Bo Wang scite author profile

Fast, sensitive, and simple methods for quantitative analysis of disparities in glycan expression between different biological samples are essential for studies of protein glycosylation patterns (glycomics) and the search for disease glycan biomarkers. Relative quantitation of glycans based on stable isotope labeling combined with mass spectrometric detection represents an emerging and promising technique. However, this technique is undermined by the complexity of mass spectra of isotope-labeled glycans caused by the presence of multiple metal ion adduct signals, which result in a decrease of detection sensitivity and an increase of difficulties in data interpretation. Herein we report a simplified quantitative glycomics strategy, which features nonreductive isotopic labeling of reducing glycans with either nondeuterated (d0-) or deuterated (d5-) Girard's reagent P (GP) without salts introduced and simplified mass spectrometric profiles of d0- and d5-GP derivatives of neutral glycans as molecular ions without complex metal ion adducts, allowing rapid and sensitive quantitative comparison between different glycan samples. We have obtained optimized GP-labeling conditions and good quantitation linearity, reproducibility, and accuracy of data by the method. Its excellent applicability was validated by comparatively quantitative analysis of the neutral N-glycans released from bovine and porcine immunoglobulin G as well as of those from mouse and rat sera. Additionally, we have revealed the potential of this strategy for the high-sensitivity analysis of sialylated glycans as GP derivatives, which involves neutralization of the carboxyl group of sialic acid by chemical derivatization.

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Tri-phase behavior of ionic liquid–water–CO₂system at elevated pressures

Zhang

Gao

et al. 2004

Phys. Chem. Chem. Phys.

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The phase behavior of CO 2 -water-1-n-butyl-3-methyl-imidazolium tetrafluoroborate ([bmim][BF 4 ]) system at different conditions has been studied by the static method in the temperature range of 5 to 25 1C and pressures up to 16 MPa. At a fixed temperature or pressure there can exist four phases. However, this work focuses on the compositions of the phases in three-phase region (ionic liquid-rich phase, water-rich phase, CO 2 -rich phase). The phase diagrams at 20.0 1C and 5.0 MPa have been discussed in detail. At 20.0 1C the concentration difference of the ionic liquid (IL) in IL-rich phase and water-rich phase becomes larger and larger with increasing pressure. At 5.0 MPa, IL concentration in the IL-rich phase decreases with increasing temperature, while that in the waterrich phase increases as temperature rises, and the difference of IL concentration in the IL-rich phase and waterrich phase is sensitive to temperature. On the basis of phase equilibrium data the distribution coefficients of [bmim][BF 4 ] between IL-rich phase and water-rich phase are calculated, and separation of IL and water is discussed.

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Solvent Molecule Cooperation Enhancing Lithium Metal Battery Performance at Both Electrodes

Han

Zhong

et al. 2020

Angew Chem Int Ed

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Developing electrolytes compatible with efficient and reversible cycling of electrodes is critical to the success of rechargeable Li metal batteries (LMBs). The Coulombic efficiencies and cycle lives of LMBs with ethylene carbonate (EC), dimethyl carbonate, ethylene sulfite (ES), and their combinations as electrolyte solvents show that in a binarysolvent electrolyte the extent of electrolyte decomposition on the electrode surface is dependent on the solvent component that dominates the solvation sheath of Li + . This knowledge led to the development of an EC-ES electrolyte exhibiting high performance for Li jj LiFePO 4 batteries. Carbonate molecules occupy the solvation sheath and improve the Coulombic efficiencies of both the anode and cathode. Sulfite molecules lead to desirable morphology and composition of the solid electrolyte interphase and extend the cycle life of the Li metal anode. The cooperation between these components provides a new example of electrolyte optimization for improved LMBs.Lithium ion batteries (LIBs) have boosted the development of portable electronics, electric vehicles, and smart grids in the past decades. [1] Nevertheless, their energy density is approaching the ceiling, which plagues their wider application in the future. The demand for more powerful batteries has motivated researchers to explore new chemistries beyond Li ion intercalation. Li metal electrodes operating upon the interconversion between Li 0 and Li + are a popular candidate for the anode. [2][3][4][5] Despite its ultrahigh specific capacity of 3860 mAh g À1 , the deposition/dissolution process often exhibits relatively low Coulombic efficiency (CE) owing to the high reactivity of Li metal with common electrolytes, which would corrode the Li anode and shorten its cycle life. [6][7][8][9] In our prior research, we found that the efficiency of a thick Li metal electrode is limited by the reactivity of the electrolyte and the cycle life is determined by the properties of the interphase layer. [10] Yet how the electrolyte species interact with the Li metal electrode under electrochemical conditions and affect the performance of Li metal batteries (LMBs) are not well understood. Solvation of the Li + ion is considered to be important to the chemistry at the electrode/ electrolyte interface. [11] Various techniques, including vibrational spectroscopy (FTIR or Raman), [12][13][14][15] electrospray ionization mass spectrometry, [16] and nuclear magnetic resonance spectroscopy [17,18] have been employed to study the structure of the solvation sheath and to understand the interfacial chemistry on the molecular level. It has been shown that the solvation structure is related to important phenomena in LIBs, including formation of the solid electrolyte interphase (SEI), [19] co-intercalation of solvent, [20] and effects of concentrated electrolyte. [14,15,21] As new electrolytes remain to be developed for efficient and stable LMBs, it is necessary to study the correlation of the Li + ion solvation with the performance of Li metal ...

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Bo Wang

Rhodium(III)‐Catalyzed Transannulation of Cyclopropenes with N‐Phenoxyacetamides through CH Activation

Simplified Quantitative Glycomics Using the Stable Isotope Label Girard’s Reagent P by Electrospray Ionization Mass Spectrometry

Tri-phase behavior of ionic liquid–water–CO₂system at elevated pressures

Solvent Molecule Cooperation Enhancing Lithium Metal Battery Performance at Both Electrodes

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Bo Wang

Rhodium(III)‐Catalyzed Transannulation of Cyclopropenes with N‐Phenoxyacetamides through CH Activation

Simplified Quantitative Glycomics Using the Stable Isotope Label Girard’s Reagent P by Electrospray Ionization Mass Spectrometry

Tri-phase behavior of ionic liquid–water–CO2system at elevated pressures

Solvent Molecule Cooperation Enhancing Lithium Metal Battery Performance at Both Electrodes

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Tri-phase behavior of ionic liquid–water–CO₂system at elevated pressures