Driving Forces for Single DNA Stretching Assessed by <i>In Situ</i> TIRFM

Han, Jing; Zhang, Ting; Zhou, Xiaochun

doi:10.1021/cbmi.3c00010

“…[11] Thus, it is desirable to control the excited state lifetime of any given fluorescent probes that could promote the development of the lifetime multiplexing imaging technique. [12] However, the rationally controlling lifetimes of specific fluorophores remains a challenge. In principle, the radiative rate (k r ) and nonradiative rate (k nr ) determined the apparent excited state lifetimes of fluorophores.…”

Section: Introductionmentioning

confidence: 99%

Chemical Control of Fluorescence Lifetime towards Multiplexing Imaging

Ma,

Luo,

Hsiung

et al. 2024

Angew Chem Int Ed

0

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Fluorescence lifetime imaging has been a powerful tool for biomedical research. Recently, fluorescence lifetime‐based multiplexing imaging has expanded imaging channels by using probes that harbor the same spectral channels and distinct excited state lifetime. While it is desirable to control the excited state lifetime of any given fluorescent probes, the rational control of fluorescence lifetimes remains a challenge. Herein, we chose boron dipyrromethene (BODIPY) as a model system and provided chemical strategies to regulate the fluorescence lifetime of its derivatives with varying spectral features. We find electronegativity of structural substituents at the 8’ and 5’ positions are important to control the lifetime for the green‐emitting and red‐emitting BODIPY scaffolds. Mechanistically, such influences are exerted via the photo‐induced electron transfer and the intramolecular charge transfer processes for the 8’ and 5’ positions of BODIPY, respectively. Based on these principles, we have generated a group of BODIPY probes that enable imaging experiments to separate multiple targets using fluorescence lifetime as a signal. In addition to BODIPY, we envision modulation of electronegativity of chemical substituents could serve as a feasible strategy to achieve rational control of fluorescence lifetime for a variety of small molecule fluorophores.

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Chemical Control of Fluorescence Lifetime towards Multiplexing Imaging

Ma,

Luo,

Hsiung

et al. 2024

Angewandte Chemie

0

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Fluorescence lifetime imaging has been a powerful tool for biomedical research. Recently, fluorescence lifetime‐based multiplexing imaging has expanded imaging channels by using probes that harbor the same spectral channels and distinct excited state lifetime. While it is desirable to control the excited state lifetime of any given fluorescent probes, the rational control of fluorescence lifetimes remains a challenge. Herein, we chose boron dipyrromethene (BODIPY) as a model system and provided chemical strategies to regulate the fluorescence lifetime of its derivatives with varying spectral features. We find electronegativity of structural substituents at the 8’ and 5’ positions are important to control the lifetime for the green‐emitting and red‐emitting BODIPY scaffolds. Mechanistically, such influences are exerted via the photo‐induced electron transfer and the intramolecular charge transfer processes for the 8’ and 5’ positions of BODIPY, respectively. Based on these principles, we have generated a group of BODIPY probes that enable imaging experiments to separate multiple targets using fluorescence lifetime as a signal. In addition to BODIPY, we envision modulation of electronegativity of chemical substituents could serve as a feasible strategy to achieve rational control of fluorescence lifetime for a variety of small molecule fluorophores.

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Chemical Modification and Delivery System of Small Interfering RNA Drugs^★

Li,

Si,

Li

et al. 2023

Acta Chimica Sinica

1

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In the past decade, nucleic acid therapeutics have experienced rapid development, with RNA interference (RNAi) based technology emerging as a versatile tool widely used in the treatment of various diseases. Small interfering RNA (siR-NA), as a sequence-specific gene silencing method, has provided an effective and specific means for studying gene function and developing new therapeutic strategies. Consequently, there has been significant interest in utilizing siRNA as a method to target specific gene functions in therapy. However, in order to make RNAi technology valuable and effective, it is crucial to chemically modify siRNA and develop efficient siRNA delivery strategies. These measures aim to improve the stability and cellular uptake capability of siRNA, enhance sequence specificity, and reduce non-specific gene silencing and biotoxicity. This review provides a concise introduction to the chemical modifications of siRNA aimed at enhancing its resistance to nucleases and stability. Additionally, the development of siRNA delivery systems, including lipid-based and polymer-based carrier systems, represents a significant research direction. These systems aim to improve the pharmacokinetics of siRNA, enhance intracellular delivery, and achieve tumor targeting. Finally, this review summarizes and discusses the technological bottlenecks and future trends in siRNA drug delivery, providing guidance for the further application of siRNA as a therapeutic strategy.

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Driving Forces for Single DNA Stretching Assessed by In Situ TIRFM

Cited by 3 publications

References 28 publications

Chemical Control of Fluorescence Lifetime towards Multiplexing Imaging

Chemical Control of Fluorescence Lifetime towards Multiplexing Imaging

Chemical Control of Fluorescence Lifetime towards Multiplexing Imaging

Chemical Modification and Delivery System of Small Interfering RNA Drugs^★

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Driving Forces for Single DNA Stretching Assessed by In Situ TIRFM

Cited by 3 publications

References 28 publications

Chemical Control of Fluorescence Lifetime towards Multiplexing Imaging

Chemical Control of Fluorescence Lifetime towards Multiplexing Imaging

Chemical Control of Fluorescence Lifetime towards Multiplexing Imaging

Chemical Modification and Delivery System of Small Interfering RNA Drugs★

Contact Info

Product

Resources

About

Chemical Modification and Delivery System of Small Interfering RNA Drugs^★