文摘Colorectal cancer(CRC) is one of the major causes of cancer-related mortality worldwide. Most near-infrared(NIR) agents used in clinical CRC treatment are at NIR-I(700–900 nm) window, which has limitations on deep tissue, and fluorescent probes in the second NIR(1,000–1,700 nm) allow high-resolution bioimaging with deep tissue penetration. However, existing NIR-II fluorophores used in clinical are still rare. Herein, based on shielding-donor-acceptor-donor-shielding(S-D-A-D-S) scaffold, we developed an organic small-molecule fluorophore IR-BTGP with NIR-II emission for imaging-guided photothermal therapy(PTT) in CRC mice model. Amphiphilic IR-BTGP can be self-assembled into spherical nano-micelles, which presents reliable water solubility and photothermal conversion efficiency(30.2%). In vitro experiments indicate that cancer cells treated with IRBTGP were significantly killed upon 808 nm light irradiation. Furthermore, in vivo NIR-II fluorescence imaging confirms that IR-BTGP accumulates in the tumor region. Remarkably, a significant tumor inhibition rate(78.5%) was observed in tumorbearing mice when treated with IR-BTGP plus 808 nm irradiation. Therefore, this work shows that IR-BTGP holds great promise as an NIR-II fluorescence imaging-guided PTT platform for CRC in the future.
基金Y.L.acknowledges financial supports from the National Natural Science Foundation of China(No.21772084)Fundamental Research Layout of Shenzhen(No.JCY20180504165657443)+2 种基金H.S.thanks the National Natural Science Foundation of China(Nos.11727810,61720106009 and 21603074)the Science and Technology Commission of Shanghai Municipality(No.19JC1412200)for funding support and the ECNU Multifunctional Platform for Innovation(001)and HPC Research Computing Team for providing computational and storage resourcesX.Z thanks the funding supports from the National Natural Science Foundation of China(Nos.91859101,81971744,and U1932107).
文摘It is challenging to develop molecular fluorophores in the second near-infrared(NIR-Ⅱ)window with long wavelength emission and high brightness,which can improve the performance of biological imaging.Herein,we report a molecular engineering approach to afford NIR-Ⅱ fluorophores with these merits based on fused-ring acceptor(FRA)molecules.Dioctyl 3,4-propylenedioxy thiophene(PDOT-C8)is utilized as the bridging donor to replace 3-ethylhexyloxy thiophene(3-EHOT),leading to more than 20 times enhancement of brightness.The nanofluorophores(NFs)based on the optimized CPTIC-4F molecule exhibit an emission peak of 1,110 nm with a fluorescence quantum yield(QY)of 0.39%(QY of IR-26 is 0.050%in dichloroethane as reference)and peak absorption coefficient of 14.5 x 10^4 M^-1·cm^-1 in aqueous solutions,which are significantly higher than those of 3-EHOT based COTIC-4F NFs.It is found that PDOT-C8 can weaken intermolecular aggregation,enhance protection of molecular backbone from water,and decrease backbone distortion,beneficial for the high brightness.Compared with indocyanine green with same injection dose,CPTIC-4F NFs show 10 times higher signal-to-background ratio for whole body vessels imaging at 1,300 nm long pass filters.
基金supported by the National Natural Science Foundation of China (21971185 and 52173177)the Natural Science Foundation of Jiangsu Province (BK20230010 and BK20221362)+4 种基金the Science and Technology Support Program of Jiangsu Province (TJ-2022-002)funded by the Collaborative Innovation Center of Suzhou Nano Science&Technologythe 111 Projectthe Joint International Research Laboratory of Carbon-Based Functional Materials and DevicesSoochow University Tang Scholar。
基金supported by the National Key Research and development Program of China(Nos.2020YFA0908800 and 2015DFA30440)the National Natural Science Foundation of China(Nos.82111530209,81773674,81573383,91959103,and 61971447)+4 种基金Hubei Province Scientific and Technical Innovation Key Project(No.2020BAB058)Beijing Natural Science Foundation(No.JQ18023)Shenzhen Science and Technology Research Grant(No.JCYJ20190808152019182)the Local Development Funds of Science and Technology Department of Tibet(Nos.XZ202102YD0033C and XZ202202YD0021C)the Fundamental Research Funds for the Central Universities.
文摘Ovarian cancer is a global problem,and is typically diagnosed in the middle or late stages,with a mysterious abdominal mass or atypical abdominal metastases due to the lack of specific initial diagnostic methods.Dual-modal near-infrared Ⅱ(NIR-Ⅱ,1,000–1,700 nm)fluorescence/photoacoustic imaging has great potential in early ovarian cancer diagnosis and image-guided surgery due to its high sensitivity and deep penetration.Herein,we report a novel organic NIR-Ⅱ dye(H10)with excellent aggregation-induced-emission(AIE)characteristics(I/I0>1.6)utilizing a selenadiazolo-[3,4-f]benzo[c][1,2,5]thiadiazole(ST)-based building block.Then,water-soluble and biocompatible H10@follicle-stimulating hormone(H10@FSH)dots with superior optical/photoacoustic properties and a tenfold increase in ovarian-specific targeting ability were synthesized.Finally,for the first time,in vivo dual-mode NIR-Ⅱ fluorescent/photoacoustic(PA)imaging and image-guided surgery of patient-derived tumor xenograft(PDTX)and micro-metastatic abdominal ovarian cancer lesions were investigated.This novel strategy will establish a new method for early detection of ovarian cancer and significantly improve the prognosis of ovarian cancer patients.
