Photodynamic therapy (PDT) is undoubtedly a cutting-edge strategy for precise tumor therapy because of its unprecedented superiorities, such as negligible long-lasting adverse effects, high spatial and temporal select...Photodynamic therapy (PDT) is undoubtedly a cutting-edge strategy for precise tumor therapy because of its unprecedented superiorities, such as negligible long-lasting adverse effects, high spatial and temporal selectivity, and inappreciable drug resistance. While the operation wavelengths of the commonly used photosensitizers (PSs) are located in visible or first near-infrared (NIR-I, 650–900 nm) region. The lights in these regions possess relatively low penetration depth, which makes PDT unsuitable for deep-tissue treatment. Near-infrared-II (NIR-II, 1000–1700 nm) light with high tissue penetration ability can be employed as excitation source for PDT, which provides a promising alternative for precision therapy of deep-seated tumors. However, designing NIR-II activated PSs is in its infancy, and still faces many challenges, such as severe nonradiative relaxation and difficulties in adjusting energy levels. This paper reviews the therapeutic mechanisms of PDT and recent strategies for designing NIR-II activated inorganic PSs. The inorganic NIR-II PSs are classified based on their functions (such as type II PSs, type I PSs, and PSs with specific properties), and their applications for effective and precision deep-tissue treatment are summarized comprehensively. Furthermore, the major issues of applying these PSs in clinical practices are also discussed.展开更多
Photothermal therapy(PTT)using near-infrared(NIR)light for tumor treatment has triggered extensive attentions because of its advantages of noninvasion and convenience.The current research on PTT usually uses lasers in...Photothermal therapy(PTT)using near-infrared(NIR)light for tumor treatment has triggered extensive attentions because of its advantages of noninvasion and convenience.The current research on PTT usually uses lasers in the first NIR window(NIR-I;700–900 nm)as irradiation source.However,the second NIR window(NIR-II;1000–1700 nm)especially NIRIIa window(1300–1400 nm)is considered much more promising in diagnosis and treatment as its superiority in penetration depth and maximum permissible exposure over NIR-I window.Hereby,we propose the use of laser excitation at 1275 nm,which is approved by Food and Drug Administration for physical therapy,as an attractive technique for PTT to balance of tissue absorption and scattering with water absorption.Specifically,CuS-PEG nanoparticles with similar absorption values at 1275 and 808 nm,a conventional NIR-I window for PTT,were synthesized as PTT agents and a comparison platform,to explore the potential of 1275 and 808 nm lasers for PTT,especially in deep-tissue settings.The results showed that 1275 nm laser was practicable in PTT.It exhibited much more desirable outcomes in cell ablation in vitro and deep-tissue antitumor capabilities in vivo compared to that of 808 nm laser.NIR-IIa laser illumination is superior to NIR-I laser for deep-tissue PTT,and shows high potential to improve the PTT outcome.展开更多
Rodents are popular biological models for physiological and behavioral research in neuroscience and rats are better models than mice due to their higher genome similarity to human and more accessible surgical procedur...Rodents are popular biological models for physiological and behavioral research in neuroscience and rats are better models than mice due to their higher genome similarity to human and more accessible surgical procedures.However,rat brain is larger than mice brain and it needs powerful imaging tools to implement better penetration against the scattering of the thicker brain tissue.Three-photon fluorescence microscopy(3PFM)combined with near-infrared(NIR)excitation has great potentials for brain circuits imaging beause of its abilities of anti scattering,deep-tissue imaging,and high signal-to-noise ratio(SNR).In this work,a type of AIE lumninogen with red fuorescence was synthesized and encapsulated with Pluronic F-127 to make up form nano-particles(NPs).Bright DCDPP-2TPA NPs were employed for in trino three-photon fuorescent laser scanning microscopy of blood vessels in rats brain under 1550 nm femtosecond laser exci-tation.A fine three-dimensional(3D)reconstruction up to the deepness of 600 pm was achieved and the blood flow velocity of a selected vessel was measured in vrito as well.Our 3PFM deep brain imaging method simultaneously recorded the morphology and function of the brain blood vessels in vivo in the rat model.Using this angiography combined with the arsenal of rodent's brain disease,models can accelerate the neuroscience research and clinical diagnosis of brain disease in the future.展开更多
Lipid droplets(LDs)participate in many physiological processes,the abnormality of which will cause chronic diseases and pathologies such as diabetes and obesity.It is crucial to monitor the distribution of LDs at high...Lipid droplets(LDs)participate in many physiological processes,the abnormality of which will cause chronic diseases and pathologies such as diabetes and obesity.It is crucial to monitor the distribution of LDs at high spatial resolution and large depth.Herein,we carried three-photon imaging of LDs in fat liver.Owing to the large three-photon absorption cross-section of the luminogen named NAP-CF_(3)(1:67×10^(-79) cm^(6) s^(2)),three-photon fluorescence fat liver imaging reached the largest depth of 80μm.Fat liver diagnosis was successfully carried out with excellent performance,providing great potential for LDs-associated pathologies research.展开更多
Comprehensive Summary Deep-tissue physiological signals are critical for accurate disease diagnosis.Current clinical equipment,however,often falls short of enabling continuous,long-term monitoring.Wearable and implant...Comprehensive Summary Deep-tissue physiological signals are critical for accurate disease diagnosis.Current clinical equipment,however,often falls short of enabling continuous,long-term monitoring.Wearable and implantable flexible electronics offer a promising avenue for addressing this limitation,allowing in vivo signal collection and paving the way for early diagnosis and personalized treatment.A major challenge lies in ensuring that these devices seamlessly integrate with the diverse physiological microenvironments throughout the human body.展开更多
基金supported by the National Natural Science Foundation of China(Nos.22175098,52373142)the Jiangsu Planned Projects for Postdoctoral Research Funds(No.2021K114B)the Huali Talents Program of Nanjing University of Posts and Telecommunications,the Postgraduate Research&Practice Innovation Program of Jiangsu Province(No.KYCX23_0984)。
文摘Photodynamic therapy (PDT) is undoubtedly a cutting-edge strategy for precise tumor therapy because of its unprecedented superiorities, such as negligible long-lasting adverse effects, high spatial and temporal selectivity, and inappreciable drug resistance. While the operation wavelengths of the commonly used photosensitizers (PSs) are located in visible or first near-infrared (NIR-I, 650–900 nm) region. The lights in these regions possess relatively low penetration depth, which makes PDT unsuitable for deep-tissue treatment. Near-infrared-II (NIR-II, 1000–1700 nm) light with high tissue penetration ability can be employed as excitation source for PDT, which provides a promising alternative for precision therapy of deep-seated tumors. However, designing NIR-II activated PSs is in its infancy, and still faces many challenges, such as severe nonradiative relaxation and difficulties in adjusting energy levels. This paper reviews the therapeutic mechanisms of PDT and recent strategies for designing NIR-II activated inorganic PSs. The inorganic NIR-II PSs are classified based on their functions (such as type II PSs, type I PSs, and PSs with specific properties), and their applications for effective and precision deep-tissue treatment are summarized comprehensively. Furthermore, the major issues of applying these PSs in clinical practices are also discussed.
