Structural Analysis of Lipid Hydroperoxides Using Mass Spectrometry with Alkali Metals

Kato, Shunji; Shimizu, Naoki; Ogura, Yusuke; Otoki, Yurika; Ito, Junya; Sakaino, Masayoshi; Sano, Takashi; Kuwahara, Shigefumi; Takekoshi, Susumu; Imagi, Jun; Nakagawa, Kiyotaka

doi:10.1021/jasms.1c00039

Cited by 16 publications

(17 citation statements)

References 43 publications

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“…First of all, to achieve accurate analyses, we prepared authentic standards. When these standards were analyzed, in accordance with our previous studies [5,13], sodiated PC 16:0/18:2;OOH and CE 18:2;OOH isomers generated the hydroperoxyl group position-specific product ions (Figure 2). On the other hand, this study newly showed that sodiated cis-trans isomers of PC 16:0/18:2;OOH (e.g., Figure 2A,B) and CE 18:2;OOH (e.g., Figure 2G,H) did not provide the differences in product ions.…”

Section: Discussionsupporting

confidence: 79%

“…Using this method, we analyzed PC 16:0/18:2;9OOH and PC 16:0/18:2;13OOH in human plasma and hypothesized the contribution of radical and/or enzymatic oxidation to PC 16:0/18:2;OOH formation in human plasma lipoproteins [5]. Recently, we further showed the evidence that CID of sodiated LOOH is available to various lipid classes, including cholesterol ester [13]. Therefore, in this study, to ensure the above hypothesis (i.e., LOOH present in plasma lipoproteins are mainly derived from radical and/or enzymatic oxidation), we firstly developed novel analytical methods for PC 16:0/18:2;OOH and CE 18:2;OOH isomers.…”

Section: Discussionmentioning

confidence: 99%

“…The hydroperoxyl group of the resulting FA 18:2;OOH isomers was then protected with MxP for subsequent esterification [12]. Protected FA 18:2;OOH isomers were esterified with LPC 16:0/0:0 or cholesterol [12,13]. Protected PC 16:0/18:2;OOH and CE 18:2;OOH isomers were finally deprotected and purified as in a previous study [12,13].…”

Section: Methodsmentioning

confidence: 99%

“…Protected FA 18:2;OOH isomers were esterified with LPC 16:0/0:0 or cholesterol [12,13]. Protected PC 16:0/18:2;OOH and CE 18:2;OOH isomers were finally deprotected and purified as in a previous study [12,13].…”

Section: Methodsmentioning

confidence: 99%

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Investigation of Lipoproteins Oxidation Mechanisms by the Analysis of Lipid Hydroperoxide Isomers

et al. 2021

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The continuous formation and accumulation of oxidized lipids (e.g., lipid hydroperoxides (LOOH)) which are present even in plasma lipoproteins of healthy subjects, are ultimately considered to be linked to various diseases. Because lipid peroxidation mechanisms (i.e., radical, singlet oxygen, and enzymatic oxidation) can be suppressed by certain proper antioxidants (e.g., radical oxidation is efficiently suppressed by tocopherol), in order to suppress lipid peroxidation successfully, the determination of the peroxidation mechanism involved in the formation of LOOH is deemed crucial. In this study, to determine the peroxidation mechanisms of plasma lipoproteins of healthy subjects, we develop novel analytical methods using liquid chromatography-tandem mass spectrometry (LC-MS/MS) for 1-palmitoyl-2-linoleoyl-sn-glycero-3-phosphocholine hydroperoxide (PC 16:0/18:2;OOH) and cholesteryl linoleate hydroperoxide (CE 18:2;OOH) isomers. Using the newly developed methods, these PC 16:0/18:2;OOH and CE 18:2;OOH isomers in the low-density lipoprotein (LDL) and high-density lipoprotein (HDL) of healthy subjects are analyzed. Consequently, it is found that predominant PC 16:0/18:2;OOH and CE 18:2;OOH isomers in LDL and HDL are PC 16:0/18:2;9OOH, PC 16:0/18:2;13OOH, CE 18:2;9OOH, and CE 18:2;13OOH, which means that PC and CE in LDL and HDL are mainly oxidized by radical and/or enzymatic oxidation. In conclusion, the insights about the oxidation mechanisms shown in this study would be useful for a more effective suppression of oxidative stress in the human organism.

