Fengfei Liu scite author profile

Fengfei Liu

5Publications

66Citation Statements Received

200Citation Statements Given

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Affiliations

Tumor Hospital of Guangxi Medical University, Lanzhou University of Technology

Publications

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Structural origin of hardness decrease in irradiated sodium borosilicate glass

Wang

Peng

Sun

et al. 2017

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Mechanical properties such as hardness and modulus of sodium borosilicate (NBS) glasses in irradiation conditions were studied extensively in recent years. With irradiation of heavy ions, a trend that the hardness of NBS glasses decreased and then stabilized with increase of dose has been reported. Variations in network structures were suggested for the decrease of hardness after irradiation. However, details of these variations in a network of glass are not clear yet. In this paper, molecular dynamics was applied to simulate the network variations in a type of NBS glass and the changes in hardness after xenon irradiation. The simulation results indicated that hardness variation decreased with fluence in an exponential law, which was consistent with experimental results. The origin of hardness decrease after irradiation might be attributed to the break of B-O links that could be derived from the (1) decrease of average coordinate number of boron, (2) decrease of Si-O-B bonds, and (3) increase of non-bridging oxygen.

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Composition effects on mechanical properties of pristine sodium borosilicate glass

Zhao

Zhang

Wang

et al. 2018

Int J of Appl Glass Sci

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Sodium borosilicate (NBS) glass is widely used in the disposal of high level nuclear waste nowadays. In order to understand the mechanism of hardness in NBS glass varies with various compositions, nanoindentation experiment and molecular dynamics simulation were carried out. Both experimental and calculated results suggested that, the hardness of glass increased with the ratio of R ([Na 2 O]/ [B 2 O 3 ] in molar percentage) and K ([SiO 2 ]/[B 2 O 3 ] in molar percentage). In the process of hardness increase, the [BO 3 ] units were transformed into [BO 4 ] units, which could lead to the polymerization increase for the glass system, and the transformation was linear to R. The hardness increase was also accompanying with the increase of silica content, which is another cause for polymerization increase. There are many possible factors that may affect the mechanical properties of pristine NBS glass, and polymerization increase should be the main reason for hardness increase, which could be resulted from the two processes above: (a) the transformation of [BO 3 ] into [BO 4 ]; (b) silica content increase. K E Y W O R D S composition effects, hardness, nanoindentation, sodium borosilicate glass

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Bottom-Up Signal Boosting with Fractal Nanostructuring and Primer Exchange Reaction for Ultrasensitive Detection of Cancerous Exosomes

et al. 2023

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Exosomes are emerging as promising biomarkers for cancer diagnosis, yet sensitive and accurate quantification of tumor-derived exosomes remains a challenge. Here, we report an ultrasensitive and specific exosome sensor (NPExo) that initially leverages hierarchical nanostructuring array and primer exchange reaction (PER) for quantitation of cancerous exosomes. This NPExo uses a high-curvature nanostructuring array (bottom) fabricated by single-step electrodeposition to enhance capturing of the target exosomes. The immuno-captured exosome thus provides abundant membrane sites to insert numerous cholesterol-DNA probes with a density much higher than that by immune pairing, which further allows PER-based DNA extension to assemble enzyme concatemers (up) for signal amplification. Such a bottom-up signal-boosting design imparts NPExo with ultrahigh sensitivity up to 75 particles/mL (i.e., <1 exosome per 10 μL) and a broad dynamic range spanning 6 orders of magnitude. Furthermore, our sensor allows monitoring subtle exosomal phenotypic transition and shows high accuracy in discrimination of liver cancer patients from healthy donors via blood samples, suggesting the great potential of NPExo as a promising tool in clinical diagnostics.

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Interfacial DNA Framework-Enhanced Background-to-Signal Transition for Ultrasensitive and Specific Micro-RNA Detection

Guo

Xiang

Lü

et al. 2022

ACS Appl. Mater. Interfaces

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Interfacial DNA self-assembly is fundamental to solid nucleic acid biosensors, whereas how to improve the signal-to-noise ratio has always been a challenge, especially in the charge-based electrochemical DNA sensors because of the large noise from the negatively charged DNA capture probes. Here, we report a DNA framework-reversed signal-gain strategy through background-to-signal transition for ultrasensitive and highly specific electrical detection of microRNAs (miRNAs) in blood. By using a model of enzyme-catalyzed deposition of conductive molecules (polyaniline) targeting to DNA, we observed the highest signal contribution per unit area by the highly charged three-dimensional (3D) tetrahedral DNA framework probe, relative to the modest of two-dimensional (2D) polyA probe and the lowest of one-dimensional (1D) single-stranded (ss)DNA probe, suggesting the positive correlation of background DNA charge with signal enhancement. Using such an effective signal-transition design, the DNA framework-based electrochemical sensor achieves ultrasensitive miRNAs detection with sensitivity up to 0.29 fM (at least 10-fold higher than that with 1D ssDNA or 2D polyA probes) and high specificity with single-base resolution. More importantly, this high-performance sensor allows for a generalized sandwich detection of tumor-associated miRNAs in the complex matrices (multiple cell lysates and blood serum) and further distinguishes the tumor patients (e.g., breast, lung, and liver cancer) from the normal individuals. These advantages signify the promise of this miRNA sensor as a versatile tool in precision diagnosis.

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Primer exchange reaction-amplified protein-nucleic acid interactions for ultrasensitive and specific microRNA detection

Fang

Liu

Fang

et al. 2023

Biosensors and Bioelectronics

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Fengfei Liu

Structural origin of hardness decrease in irradiated sodium borosilicate glass

Composition effects on mechanical properties of pristine sodium borosilicate glass

Bottom-Up Signal Boosting with Fractal Nanostructuring and Primer Exchange Reaction for Ultrasensitive Detection of Cancerous Exosomes

Interfacial DNA Framework-Enhanced Background-to-Signal Transition for Ultrasensitive and Specific Micro-RNA Detection

Primer exchange reaction-amplified protein-nucleic acid interactions for ultrasensitive and specific microRNA detection

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