Abstract
Cholesterol oxidation products (COPs) have greater biological activity than cholesterol itself. Oxysterols reduce the nutritional value of foods and exhibit a wide range of biological activity, including pro-oxidant, carcinogenic, and cytotoxic properties. The most commonly detected oxysterols in foods are 7α-HC, 7β-HC, a product of their dehydrogenation 7-KC and α-CE, β-CE. The main dietary sources of oxysterols are eggs and egg-derived products, thermally processed milk and milk-based products, fried meat. This study aimed to measure the amount of cholesterol oxidation products in milk powder, egg powder and milk–egg powder during 24 months of storage. The changes in the selected oxysterols (determined by gas chromatography) were recorded. In milk powder, after the production process, the amount of cholesterol was 0.2 g 100 g−1 fat and in egg powder it was 3.4 g 100 g−1. After 6 months of storage, the dominant oxysterol in milk and egg powder was 7α-HC and in milk–egg powder it was 7-KC. After the storage period, oxysterols in powdered milk reached 1.81% of total cholesterol. The most stable cholesterol was in the milk–egg mixture and its oxidation was the slowest. This study showed the presence of COPs in milk powder, egg powder and milk–egg powder and the effect of storage on cholesterol oxidation.
Highlights
Cholesterol oxidation products (COPs) have greater biological activity than cholesterol itself
Autoxidation of cholesterol leads to the formation of hydroperoxides and the various cholesterol oxidation products (COPs)
Numerous studies have shown that oxidation products (COPs) in foods can reach 1% of total cholesterol and occasionally 10% or m ore[1]
Summary
Cholesterol oxidation products (COPs) have greater biological activity than cholesterol itself. This study aimed to measure the amount of cholesterol oxidation products in milk powder, egg powder and milk–egg powder during 24 months of storage. This study showed the presence of COPs in milk powder, egg powder and milk–egg powder and the effect of storage on cholesterol oxidation. Deprotonation of the carbon atom at position 7 by the attack of a reactive oxygen species promotes the formation of cholesterol oxidation products, including 7α and 7β-hydroperoxides (the most representative ones in the oxysterols’ family). Their degradation products include 7α-hydroxycholesterol (7α-HC), 7β-hydroxycholesterol (7β-HC) and 7-ketocholesterol (7-KC), which can be formed from 7 (α, β)-HC. According to Zmysłowski and Szterk[11] oxysterols have the property of causing the formation of atherosclerosis and accelerating its progression
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