One-step Synthesis Pd@Pt Core-Shell Concave Cube by Facile Reduction Control toward formic acid oxidation reaction

( Xiao ),( Cun Liu ),( Pengfei Jiang ),유태경 한국공업화학회 2020 한국공업화학회 연구논문 초록집 Vol.2020 No.-

The core-shell Pd@Pt nanocubes were successfully designed as concave structure by a galvanic replacement, one-step process. In this study, we chose the ascorbic acid and citric acid as the different strength reduction to facile control the Pd@Pt crystal growth. Firstly, the Pd nanocube formed using ascorbic acid as stronger reducing agent with accuracy control amount. In general, the different intensities reducing agent ascorbic acid and citric acid are the key-points to kinetic control the concave structure formed and the Br^- play the major role to enhance the galvanic replacement reaction between Pt(II)Cl₄^2-and Pd. In addition, the concave cubic Pd@Pt nanocrystal exhibited higher electrochemical performance compare to commercial Pt electrocatalyst toward formic acid oxidation reaction.

Potency of Phlebia species of white rot fungi for the aerobic degradation, transformation and mineralization of lindane

Pengfei Xiao,Ryuichiro Kondo 한국미생물학회 2020 The journal of microbiology Vol.58 No.5

The widespread use of the organochlorine insecticide lindane in the world has caused serious environmental problems. The main purpose of this paper is to investigate the potency of several Phlebia species of white rot fungi to degrade, transform and mineralize lindane, and to provide the feasibility of using white rot fungi for bioremediation at contaminated sites. Based on tolerance experiment results, Phlebia brevispora and Phlebia lindtneri had the highest tolerance to lindane and were screened by degradation tests. After 25 days of incubation, P. brevispora and P. lindtneri degraded 87.2 and 73.3% of lindane in low nitrogen medium and 75.8 and 64.9% of lindane in high nitrogen medium, respectively. Several unreported hydroxylation metabolites, including monohydroxylated, dehydroxylated, and trihydroxylated products, were detected and identified by GC/MS as metabolites of lindane. More than 10% of [14C] lindane was mineralized to 14CO2 by two fungi after 60 days of incubation, and the mineralization was slightly promoted by the addition of glucose. Additionally, the degradation of lindane and the formation of metabolites were efficiently inhibited by piperonyl butoxide, demonstrating that cytochrome P450 enzymes are involved in the fungal transformation of lindane. The present study showed that P. brevispora and P. lindtneri were efficient degraders of lindane; hence, they can be applied in the bioremediation process of lindane-contaminated sites.

Implantation of Adipose-Derived Mesenchymal Stromal Cells (ADSCs)-Lining Prosthetic Graft Promotes Vascular Regeneration in Monkeys and Pigs

Zuo Xiao,Han Pengfei,Yuan Ding,Xiao Ying,Huang Yushi,Li Rui,Jiang Xia,Feng Li,Li Yijun,Zhang Yaya,Zhu Ping,Wang Hongge,Wang Ning,Kang Y. James 한국조직공학과 재생의학회 2024 조직공학과 재생의학 Vol.21 No.4

Background: Current replacement procedures for stenosis or occluded arteries using prosthetic grafts have serious limitations in clinical applications, particularly, endothelialization of the luminal surface is a long-standing unresolved problem. Method: We produced a cell-based hybrid vascular graft using a bioink engulfing adipose-derived mesenchymal stromal cells (ADSCs) and a 3D bioprinting process lining the ADSCs on the luminal surface of GORE-Tex grafts. The hybrid graft was implanted as an interposition conduit to replace a 3-cm-long segment of the infrarenal abdominal aorta in Rhesus monkeys. Results: Complete endothelium layer and smooth muscle layer were fully developed within 21 days post-implantation, along with normalized collagen deposition and crosslinking in the regenerated vasculature in all monkeys. The regenerated blood vessels showed normal functionality for the longest observation of more than 1650 days. The same procedure was also conducted in miniature pigs for the interposition replacement of a 10-cm-long right iliac artery and showed the same long-term effective and safe outcome. Conclusion: This cell-based vascular graft is ready to undergo clinical trials for human patients. Background: Current replacement procedures for stenosis or occluded arteries using prosthetic grafts have serious limitations in clinical applications, particularly, endothelialization of the luminal surface is a long-standing unresolved problem. Method: We produced a cell-based hybrid vascular graft using a bioink engulfing adipose-derived mesenchymal stromal cells (ADSCs) and a 3D bioprinting process lining the ADSCs on the luminal surface of GORE-Tex grafts. The hybrid graft was implanted as an interposition conduit to replace a 3-cm-long segment of the infrarenal abdominal aorta in Rhesus monkeys. Results: Complete endothelium layer and smooth muscle layer were fully developed within 21 days post-implantation, along with normalized collagen deposition and crosslinking in the regenerated vasculature in all monkeys. The regenerated blood vessels showed normal functionality for the longest observation of more than 1650 days. The same procedure was also conducted in miniature pigs for the interposition replacement of a 10-cm-long right iliac artery and showed the same long-term effective and safe outcome. Conclusion: This cell-based vascular graft is ready to undergo clinical trials for human patients.

