Metodología analítica para la determinación de oxiesteroles

Gas chromatographic separation and mass spectrometric identification of mixtures of oxyphytosterol and oxycholesterol derivatives

Pure individual phytosterols were prepared using reversed-phase HPLC in order to obtain the oxidized compounds of sitosterol, campesterol, stigmasterol and brassicasterol. 7-Hydroxy-, 7-keto-, 5,6-epoxy-, 4beta-hydroxy-, 4-ene-6-hydroxy-, 6-keto- and 5alpha,6beta-dihydroxyphytosterols were obtained as well as analogous compounds of cholesterol. The gas chromatographic properties as well as the electronic impact mass spectra of these compounds (as trimethylsilyl ether derivatives) were studied. These data were used to identify oxyphytosterols in a spread enriched in phytosterols: the oxyphytosterols represented no more than 68 microg/g of spread (about 0.08% of phytosterols were oxidised).

Oxysterol profiles of normal human arteries, fatty streaks and advanced lesions

OBJECTIVE

Human atherosclerotic lesions of different stages have quantitative differences in cholesterol and oxysterol content, but information on the oxysterol profile in fatty streaks is limited. This study aims to provide more detailed oxysterol quantification in human fatty streaks, as well as normal aorta and advanced lesions.

METHODS

A newly adapted method was used, including oxysterol purification by means of a silica cartridge; and it was ensured that artifactual oxysterol formation was kept to a minimum. Cholesterol and oxysterols were estimated by GC and identification confirmed by GC-MS in samples of normal human arterial intima, intima with near-confluent fatty streaks and advanced lesions, in necropsy samples.

RESULTS

The oxysterols 7 alpha-hydroxycholesterol, cholesterol-5 beta, 6 beta-epoxide, cholesterol-5 alpha, 6 alpha-epoxide, 7 beta-hydroxycholesterol, 7-ketocholesterol and 27-hydroxycholesterol (formerly known as 26-hydroxycholesterol) were found in all the lesions, but were at most very low in the normal aorta, both when related to wet weight and when related to cholesterol. Most components of the normal artery showed some cross-correlation on linear regression analysis, but cross-correlations were weaker in the fatty streaks and advanced lesions. However, in fatty streak there was a marked positive correlation between 27-hydroxycholesterol and cholesterol.

CONCLUSION

The findings confirm that oxysterols are present in fatty streaks and advanced lesions and may arise from different cholesterol oxidation mechanisms, including free radical-mediated oxidation and enzymatic oxidation.