Your search keyword '"Ji YG"' showing total 3 results

1. Efficient Nitrate-to-Ammonia Electroreduction at Cobalt Phosphide Nanoshuttles.

Author

Jia Y, Ji YG, Xue Q, Li FM, Zhao GT, Jin PJ, Li SN, and Chen Y

Abstract

The nitrate electroreduction reaction (NO 3 - -ERR) is an efficient and green approach for nitrate remediation, which requires a highly active and selective electrocatalyst. In this work, porous and amorphous cobalt phosphide nanoshuttles (CoP PANSs) are successfully synthesized by using Mg 2+ ion-doped calcium carbonate nanoshuttles (Mg-CaCO 3 NSs) as the initial reaction precursor via precipitation transformation and a high-temperature phosphidation strategy. Various physical characterizations show that CoP PANSs have porous architecture, amorphous crystal structure, and big surface area. Electrochemical measurements reveal for the first time that CoP PANSs have outstanding electroactivity for NO 3 - -ERR in a neutral electrolyte. At an applied potential of -0.5 V vs reversible hydrogen electrode, CoP PANSs can achieve a high Faraday efficiency (94.24 ± 2.8%) and high yield rate (19.28 ± 0.53 mg h -1 mg cat -1 ) for ammonia production, which exceeds most reported values at various electrocatalysts for NO 3 - -ERR. Thus, the present result indicates that cobalt phosphide nanomaterials have promising application for NO 3 - -ERR.

Published

2021

2. Early-Stage Lung Cancer Diagnosis by Deep Learning-Based Spectroscopic Analysis of Circulating Exosomes.

Author

Shin H, Oh S, Hong S, Kang M, Kang D, Ji YG, Choi BH, Kang KW, Jeong H, Park Y, Hong S, Kim HK, and Choi Y

Subjects

Biomarkers, Tumor, Humans, Spectrum Analysis, Raman, Deep Learning, Exosomes, Lung Neoplasms diagnosis

Abstract

Lung cancer has a high mortality rate, but an early diagnosis can contribute to a favorable prognosis. A liquid biopsy that captures and detects tumor-related biomarkers in body fluids has great potential for early-stage diagnosis. Exosomes, nanosized extracellular vesicles found in blood, have been proposed as promising biomarkers for liquid biopsy. Here, we demonstrate an accurate diagnosis of early-stage lung cancer, using deep learning-based surface-enhanced Raman spectroscopy (SERS) of the exosomes. Our approach was to explore the features of cell exosomes through deep learning and figure out the similarity in human plasma exosomes, without learning insufficient human data. The deep learning model was trained with SERS signals of exosomes derived from normal and lung cancer cell lines and could classify them with an accuracy of 95%. In 43 patients, including stage I and II cancer patients, the deep learning model predicted that plasma exosomes of 90.7% patients had higher similarity to lung cancer cell exosomes than the average of the healthy controls. Such similarity was proportional to the progression of cancer. Notably, the model predicted lung cancer with an area under the curve (AUC) of 0.912 for the whole cohort and stage I patients with an AUC of 0.910. These results suggest the great potential of the combination of exosome analysis and deep learning as a method for early-stage liquid biopsy of lung cancer.

Published

2020

3. Cascade Alkynylation and Highly Selective Hydrogenation Catalyzed by Binaphthyl-Palladium Nanoparticles Accessing Phosphinyl ( Z )-[3]Dendralenes.

Author

Xia YT, Wu JJ, Zhang CY, Mao M, Ji YG, and Wu L

Abstract

A cascade alkynylation and selective hydrogenation catalyzed by covalent binaphthyl-stabilized palladium nanoparticles has been established, providing a novel and highly efficient methodology for accessing Z and Z,Z -selective phosphinyl [3]dendralenes with broad functional group tolerance and good yields. This strategy achieves the first cascade reactions of alkynylation and hydrogenation with chemoselectivity modulated by catalyst loading.

Published

2019