Murine Model Study of a New Receptor-Targeted Tracer for Sentinel Lymph Node in Breast Cancer

Chonglin Tian,Xiao Sun,Bin-Bin Cong,Pengfei Qiu,Yongsheng Wang 한국유방암학회 2019 Journal of breast cancer Vol.22 No.2

Purpose: Sentinel lymph node biopsy (SLNB), a critical staging and treatment step, has replaced axillary lymph node (LN) dissection as the standard staging procedure for early stage breast cancer patients with clinically negative axillary LNs. Hence, using a murine sentinel lymph node (SLN) model, we investigated the localization effect of the new receptor-targeted tracer, indocyanine green (ICG)-rituximab, on breast cancer SLNB. Methods: After establishing the murine SLN model, different doses of ICG-rituximab were subcutaneously injected into the hind insteps of BALB/c mice to determine the optimal dose and imaging time using continuous (> 3 hours) MDM-I fluorescence vasculature imaging. To explore the capacity of ICG-rituximab for sustained SLN localization with the optimal dose, MDM-I imaging was monitored at 6, 12, and 24 hours. Results: The popliteal LN was defined as the SLN for hindlimb lymphatic drainage, the iliac LN as the secondary, and the para-aortic or renal LN as the tertiary LNs. The SLN initial imaging and optimal imaging times were shortened with increased ICG-rituximab doses, and the imaging rates of the secondary and tertiary LNs increased accordingly. The optimal ICG dose was 0.12 μg, and its optimal imaging time was 34 minutes. After 24 hours, the SLN imaging rate remained 100%, while those of the secondary and the tertiary LNs increased from 0% (6 hours) and 0% (6 hours) to 10% (12 hours) and 10% (12 hours) to 20% (24 hours) and 10% (24 hours), respectively. Conclusion: ICG-rituximab localized to the SLN without imaging from the secondary or tertiary LNs within 6 hours. The optimal ICG dose was 0.12 μg, and the optimal interval for SLN detection was 34 minutes to 6 hours post-injection. This novel receptor-targeted tracer is of great value to clinical research and application.

Synergistic and sustainable activation of peroxymonosulfate by nanoscale MWCNTs-CuFe2O4 as a magnetic heterogeneous catalyst for the efficient removal of levofloxacin

Zhao Jing,Xiao Pengfei 한국화학공학회 2023 Korean Journal of Chemical Engineering Vol.40 No.6

Nanoscale CuFe2O4 was anchored on the surface of multiwalled carbon nanotubes (MWCNTs) as a magnetic heterogeneous catalyst to achieve efficient and sustainable activation of peroxymonosulfate and degradation of levofloxacin through the synergistic effect of the above materials. The catalyst properties were characterized by a series of detection techniques. It was found that the mass ratio of MWCNTs-CuFe2O4, operational parameters and common interfering substances influenced the levofloxacin removal efficiency to a certain extent. This study sheds light on the ultraefficient removal of levofloxacin with the MWCNTs-CuFe2O4(1:3)/peroxymonosulfate system, which has advantages over other reaction systems. More importantly, we propose two pathways of peroxymonosulfate activation, including free radicals and nonfree radicals, in which superoxide radicals and signal oxygen are the main active species. In addition, we observed that the MWCNT surface groups contributed to the peroxymonosulfate activation processes with the generation of extra reactive species. The Fe3+/Fe2+ and Cu2+/Cu+ redox cycles are conducive to the continuous generation of active species. The results of the catalyst recycling test, metal ion leaching test and mineralization test suggested that the fabricated catalyst had excellent catalytic stability, sustainability and mineralization ability. In addition, twenty-one intermediates were detected using liquid chromatography-mass spectrometry, and three possible degradation pathways were further proposed. MWCNTs-CuFe2O4 makes up for the shortcomings of transition metals and single carbon materials in activating peroxymonosulfate to treat wastewater and have significant potential to improve the separation and catalytic capacity of the catalyst. This study provides new ideas for the design of high-performance multiphase catalysts for applications in catalytic oxidation and proposes new insights into the mechanistic investigation.

Li- and Mn-Rich Cathode Materials: Challenges to Commercialization

Zheng, Jianming,Myeong, Seungjun,Cho, Woongrae,Yan, Pengfei,Xiao, Jie,Wang, Chongmin,Cho, Jaephil,Zhang, Ji-Guang Wiley Blackwell (John Wiley Sons) 2017 ADVANCED ENERGY MATERIALS Vol.7 No.6

Trace surface fluorination and tungsten-intercalation cooperated dual modification induced photo-activity enhancement of titanium dioxide

Yifan Xu,Zhongyuan Liu,Kunlun Wang,Chunyao Niu,Pengfei Yuan,Jin You Zheng,Young Soo Kang,Xiao Li Zhang 한국공업화학회 2022 Journal of Industrial and Engineering Chemistry Vol.108 No.-

General modification that utilizes insoluble tungstic acid or highly toxic hydrofluoric acid to improvecharge separation and transfer in TiO2 results in considerable issues such as uneven doping, significantimpacts on particle size and morphology, as well as environmental hazards. In the present work, an environmentalbenign one-pot dual-modification approach was demonstrated that uses soluble sodium tungstateand only trace-level sodium fluoride as replacements. The photoactivity efficiency for decolorationof methylene blue (MB) solution was improved by 33.6% and 119.5% under ultraviolet and visible light,respectively. Meanwhile, the photocurrent density reached an enhancement by 181.2% by this dualmodification. The dual-modification had negligible influence on the crystal structure and the surface areaof the TiO2 nanoparticles. Density functional calculation suggested the remarkable improvements of thephotocatalysis of TiO2 can be ascribed to the rapid charge separation and transfer owing to the downshiftof conduction band from the tungsten doping and localized spatial charge separation from the surfacefluorination enabled by the dual-modification approach.