基金supported,in part,by the Natural Science Foundation of China (Nos.81402043 and 81201141)the Clinical Capability Construction Project for Liaoning Provincial Hospitals (LNCCC-D50-2015+1 种基金LNCCC-C09-2015)the China postdoctoral science foundation Grant (2016T90233)
文摘Photothermal therapy(PTT)using near-infrared(NIR)light for tumor treatment has triggered extensive attentions because of its advantages of noninvasion and convenience.The current research on PTT usually uses lasers in the first NIR window(NIR-I;700–900 nm)as irradiation source.However,the second NIR window(NIR-II;1000–1700 nm)especially NIRIIa window(1300–1400 nm)is considered much more promising in diagnosis and treatment as its superiority in penetration depth and maximum permissible exposure over NIR-I window.Hereby,we propose the use of laser excitation at 1275 nm,which is approved by Food and Drug Administration for physical therapy,as an attractive technique for PTT to balance of tissue absorption and scattering with water absorption.Specifically,CuS-PEG nanoparticles with similar absorption values at 1275 and 808 nm,a conventional NIR-I window for PTT,were synthesized as PTT agents and a comparison platform,to explore the potential of 1275 and 808 nm lasers for PTT,especially in deep-tissue settings.The results showed that 1275 nm laser was practicable in PTT.It exhibited much more desirable outcomes in cell ablation in vitro and deep-tissue antitumor capabilities in vivo compared to that of 808 nm laser.NIR-IIa laser illumination is superior to NIR-I laser for deep-tissue PTT,and shows high potential to improve the PTT outcome.
基金supported by the Zhejiang Provincial Natural Science Foundation of China(LR17F050001 and LY17C090005)the National Natural Science Foundation of China(61735016 and 91632105)National Basic Research Program of China(973 Program,2013CB834701 and 2013CB834704).
文摘Rodents are popular biological models for physiological and behavioral research in neuroscience and rats are better models than mice due to their higher genome similarity to human and more accessible surgical procedures.However,rat brain is larger than mice brain and it needs powerful imaging tools to implement better penetration against the scattering of the thicker brain tissue.Three-photon fluorescence microscopy(3PFM)combined with near-infrared(NIR)excitation has great potentials for brain circuits imaging beause of its abilities of anti scattering,deep-tissue imaging,and high signal-to-noise ratio(SNR).In this work,a type of AIE lumninogen with red fuorescence was synthesized and encapsulated with Pluronic F-127 to make up form nano-particles(NPs).Bright DCDPP-2TPA NPs were employed for in trino three-photon fuorescent laser scanning microscopy of blood vessels in rats brain under 1550 nm femtosecond laser exci-tation.A fine three-dimensional(3D)reconstruction up to the deepness of 600 pm was achieved and the blood flow velocity of a selected vessel was measured in vrito as well.Our 3PFM deep brain imaging method simultaneously recorded the morphology and function of the brain blood vessels in vivo in the rat model.Using this angiography combined with the arsenal of rodent's brain disease,models can accelerate the neuroscience research and clinical diagnosis of brain disease in the future.
基金supported by National Natural Science Foundation of China (61975172,82001874,62105184)the Guangdong Basic and Applied Basic Research Foundation (2020A1515110578).
文摘Lipid droplets(LDs)participate in many physiological processes,the abnormality of which will cause chronic diseases and pathologies such as diabetes and obesity.It is crucial to monitor the distribution of LDs at high spatial resolution and large depth.Herein,we carried three-photon imaging of LDs in fat liver.Owing to the large three-photon absorption cross-section of the luminogen named NAP-CF_(3)(1:67×10^(-79) cm^(6) s^(2)),three-photon fluorescence fat liver imaging reached the largest depth of 80μm.Fat liver diagnosis was successfully carried out with excellent performance,providing great potential for LDs-associated pathologies research.
基金supported by the National Natural Science Foundation of China(81971701).
文摘Comprehensive Summary Deep-tissue physiological signals are critical for accurate disease diagnosis.Current clinical equipment,however,often falls short of enabling continuous,long-term monitoring.Wearable and implantable flexible electronics offer a promising avenue for addressing this limitation,allowing in vivo signal collection and paving the way for early diagnosis and personalized treatment.A major challenge lies in ensuring that these devices seamlessly integrate with the diverse physiological microenvironments throughout the human body.
