Your search keyword '"Fan, Chunli"' showing total 6 results

1. Analyses of the Complete Mitochondrial Genome of Paraconiothyrium sp. and Gene Rearrangement Diversity in the Pleosporales.

Author

An, Jiaqi, Fan, Chunli, Fu, Zuoyi, Zhang, Hongping, and Yang, Pu

Subjects

*MITOCHONDRIAL DNA, *GENE rearrangement, *SCALE insects, *ZINC oxide, *GENOMES, *SPECIES diversity

Abstract

The Pleosporales is the most predominant order in the Dothideomycetes class, which contains over 4700 species that function in a variety of ways. The material used in this research was previously isolated from the Chinese white wax scale insect, and it was determined to be a Paraconiothyrium genus species that belonged to the Pleosporales order. For further molecular analysis, we assembled the complete mitochondrial genome of Paraconiothyrium sp. based on short reads of BGISEQ sequencing and subreads from Pacbio sequencing. The results showed that it was 42,734 bp in length and contained 8 open reading frames, 12 protein-coding genes and 31 non-coding genes. Phylogenetic analysis showed it was affiliated to the Pleosporales order and formed a sister relationship with Pithomyces chartarum. Compared to the seven other species in the Pleosporales order, Paraconiothyrium sp. has generally conserved gene content and structure, while the homologous blocks and gene order were shown to be significantly rearranged, in accordance with the species diversity in the Pleosporales order. In this study, we presented the first mitochondrial genome of Paraconiothyrium fungi to be reported, and we also showed gene order diversity in the Pleosporales order. These findings will lay the foundation for further species studies regarding molecular diversity and our understanding of species characteristics in the Paraconiothyrium genus. [ABSTRACT FROM AUTHOR]

Published

2022

2. Barrier Properties and Characterizations of Poly(lactic Acid)/ZnO Nanocomposites.

Author

Tang, Zhenya, Fan, Fangling, Chu, Zhuangzhuang, Fan, Chunli, Qin, Yuyue, Bikiaris, Dimitrios, and Jimenez, Alfonso

Subjects

POLYLACTIC acid, LACTIC acid, ZINC oxide, TERNARY system, DIFFERENTIAL scanning calorimetry, X-ray scattering, INFRARED spectroscopy

Abstract

This study aimed to reinforce the barrier performance (i.e., oxygen–gas and water–vapor permeability) of poly(lactic acid) (PLA)-based films. Acetyltributylcitrate and zinc oxide nanoparticle (nano-ZnO), serving as plasticizer and nanofiller, respectively, were blended into a PLA matrix through a solvent-volatilizing method. The structural, morphological, thermal, and mechanical performances were then studied. Scanning electron microscopic images showed a significant dispersion of nano-ZnO in PLA ternary systems with low nano-ZnO content. The interaction between PLA matrix and ZnO nanoparticles was further analyzed by Fourier-transform infrared spectroscopy. Wide-angle X-ray scattering spectroscopy demonstrated high compatibility between PLA matrix and ZnO nanoparticles. Mechanical property studies revealed good tensile strength and low flexibility. Differential scanning calorimetry curves proved that an amorphous structure mostly existed in PLA ternary systems. The improvements in barrier property and tensile strength indicated that the PLA/nano-ZnO composite films could be used for food packaging application. [ABSTRACT FROM AUTHOR]

Published

2020

3. The Performance Changes and Migration Behavior of PLA/Nano-TiO2 Composite Film by High-Pressure Treatment in Ethanol Solution.

Author

Tang, Zhenya, Fan, Fangling, Fan, Chunli, Jiang, Kai, and Qin, Yuyue

Subjects

NANOPARTICLES, PACKAGING film, FOOD packaging, ACETALDEHYDE, PACKAGING materials, POLYLACTIC acid

Abstract

To study the relationship between performance changes and nanoparticles migration of the composite film at different migration stages, the poly (lactic acid) (PLA)/nano-TiO2 composite film treated by high pressure was immersed in 50% (v/v) ethanol solution for 45 days at 40 °C, and the film characteristics and migration behavior were analyzed. The results showed that the migration of the composite film with the highest loading of nano-TiO2 (20 wt. %) in alcoholic food simulated solution was far less than 10 mg/kg during the 45-day migration process. Although with the increase of migration time, the micro-morphology of composite film became rougher, the crystallinity decreased and the gas permeability increased, but the internal crystal structure of the composite film remained basically unchanged. The PLA/nano-TiO2 composite films treated by high pressure treatment were relatively stable, and had good performance and migration behavior in alcoholic food simulated solution, the nanocomposite film after high pressure treatment could be used to reduce nano-TiO2 particle migration and subsequently reduce human exposure as the packaging film for the packaging of alcoholic food, which provide a theoretical basis for the applications of high pressure treatment of PLA/nano-TiO2 composite films in food packaging material and broaden its application prospects. [ABSTRACT FROM AUTHOR]

