Phytosterol oxidation products in enriched foods: Occurrence, exposure, and biological effects

Scholz, Birgit; Guth, Sabine; Engel, Karl‐Heinz; Steinberg, Pablo

doi:10.1002/mnfr.201400922

Cited by 63 publications

(55 citation statements)

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“…The contents of total phytosterols reported in bread range from 40.5 mg/100 g dry weight (white bread) to 80.3 mg/100 g dry weight (rye bread made from rye and wheat flour) and 90.2 mg/100 g dry weight (rye bread made only from rye flour) (Piironen et al, 2002). Assuming that the maximum oxidation rate for phytosterols upon UV treatment is in the same order of magnitude as the maximum oxidation rate (1 %) reported for phytosterols following thermal processing (Scholz et al, 2015), phytosterol oxidation products expected in bread as a result of the UV treatment would amount to, approximately, 0.4-0.9 mg/100 g dry weight. Taking into account the short time of the UV treatment and the fact that UV-induced oxidations would occur in only the outer layer of the bread, the formation of phytosterol oxidation products is not considered to be of relevance.…”

Section: Effect Of the Uv Treatment On Bread Constituents And Potentimentioning

confidence: 88%

Scientific Opinion on the safety of UV‐treated bread as a novel food EFSA Panel on Dietetic Products, Nutrition and Allergies

Products¹

2015

EFS2

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Following a request from the European Commission, the EFSA Panel on Dietetic Products, Nutrition and Allergies (NDA Panel) was asked to carry out the additional assessment for UV-treated bread as a novel food (NF) in the context of Regulation (EC) No 258/97, taking into account the comments and objections of a scientific nature raised by Member States. The NF is bread to which a treatment with UV radiation is applied after baking in order to convert ergosterol, which is present in bread as a result of yeast fermentation, to vitamin D 2 . The provided compositional data, the specifications (i.e. vitamin D 2 content of 0.75-3 μg/100 g in the UV-treated bread, 1-5 g/100 g of yeast in the dough) and the data from batch testing do not give rise to safety concerns. The data provided on the production process are sufficient and do not give rise to safety concerns. The Panel considers that even if it is conservatively assumed that all consumed breads are UV-treated and contain the maximum proposed amount of 3 µg vitamin D 2 /100 g, it is highly unlikely that tolerable upper intake levels for vitamin D, established by EFSA for various age groups, will be exceeded. The NF is not nutritionally disadvantageous. Under certain conditions, UV treatment may result in reactions of biomolecules. However, the levels of potential reaction products that may be formed under the employed conditions are low compared with the reactions induced by the baking process. Therefore, the Panel considers that it is not necessary to perform additional analyses and that the absence of toxicological studies with the novel food is acceptable. The risk of allergic reactions to the NF is not dissimilar to that associated with conventional bread. The Panel considers that bread enriched with vitamin D 2 through UV treatment is safe under the conditions of use as specified by the applicant. The NF is bread to which a treatment with UV radiation is applied after baking in order to convert ergosterol, which is present in bread as a result of yeast fermentation, to vitamin D 2 (ergocalciferol). Specifications of the NF include the intended vitamin D 2 content (0.75-3 μg/100 g) in the UV-treated bread and the amount of yeast (1-5 g/100 g) required in the dough in order to achieve the amount of vitamin D 2 . © EuropeanThe applicant provided compositional data on macro-and micronutrients in various types of bread subjected to the UV treatment at pilot and commercial scale. The UV-treated breads contained significant amounts of vitamin D 2 , while the contents in the control breads were below the limit of detection. The contents of water, protein, fat, carbohydrate, fibre, different groups of fatty acids, vitamin E and B vitamins in the UV-treated breads were comparable to those in the control breads. The UV treatment results in the formation of vitamin D 2 in only a thin outer layer (i.e. crust, 2-3 mm) of the bread. Peroxide values and folate contents in crust and crumb following UV treatment were comparable to those determined in the control. The Pa...

