Fatty acid isomerism: analysis and selected biological functions.
Zhen WangTingxiang YangJ Thomas BrennaDong Hao WangPublished in: Food & function (2024)
The biological functions of fatty acids and the lipids in which they are esterified are determined by their chain length, double bond position and geometry and other structural motifs such as the presence of methyl branches. Unusual isomeric features in fatty acids of human foods such as conjugated double bonds or chain branching found in dairy products, some seeds and nuts, and marine foods potentially have important effects on human health. Recent advancements in identifying fatty acids with unusual double bond positions and pinpointing the position of methyl branches have empowered the study of their biological functions. We present recent advances in fatty acid structural elucidation by mass spectrometry in comparison with the more traditional methods. The double bond position can be determined by purely instrumental methods, specifically solvent-mediated covalent adduct chemical ionization (SM-CACI) and ozone induced dissociation (OzID), with charge inversion methods showing promise. Prior derivatization using the Paternò-Büchi (PB) reaction to yield stable structures that, upon collisional activation, yield the double bond position has emerged. The chemical ionization (CI) based three ion monitoring (MRM) method has been developed to simultaneously identify and quantify low-level branched chain fatty acids (BCFAs), unattainable by electron ionization (EI) based methods. Accurate identification and quantification of unusual fatty acid isomers has led to research progress in the discovery of biomarkers for cancer, diabetes, nonalcoholic fatty liver disease (NAFLD) and atherosclerosis. Modulation of eicosanoids, weight loss and the health significance of BCFAs are also presented. This review clearly shows that the improvement of analytical capacity is critical in the study of fatty acid biological functions, and stronger coupling of the methods discussed here with fatty acid mechanistic research is promising in generating more refined outcomes.
Keyphrases
- fatty acid
- human health
- gas chromatography
- mass spectrometry
- weight loss
- electron transfer
- risk assessment
- healthcare
- liquid chromatography
- cardiovascular disease
- type diabetes
- high resolution
- public health
- endothelial cells
- bariatric surgery
- heavy metals
- nitric oxide
- climate change
- high glucose
- air pollution
- hydrogen peroxide
- machine learning
- glycemic control
- young adults
- magnetic resonance imaging
- gas chromatography mass spectrometry
- adipose tissue
- high performance liquid chromatography
- health information
- solar cells
- room temperature
- social media
- tandem mass spectrometry
- obese patients
- weight gain