Published

2020

4. Effect of High Pressure Treatment on Poly(lactic acid)/Nano–TiO2 Composite Films.

Author

Chi, Hai, Li, Wenhui, Fan, Chunli, Zhang, Cheng, Li, Lin, Qin, Yuyue, and Yuan, Minglong

Subjects

FUNCTIONAL groups, NANOPARTICLES, MICROSTRUCTURE, CHEMICAL bonds, CRYSTALLINITY, HIGH pressure (Science), POLYLACTIC acid, COMPOSITE materials

Abstract

The microstructure, thermal properties, mechanical properties and oxygen and water vapor barrier properties of a poly(lactic acid) (PLA)/nano-TiO2 composite film before and after high pressure treatment were studied. Structural analysis showed that the functional group structure of the high pressure treated composite film did not change. It was found that the high pressure treatment did not form new chemical bonds between the nanoparticles and the PLA. The micro-section of the composite film after high pressure treatment became very rough, and the structure was depressed. Through the analysis of thermal and mechanical properties, high pressure treatment can not only increase the strength and stiffness of the composite film, but also increase the crystallinity of the composite film. Through the analysis of barrier properties, it is found that the barrier properties of composite films after high pressure treatment were been improved by the applied high pressure treatment. [ABSTRACT FROM AUTHOR]

Published

2018

5. The Performance Changes and Migration Behavior of PLA/Nano-TiO 2 Composite Film by High-Pressure Treatment in Ethanol Solution.

Author

Tang Z, Fan F, Fan C, Jiang K, and Qin Y

Abstract

To study the relationship between performance changes and nanoparticles migration of the composite film at different migration stages, the poly (lactic acid) (PLA)/nano-TiO 2 composite film treated by high pressure was immersed in 50% ( v / v ) ethanol solution for 45 days at 40 °C, and the film characteristics and migration behavior were analyzed. The results showed that the migration of the composite film with the highest loading of nano-TiO 2 (20 wt. %) in alcoholic food simulated solution was far less than 10 mg/kg during the 45-day migration process. Although with the increase of migration time, the micro-morphology of composite film became rougher, the crystallinity decreased and the gas permeability increased, but the internal crystal structure of the composite film remained basically unchanged. The PLA/nano-TiO 2 composite films treated by high pressure treatment were relatively stable, and had good performance and migration behavior in alcoholic food simulated solution, the nanocomposite film after high pressure treatment could be used to reduce nano-TiO 2 particle migration and subsequently reduce human exposure as the packaging film for the packaging of alcoholic food, which provide a theoretical basis for the applications of high pressure treatment of PLA/nano-TiO 2 composite films in food packaging material and broaden its application prospects., Competing Interests: The authors declare no conflict of interest.

Published

2020

6. Effect of High Pressure Treatment on Poly(lactic acid)/Nano⁻TiO₂ Composite Films.

Author

Chi H, Li W, Fan C, Zhang C, Li L, Qin Y, and Yuan M

Subjects

Product Packaging, Temperature, Tensile Strength, Nanocomposites chemistry, Polyesters chemistry, Titanium chemistry

Abstract

The microstructure, thermal properties, mechanical properties and oxygen and water vapor barrier properties of a poly(lactic acid) (PLA)/nano-TiO₂ composite film before and after high pressure treatment were studied. Structural analysis showed that the functional group structure of the high pressure treated composite film did not change. It was found that the high pressure treatment did not form new chemical bonds between the nanoparticles and the PLA. The micro-section of the composite film after high pressure treatment became very rough, and the structure was depressed. Through the analysis of thermal and mechanical properties, high pressure treatment can not only increase the strength and stiffness of the composite film, but also increase the crystallinity of the composite film. Through the analysis of barrier properties, it is found that the barrier properties of composite films after high pressure treatment were been improved by the applied high pressure treatment.

Published

2018