Your search keyword '"Lu, Yanxu"' showing total 5 results

1. A Clean, Rapid, and Controllable Approach for Establishing Bioactive Surfaces on Zirconia Implants.

Author

Chen, Chengxin, Cheng, Qi, Han, Yu, Wang, Ran, Kong, Dejian, Chen, Xiaojing, Zhu, Yuanjing, Lu, Yanxu, and Zhou, Hongbo

Subjects

HYDROXYAPATITE, ZIRCONIUM oxide, FEMTOSECOND lasers, SURFACE preparation, CRYSTAL surfaces, SOLID-state lasers, FLEXURAL strength

Abstract

Zirconia implants have great application prospects due to their favorable biocompatibility and esthetic properties. However, the percentage of osseointegration of zirconia implants is lower than that of titanium implants. This study, structures bioactive surfaces on zirconia using a femtosecond laser combined with hydroxyapatite (HA) crystals and evaluates the surface morphology, functional groups, crystal phase, mechanical performance, and cell response. The results revealed that calcium phosphate deposition coincided with the establishment of micro‐grooves on the zirconia surface. The crystal composition and flexural strength of zirconia showed no significant changes after the surface treatment. Furthermore, the modified surface promoted cell adhesion and proliferation through adjustments in cell morphology. The findings suggest that the combination of femtosecond laser and HA crystals offers a clean, rapid, and controllable approach to preparing bioactive surfaces for zirconia implants. [ABSTRACT FROM AUTHOR]

Published

2024

2. Identifying potential anti‐metastasis drugs for prostate cancer through integrative bioinformatics analysis and compound library screening.

Author

Li, Zhi Wei, Yu, Jiang Fan, Han, Feng, Peng, Jingxuan, Lu, Yanxu, and Ding, Ke

Abstract

Background: Metastasis poses the greatest threat to the lives of individuals with prostate cancer. Therefore, it is imperative to identify the underlying mechanism driving metastasis. Doing so would facilitate the detection of new diagnostic biomarkers and the advancement of treatment options for patients. Methods: Metastasis‐related modules were identified through weighted gene co‐expression network analysis based on microarray GSE6919. Hub genes were confirmed by quantitative real‐time PCR across different prostate cell lines and clinic samples. Pivotal genes were determined through integration of RNA and transcription factor‐target associated interactions. To predict drugs with potential to suppress tumor metastasis, we applied molecular networks using the DrugBank database. Drug repositioning analysis and confirmation of drug screen were conducted using the compound library. Confirmation of selective cytotoxicity of cupric oxide was carried out via invasion, transwell and apoptosis assays. Results: We identified five metastasis‐related modules. Of these modules, two were identified to represent core dysfunction modules in which five hub genes were determined for each module. Five of these 10 genes correlating with prostate cancer progression. Furthermore, our analysis revealed that there are 36 drugs with the potential to be active against tumor metastasis. Finally, we identified four compounds that have not previously been reported to have any association with cancer therapy. Of these, cupric oxide was determined to have the best chemotherapeutic potential in treating prostate cancer metastasis. Conclusions: By combining bioinformatics methods with compound library screening, this study proposes a valuable approach to drug discovery. Cupric oxide showed the potential in the treatment of prostate cancer metastasis and deserves further study. [ABSTRACT FROM AUTHOR]

Published

2023

3. Spheres Multiple Physical Network‐Based Triboelectric Materials for Self‐Powered Contactless Sensing.

Author

Zhang, Wanglin, Lu, Yanxu, Liu, Tao, Zhao, Jiamin, Liu, Yanhua, Fu, Qiu, Mo, Jilong, Cai, Chenchen, and Nie, Shuangxi

Published

2022

4. Enhancement of Triboelectric Charge Density by Chemical Functionalization.

Author

Liu, Yanhua, Mo, Jilong, Fu, Qiu, Lu, Yanxu, Zhang, Ni, Wang, Shuangfei, and Nie, Shuangxi

Subjects

ELECTRONIC equipment, TRIBOELECTRICITY, SURFACE charges, FRICTION materials, ARTIFICIAL implants, DOPING agents (Chemistry), ELECTROSTATIC induction

Abstract

A triboelectric nanogenerator (TENG) can convert energy in the surrounding environment to electricity. Therefore, in recent years, research related to TENGs has significantly increased owing to its simple and low‐cost manufacturing process, high portability, and high efficiency. The principle of the TENG lies in the coupling effect of contact electrification and electrostatic induction. Its output performance is directly proportional to the square of the surface charge density, which is related to friction materials. To increase the output power of a TENG and continuously provide electricity for other electronic equipment, many scholars have conducted detailed studies on the triboelectric properties of materials. Particularly, there has been research interest in the chemical functionalization of TENGs due to their unique advantages, such as high triboelectric charge density, durability, stability, and self‐cleaning properties. This Progress Report highlights the research progress in chemical modification methods for improving the charge density of TENGs, and classifies their modification methods according to their mechanisms. The effects of chemical reaction, surface chemical treatment, and chemical substance doping on the output performance of TENGs are systematically elaborated. Furthermore, the applications of chemically modified TENG in self‐powered sensors and emerging fields, including wearable electronic devices, human‐machine interfaces, and implantable electronic devices, are introduced. Lastly, the challenges faced in the future developments of chemical modification methods are discussed, thereby guiding researchers to the use of chemical modification methods for the improvement of charge density for further exploration. [ABSTRACT FROM AUTHOR]

Published

2020

5. Superhydrophobic Cellulose Paper‐Based Triboelectric Nanogenerator for Water Drop Energy Harvesting.

Author

Nie, Shuangxi, Guo, Hengyu, Lu, Yanxu, Zhuo, Jingting, Mo, Jilong, and Wang, Zhong Lin

Subjects

ENERGY harvesting, RENEWABLE energy sources, CELLULOSE, ELECTROSTATIC induction, MECHANICAL energy, ELASTOMERS, HYDROPHOBIC compounds

Abstract

The high‐efficiency conversion of water drop mechanical energy into electrical energy has always been an urgent issue in the development and utilization of raindrop energy. In this work, a novel drum‐like triboelectric nanogenerator (D‐TENG) with robust self‐cleaning superhydrophobic features is developed to harvest water drop energy. An elastic superhydrophobic cellulose paper is created by spray‐coating nanofumed silica dispersed in a thermoplastic elastomer solution, followed by treatment with triethoxy‐1H,1H,2H,2H‐tridecafluoro‐n‐octylsilane. When raindrops hit the D‐TENG surface, the superhydrophobic cellulose paper will vibrate and periodic contact and separation with polytetrafluoroethylene will occur to generate electricity. The results demonstrate that when a 6 mm water drop falls from a height of 2.5 m and hits the D‐TENG, the generated voltage output can reach a peak of 21.6 V and charge transfer of 10 nC. The output power of the D‐TENG can reach 16 µW per droplet, which is more than 13.3 times that generated from the previous TENGs based on the electrostatic induction of water droplets. These results indicate that the superhydrophobic cellulose paper‐based D‐TENG is potentially a strong candidate for harvesting energy from raindrops, thereby making it a promising sustainable energy source for next‐generation electronics. [ABSTRACT FROM AUTHOR]

Published

2020