Nano metal–organic framework (NMOF)-based strategies for multiplexed microRNA detection in solution and living cancer cells

Wu, Yafeng; Han, Jianyu; Xue, Peng; Xu, Rong; Kang, Yuejun

doi:10.1039/c4nr05447d

Cited by 128 publications

(79 citation statements)

References 51 publications

(53 reference statements)

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“…Now abundance variation of many miRNAs in specific tumor have been tested. Wu and his colleagues produced a miRNA sensor, which not only enabled the quantitative and highly specific detection of multiplexed miRNAs in living cancer cells, but also allowed the precise and in situ monitoring of the spatiotemporal changes of miRNA expression (Wu et al , 2015). Moreover, some miRNA expression profiles in cancer cells have been used in the diagnosis of cancer, such as miR-18a and miR-155 (Komatsu et al, 2014, Sochor et al , 2014.…”

Section: Accepted Manuscriptmentioning

confidence: 97%

MicroRNAs in tumor angiogenesis

2015

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Section: Accepted Manuscriptmentioning

confidence: 97%

MicroRNAs in tumor angiogenesis

2015

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“…19 In order to achieve high FRET efficiency, some nanomaterials, particularly 0D and 2D nanomaterials, have been fabricated as nanoquenchers for miRNA detection, including gold nanoparticles, 20 quantum dots, 21 carbon nanoparticles, 22 graphene oxide, 23 WS 2 nanosheets, 24 and metal-organic frameworks. 25 It is worth noting that few 1D nanotubes beyond carbon nanotubes 26–28 have been reported for such applications.…”

Section: Introductionmentioning

confidence: 99%

MnO₂ Nanotube-Based NanoSearchlight for Imaging of Multiple MicroRNAs in Live Cells

Ericson

Yang

et al. 2017

ACS Appl. Mater. Interfaces

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Sensitive assay and imaging of multiple low-abundance microRNAs (miRNAs) in living cells remain a grand challenge. Herein, based on polyelectrolyte induced reduction, a facile approach has been proposed to synthesize novel MnO2 nanotubes. Owing to the remarkably strong fluorescence quenching ability, low cytotoxicity and excellent colloid stability, the as-prepared MnO2 nanotubes showed great potential for simultaneous detection and imaging of multiple miRNAs in vitro and in situ in living cells for the first time. Besides, MnO2 nanotubes can be reduced to Mn2+ by intracellular acid pH or glutathione, which may serve as activatable contrast reagent for MRI. Therefore, the MnO2 nanotubes based probes, termed “NanoSearchlight”, provide a promising, multimodal imaging tool for precise and accurate diagnosis and prognosis of cancers.

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“…Some graphene-like fluorescence quenching analogs were reported for bioanalysis. Wu et al [22] presented a novel strategy by using PNA probes labeled with fluorophores; they were conjugated with nanometal-organic framework (NMOF) as a fluorescence quencher of the labeled PNA and developed for multiplexed miRNAs detection in living cancer cells. A multifunctional SnO 2 nanoprobe for target-cell-specific delivery and imaging with detection of intracellular miRNA was reported by Ju et al [23] (Fig.…”

Section: Functional Nanoprobe-based Intracellular Mirna Detectionmentioning

confidence: 99%

Intracellular and Organic miRNA In Situ Detection

Zhang

Dong

Tian

2015

SpringerBriefs in Molecular Science

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The detection methods of miRNA in intracellular or organisms fall into two broad categories: indirect detection and direct analysis. The indirect measurement of the expression levels of miRNAs in cells and tissues involves cells lysis and detection by qRT-PCR, northern blotting, or microarray hybridization. The direct analysis methods are a noninvasive manner for repetitively monitoring and obtaining real-time imaging of the intracellular miRNA by using imaging analysis or in situ hybridization (ISH). Technologies for direct detection of the temporal and spatial expression sequence of specific miRNA in cells or tissues are extremely important for elucidating miRNA biology. The progress of optical imaging techniques with multimodal reporter systems holds great promise for noninvasive and real-time imaging of molecular agent expression in living cell. Recent progress in nanotechnology and imaging detection techniques leads to multifunctional nanoprobe with specific-transfection, tracing, and regulation function in intracellular miRNA detection. ISH holds great promise for visualization of the spatial localization of RNA at the tissue, cellular, and even subcellular level.Keywords Intracellular miRNA · Organic miRNA · In situ detection · Cell imaging analysis · Functional nanoprobeThe detection of intracellular miRNA is significant in the development of gene therapy and gene medicines. The deficiency of small size and degradation of the mature miRNAs make it difficult to directly transfer the specific miRNA into the cell. A noninvasive manner for repetitively monitoring and obtaining real-time imaging of the intracellular miRNA is required for the analysis of miRNAs in practical clinic application. Efficient gene vectors, including viral [1] and nonviral categories, [2] were usually required to translocate miRNA probe through membrane barrier into the cell. Retrovirus and adenovirus vectors can be effectively transferred via the gene probes (DNA, RNA) into most cell lines. However, the

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Nano metal–organic framework (NMOF)-based strategies for multiplexed microRNA detection in solution and living cancer cells

Cited by 128 publications

References 51 publications

MicroRNAs in tumor angiogenesis

MicroRNAs in tumor angiogenesis

MnO₂ Nanotube-Based NanoSearchlight for Imaging of Multiple MicroRNAs in Live Cells

Intracellular and Organic miRNA In Situ Detection

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Nano metal–organic framework (NMOF)-based strategies for multiplexed microRNA detection in solution and living cancer cells

Cited by 128 publications

References 51 publications

MicroRNAs in tumor angiogenesis

MicroRNAs in tumor angiogenesis

MnO2 Nanotube-Based NanoSearchlight for Imaging of Multiple MicroRNAs in Live Cells

Intracellular and Organic miRNA In Situ Detection

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MnO₂ Nanotube-Based NanoSearchlight for Imaging of Multiple MicroRNAs in Live Cells