Yanlan Liu scite author profile

Chemodynamic therapy (CDT) has demonstrated new possibilities for selective and logical cancer intervention by specific manipulation of dysregulated tumorous free radical homeostasis. Current CDT methods largely rely on conversion of endogenous hydrogen peroxide (H2O2) into highly toxic hydroxyl radicals via classical Fenton or Haber–Weiss chemistry. However, their anticancer efficacies are greatly limited by the requirement of strong acidity for efficient chemical reactions, insufficient tumorous H2O2, and upregulated antioxidant defense to counteract free radical-caused oxidative damage. Here, we present a new concept whereby bioorthogonal chemistry and prodrug are combined to create a new type of aptamer drug conjugate (ApDC): aptamer-prodrug conjugate (ApPdC) micelle for improved and cancer-targeted CDT. The hydrophobic prodrug bases can not only promote self-assembly of aptamers but also act as free radical generators via bioorthogonal chemistry. In depth mechanistic studies reveal that, unlike traditional CDT systems, ApPdC micelles enable in situ activation and self-cycling generation of toxic C-centered free radicals in cancer cells through cascading bioorthogonal reactions, with no dependence on either H2O2 or pH, yet concurrently with diminished cancerous antioxidation by GSH depletion for a synergistic CDT effect. We expect this work to provide new insights into the design of targeted cancer therapies and studies of free radical-related molecular mechanisms.

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Adsorptive removal of fluoride from aqueous solutions using Al-humic acid-La aerogel composites

Liu

Qin

Wang

et al. 2016

Chemical Engineering Journal

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Dual-Parameter Recognition-Directed Design of the Activatable Fluorescence Probe for Precise Imaging of Cellular Senescence

Wang

Luo

et al. 2023

Anal. Chem.

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Specific imaging of cellular senescence emerges as a promising strategy for early diagnosis and treatment of various age-related diseases. The currently available imaging probes are routinely designed by targeting a single senescence-related marker. However, the inherently high heterogeneity of senescence makes them inaccessible to achieve specific and accurate detection of broad-spectrum cellular senescence. Here, we report the design of a dual-parameter recognition fluorescent probe for precise imaging of cellular senescence. This probe remains silent in non-senescent cells, yet produces bright fluorescence after sequential responses to two senescence-associated markers, namely, SA-β-gal and MAO-A. In-depth studies reveal that this probe allows for high-contrast imaging of senescence, independent of the cell source or stress type. More impressively, such dual-parameter recognition design further allows it to distinguish senescence-associated SA-β-gal/MAO-A from cancer-related β-gal/MAO-A, compared to commercial or previous single-marker detection probes. This study offers a valuable molecular tool for imaging cellular senescence, which is expected to significantly expand the basic studies on senescence and facilitate advances of senescence-related disease theranostics.

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An aptamer-based, fluorescent and radionuclide dual-modality probe

Zhang

Liu

et al. 2020

Biochimie

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Engineering Multifunctional RNAi Nanomedicine To Concurrently Target Cancer Hallmarks for Combinatorial Therapy

Liu

Tong

et al. 2018

Angewandte Chemie

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Cancer hallmarks allowt he complexity and heterogeneity of tumor biology to be better understood, leading to the discovery of various promising targets for cancer therapy. An amorphous iron oxide nanoparticle (NP)-based RNAi strategy is developed to co-target two cancer hallmarks.T he NP technology can modulate the glycolysis pathway by silencing MCT4 to induce tumor cell acidosis,a nd concurrently exacerbate oxidative stress in tumor cells via the Fenton-like reaction. This strategy has the following features for systemic siRNAd elivery:1 )siRNAe ncapsulation within NPs for improving systemic stability;2 )effective endosomal escape through osmotic pressure and/or endosomal membrane oxidation;3 )small sizef or enhancing tumor tissue penetration; and 4) triple functions (RNAi, Fenton-like reaction, and MRI) for combinatorial therapya nd in vivo tracking.Scheme 1. Illustration of A) the formulation and B) multiple functions of AIO RNAi NPs.

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Yanlan Liu

Molecular Self-Assembly of Bioorthogonal Aptamer-Prodrug Conjugate Micelles for Hydrogen Peroxide and pH-Independent Cancer Chemodynamic Therapy

Adsorptive removal of fluoride from aqueous solutions using Al-humic acid-La aerogel composites

Dual-Parameter Recognition-Directed Design of the Activatable Fluorescence Probe for Precise Imaging of Cellular Senescence

An aptamer-based, fluorescent and radionuclide dual-modality probe

Engineering Multifunctional RNAi Nanomedicine To Concurrently Target Cancer Hallmarks for Combinatorial Therapy

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