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Section: Effect Of the Uv Treatment On Bread Constituents And Potentimentioning

confidence: 88%

Scientific Opinion on the safety of UV‐treated bread as a novel food EFSA Panel on Dietetic Products, Nutrition and Allergies

Products¹

2015

EFS2

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“…These photooxidation products were similar to the oxidation products produced by phytosterol autoxidation. Phytosterol oxidation products (POPs) were considered a potential risk to human health, but no experimental results clearly support this view . Ergosterol is the major sterol distributed in higher fungi, with two double bonds within the sterol ring structure instead of one.…”

Section: Photoreaction Of Phytochemicalsmentioning

confidence: 99%

Photooxidation of phytochemicals in food and control: a review

Zhao

2017

Annals of the New York Academy of Sciences

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Phytochemicals are widely present in food and have been confirmed to be bioactive, thereby contributing to human health. However, some phytochemicals are sensitive to light owing to their structures and may suffer from photodegradation, especially when sensitizers exist, resulting in sensory quality change, nutrient loss in food, and even the formation of toxic compounds. The photooxidation of phytochemicals occurs through three different mechanisms: (1) by directly absorbing luminous energy, (2) with triplet-excited state sensitizers through electron transfer or proton transfer (type I photooxidation), and (3) with singlet oxygen produced by O (type II photooxidation). On the basis of these mechanisms, adequate antioxidants can be added to quench the triple-excited state sensitizers or singlet oxygen to protect against the photooxidation of phytochemicals in food. Here, we summarize and discuss the possible pathways and products of the photooxidation of phytochemicals that have been reported and the relationships between structures and photooxidation. We also propose some control measures, with special attention paid to the potential abilities of phytochemicals in the prevention of food photooxidation.

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“…Oxidation of phytosterols and their fatty acid esters through multiple reactions leads to primary (hydroperoxides), secondary (polar: ketones, epoxides, alcohols; nonpolar: dienes, trienes) and tertiary (dimers, oligomers, polymers) oxidation products. Most research has focused on primary and secondary polar compounds (García-Llatas and Rodríguez-Estrada, 2011;Scholz et al, 2015). However, the most abundant from oxides, formed during sterol degradation at elevated temperatures, are dimers, which are bound mostly by ether (C-O-C) or peroxy (C-O-O-C) linkages (Sosińska et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Cytotoxic activity of stigmasteryl esters and products of their thermo-oxidative degradation against drug sensitive and drug resistant human acute lymphoblastic leukemia cells

Raczyk

Paszel-Jaworska

Rudzińska

2018

Acta Sci Pol Technol Aliment

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Background. Phytosterols are mainly known as a cholesterol-lowering factor, although they form oxidation products during food storage and processing. Moreover, phytosterol oxidation products (POP) can be absorbed and found in human serum, so there is the need to investigate their impact on different kinds of cells. Material and methods. Esters of fatty acids (oleic, linoleic and linolenic) with stigmasterol were synthetized and heated at 180°C, for 1-12 hours. The cytotoxic effect on the leukemic cells of unheated stigmasteryl esters and the mixture of compounds after heating was determined using MTT assays. POP were identified using GC-MS. The total number of POP was analysed by SPE fractionation and GC-FID separation. Dimers, trimers and oligomers in non-polar fraction were determined by gel permeation chromatography with refractive index detection. Results. After heating, stigmasterol oxidation products were formed (up to 1.1 mg/g ester). The heating increased the potency of the compounds to reduce cell population and form POPs and oligomers in a timedependent manner. Conclusion. The cytotoxicity depends on the kind of ester, dose and time. The strongest cytotoxic effect was found after 72 hours of cell treatment. Among the three stigmasteryl esters tested the most cytotoxic effect was caused by stigmasteryl linoleate.

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Phytosterol oxidation products in enriched foods: Occurrence, exposure, and biological effects

Cited by 63 publications

References 103 publications

Scientific Opinion on the safety of UV‐treated bread as a novel food EFSA Panel on Dietetic Products, Nutrition and Allergies

Scientific Opinion on the safety of UV‐treated bread as a novel food EFSA Panel on Dietetic Products, Nutrition and Allergies

Photooxidation of phytochemicals in food and control: a review

Cytotoxic activity of stigmasteryl esters and products of their thermo-oxidative degradation against drug sensitive and drug resistant human acute lymphoblastic leukemia cells

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