A “pursuit and interception” strategy of amplified autophagy inhibition for tumor therapy based on ultra-small Rh nanoparticles

Liang, Xiaoyang; Ji, Yanhui; Zhou, Yue; Wang, Siyu; Long, Vong Binh; Li, Nan

doi:10.1016/j.cej.2022.136379

Cited by 7 publications

(2 citation statements)

References 40 publications

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“…The protein p62 is a substrate degraded in the autolysosomes, and higher expression levels indicate inhibition of lysosomal degradation. 44 Upon combined treatments, the expression level of p62 was remarkably upregulated compared to the control groups. Collectively, the activation of complex 4 with TCO-OH followed by light irradiation can efficiently inhibit autophagosome formation and lysosomal degradation, owing to the release of the more cytotoxic complex 3a, which also acts as an efficient 1 O 2 photosensitiser.…”

Section: Resultsmentioning

confidence: 93%

Bioorthogonal dissociative rhenium(i) photosensitisers for controlled immunogenic cell death induction

Xu,

Lee,

Leung

et al. 2023

Chem. Sci.

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Section: Resultsmentioning

confidence: 93%

Bioorthogonal dissociative rhenium(i) photosensitisers for controlled immunogenic cell death induction

Xu,

Lee,

Leung

et al. 2023

Chem. Sci.

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“…These electrochemical approaches have advanced the field of nanobiotechnology through their versatility and powerful tools for constructing nano-bio-interfaces, investigating molecular dynamics, enabling label-free biosensing, and detecting specific DNA sequences. AuNPs Antibacterial Oral administration and in vivo synthesis [172] AuNPs Antibacterial Deoxyribonuclease functionalized AuNCs and effectively remove biofilms [173] Aminobenzeneboronic acid modified AuNCs Antibacterial and self-monitor Self-monitoring residual dosage [174] PolySC 4 AP/FGGC@AuNC assemblies b) Mitochondrial imaging Host-guest assembly and high quantum yield [175] Pt(IV)-ALA-Chitosan-AuNCs c) Anticancer and bioimaging Traceable nanocluster and combinatorial therapy [176] AuNCs/QGDs/MPA/PEI d) Anticancer pH-and near-infrared-responsive and combinatorial therapy [177] AgNCs/AgNPs Antibacterial and bioimaging Versatile antimicrobial [178] DNA-templated AgNCs Anticancer and bioimaging Combinatorial therapy and fluorescence tracing and chemo drug delivery capabilities [179] Peptide-protected AgNCs Antimicrobial Green synthesis [180] PtNCs Fluorescent probe Detecting and imaging HER2 e) [181] Pillararene-functionalized RhNPs Antibacterial Photothermal sterilization and efficient catalytic ability (reduce nitrophenols and azo dyes) [182] uRh-mSNO NPs f ) Anticancer Autophagy inhibition effect and peroxidase mimic and lysosome dysfunction [183] PdNPs/covalent organic framework g) Biosensor and bioimaging Multicolor imaging [184] Hyaluronate-modified Au@PtNPs Anticancer and bioimaging Transdermal delivery and photoacoustic imaging [169] Yeast microcapsule-derived Au/PtNPs Cancer immunotherapy Combinatorial therapy and chemodynamic/photothermal synergistic treatment [185] Core-shell structured Au@Pd Anticancer ROS augmentation-induced mild PTT [186] a)…”

Section: Electrochemical Bioconjugationmentioning

confidence: 99%

Nano‐bio‐interface: Unleashing the Potential of Noble Nanometals

Guo,

Wang,

Cui

et al. 2024

Small Science

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Engineered noble metal nanomaterials (NMN) possess adjustable optical, electrical, and biocompatible properties that make them excellent tools for probing the nano‐bio‐interface. Understanding their interactions with biomolecules, cells, and tissues at the nano‐bio‐interface is crucial in designing these nanomaterials for biomedical applications. This review summarizes the structure, properties, synthesis, and passivation methods of noble metal nanoparticles, as well as the construction strategy and detection technology of the nano‐bio‐interface to provide important information about their uptake, distribution, metabolism, and degradation in vivo and in vitro. The related action mechanisms include the kinetic and thermodynamic processes of the nano‐bio‐interface, the driving forces for its formation, and the chemical reactions at the nano‐bio‐interface. By exploring the action mechanism of the nano‐bio‐interface, the antibacterial properties and cytotoxicity of NMN could be better understood, and open up more extensive biological applications. Finally, the future trends of NMNs in the biological field and the challenges encountered in realizing these technologies are discussed.

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Rhodium‐Based Nanozymes: Recent Advances and Challenges

Dai

Sun

et al. 2023

The Chemical Record

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Rhodium (Rh) is a non‐toxic transition metal used as various nanomaterials with unique structures and properties. Rh‐based nanozymes can mimic the activities of natural enzymes, overcome the limitation of the application scope of natural enzymes, and interact with various biological microenvironments to play a variety of functions. Rh‐based nanozymes can be synthesized in various ways, and different modification and regulation methods can also enable users to control catalytic performance by adjusting enzyme active sites. The construction of Rh‐based nanozymes has attracted great interest in the biomedical field and impacted the industry and other areas. This paper reviews the typical synthesis and modification strategies, unique properties, applications, challenges, and prospects of Rh‐based nanozymes. Next, the unique features of Rh‐based nanozymes are emphasized, including adjustable enzyme‐like activity, stability, and biocompatibility. In addition, we discuss Rh‐based nanozymes biosensors and detection, biomedical therapy, and industrial and other applications. Finally, the future challenges and prospects of Rh‐based nanozymes are proposed.

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A “pursuit and interception” strategy of amplified autophagy inhibition for tumor therapy based on ultra-small Rh nanoparticles

Cited by 7 publications

References 40 publications

Bioorthogonal dissociative rhenium(i) photosensitisers for controlled immunogenic cell death induction

Bioorthogonal dissociative rhenium(i) photosensitisers for controlled immunogenic cell death induction

Nano‐bio‐interface: Unleashing the Potential of Noble Nanometals

Rhodium‐Based Nanozymes: Recent Advances and Challenges

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