Your search keyword '"Chen, Chaobi"' showing total 2 results

1. Semi‐aromatic polyamide containing ether bond/hydroxyapatite composites: Preparation, structure and cytocompatibility.

Author

Chen, Chaobi, Lyu, Defu, Xi, Wenjing, Chen, Lichao, Cai, Shijie, Yan, Yonggang, Li, Xiaodan, Ren, Haohao, and Xing, Rong

Subjects

PRECIPITATION (Chemistry), HYDROXYAPATITE, CYTOCOMPATIBILITY, NUCLEOPHILIC substitution reactions, POLYAMIDES, COMPACT bone, ETHERS

Abstract

In this work, semi‐aromatic polyamide containing ether bond (PAE10T) was synthesized through nucleophilic substitution reaction using 1, 10‐N, N′‐bis(4‐fuorobenzamide) decane (BFBD) and hydroquinone (HQ) as the raw materials. And then the composites hydroxyapatite/semi‐aromatic polyamide (40%HA‐PAE10T and 60%HA‐PAE10T) were prepared by chemical precipitation method. Mechanical, SEM, FT‐IR, XRD, DSC, TGA and bioactivity tests were performed to characterize the structure, morphology, thermal and mechanical properties of PAE10T and its composites. Mechanical tests revealed that the difference of HA in weight played an important role in mechanical performance of the composites. Furthermore, in comparison with PAE10T, the 60%HA‐PAE10T showed the highest enhancement in compressive strength (133 MPa) at 75.9%, and the 40%HA‐PAE10T given expression to the best increase in bending strengths (97 MPa) at about 18.4%. The 40%HA‐PAE10T and 60% HA‐PAE10T exhibited the mechanical performances closed to the cortical bone of human. After 28 days of dip in the phosphate buffer saline (PBS), PAE10T, and its composites showed satisfactory stability. The cell culture results showed all composites gad good cytocompatibility, cells attached on the materials well with excellent morphology. All the experimental results showed that the composites were expected to have a good application in the field of compact bone repair. [ABSTRACT FROM AUTHOR]

Published

2024

2. Preparation, characterization, and in vitro biological evaluation of salicylic acid‐modified polyphenylene sulfide/quartz fiber/hydroxyapatite composite with high mechanical property for bone replacement.

Author

Cai, Shijie, Yan, Dawei, Chen, Xiaolu, Yang, Hulin, Chen, Chaobi, Li, Xiaodan, Yan, Yonggang, and Ren, Haohao

Subjects

POLYPHENYLENE sulfide, HYDROXYAPATITE, BONE mechanics, GOLD ores, FIBROUS composites, FOURIER transform infrared spectroscopy, MESENCHYMAL stem cells, QUARTZ

Abstract

The surface inertness of pure polyphenylene sulfide (PPS) limits its application in orthopedic implant materials. On that basis, modified PPS containing hydroxyl and carboxyl groups, that is, SAPPS was synthesized by nucleophilic substitution of dihalide monomers and sodium sulfide under high pressure. And consequently, a kind of ternary composite consisting of polyphenylene sulfide salicylate/quartz fiber/hydroxyapatite (SAPPS/QF/HA) was developed. The structure, composition, cross section morphology, degradation behavior, mechanical property, and biological property of all the composites were characterized by Fourier transform infrared spectroscopy, x‐ray diffraction, differential scanning calorimetry, thermogravimetric analyzer, scanning electron microscope, energy dispersive spectrometer, and in vitro cytocompatibility tests. The composites exhibited good thermal property, which achieved a high melting point (277.8°C) and decomposition temperature (493.9–502.7°C at 5% weight loss). When the mass fraction of 20 wt% QF and 20 wt% HA was added in the pure SAPPS, the bending yield strength and bending modulus of the composite (SAPPS/20QF/20HA) were 177.4 MPa and 8.03 GPa, respectively, which increased by 61.6% and 158.2% compared with that of the pure SAPPS. Observing the considerable proliferation and adhesion of mouse bone marrow mesenchymal stem cells (mBMSCs) in the experiment, we demonstrated that the SAPPS and its composites were non‐toxic, and the SAPPS/QF/20HA composites had the most prominent effect in promoting the proliferation and adhesion of mBMSCs. Highlights: Salicylic acid‐modified polyphenylene sulfide was studied as a biomaterial.The composite material has mechanics matching with human cortical bone.Cell experiments showed that all materials were nontoxic. [ABSTRACT FROM AUTHOR]

Published

2024