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Section: Discussionsupporting

confidence: 79%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Investigation of Lipoproteins Oxidation Mechanisms by the Analysis of Lipid Hydroperoxide Isomers

et al. 2021

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“…Recently Kato et al [ 81 ] investigated the effects of different alkali metals on the fragmentation of LOOHs. From the analysis of PC 16:0/18:2;OOH (phosphatidylcholine) and FA 18:2;OOH (fatty acid), fragmentation pathways and ion intensities were found to depend largely on the binding position and type of alkali metals (i.e., Li + , Hock fragmentation; Na + and K + , α -cleavage (Na + > K + ); Rb + and Cs + , no fragmentation).…”

Section: Hyphenated Methodsmentioning

confidence: 99%

Analytical and Structural Tools of Lipid Hydroperoxides: Present State and Future Perspectives

Kontogianni

Gerothanassis

2022

Molecules

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Mono- and polyunsaturated lipids are particularly susceptible to peroxidation, which results in the formation of lipid hydroperoxides (LOOHs) as primary nonradical-reaction products. LOOHs may undergo degradation to various products that have been implicated in vital biological reactions, and thus in the pathogenesis of various diseases. The structure elucidation and qualitative and quantitative analysis of lipid hydroperoxides are therefore of great importance. The objectives of the present review are to provide a critical analysis of various methods that have been widely applied, and more specifically on volumetric methods, applications of UV-visible, infrared, Raman/surface-enhanced Raman, fluorescence and chemiluminescence spectroscopies, chromatographic methods, hyphenated MS techniques, NMR and chromatographic methods, NMR spectroscopy in mixture analysis, structural investigations based on quantum chemical calculations of NMR parameters, applications in living cells, and metabolomics. Emphasis will be given to analytical and structural methods that can contribute significantly to the molecular basis of the chemical process involved in the formation of lipid hydroperoxides without the need for the isolation of the individual components. Furthermore, future developments in the field will be discussed.

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Self‐Assembly of Selenium‐Doped Carbon Quantum Dots as Antioxidants for Hepatic Ischemia‐Reperfusion Injury Management

Bai

Yang

et al. 2023

Small

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Hepatic ischemia‐reperfusion injury (HIRI) is a critical complication after liver surgery that negatively affects surgical outcomes of patients with the end‐stage liver‐related disease. Reactive oxygen species (ROS) are responsible for the development of ischemia‐reperfusion injury and eventually lead to hepatic dysfunction. Selenium‐doped carbon quantum dots (Se‐CQDs) with an excellent redox‐responsive property can effectively scavenge ROS and protect cells from oxidation. However, the accumulation of Se‐CQDs in the liver is extremely low. To address this concern, the fabrication of Se‐CQDs‐lecithin nanoparticles (Se‐LEC NPs) is developed through self‐assembly mainly driven by the noncovalent interactions. Lecithin acting as the self‐assembly building block also makes a pivotal contribution to the therapeutic performance of Se‐LEC NPs due to its capability to react with ROS. The fabricated Se‐LEC NPs largely accumulate in the liver, effectively scavenge ROS and inhibit the release of inflammatory cytokines, thus exerting beneficial therapeutic efficacy on HIRI. This work may open a new avenue for the design of self‐assembled Se‐CQDs NPs for the treatment of HIRI and other ROS‐related diseases.

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Structural Analysis of Lipid Hydroperoxides Using Mass Spectrometry with Alkali Metals

Cited by 16 publications

References 43 publications

Investigation of Lipoproteins Oxidation Mechanisms by the Analysis of Lipid Hydroperoxide Isomers

Investigation of Lipoproteins Oxidation Mechanisms by the Analysis of Lipid Hydroperoxide Isomers

Analytical and Structural Tools of Lipid Hydroperoxides: Present State and Future Perspectives

Self‐Assembly of Selenium‐Doped Carbon Quantum Dots as Antioxidants for Hepatic Ischemia‐Reperfusion Injury Management

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