Acrylamide and 5-hydroxymethylfurfural in thermally treated non-wheat flours and respective breads.

This is the first report about the influence of dry and wet heat treatment on acrylamide content in flours and, subsequently, in breads. It was shown that during production of some breads acrylamide content decreases. Dry heating of non-wheat flour resulted in acrylamide in flours of sorghum (160 µg/kg); millet (447 µg/kg); barley (516 µg/kg); triticale (868 µg/kg); rye (1833 µg/kg); oat (1951 µg/kg). Hydrothermal heating had a negligible impact on acrylamide formation. In breads made from flour blends consisted of 70% of dry thermally and 30% of hydrothermally treated flours of millet, sorghum, oat, and rye, respectively, acrylamide was detected in the range from 105 to 312 µg/kg. 5-hydroxymethylfurfural probably contributing to acrylamide formation in bread was detected in the range from 2.0 mg/kg to 44.3 mg/kg in dry heated flours; in hydrothermally treated flours was below LOQ (1.7 mg/kg); in breads was between 3.3 and 8.0 mg/kg.

Why is sea buckthorn (Hippophae rhamnoides L.) so exceptional? A review.

Sea buckthorn (Hippophae L.) is a valuable, multipurpose plant extensively grown in Asia, Europe and Canada. In order to use it in the best way for products of human nutrition, it is necessary to recognize its positive aspects and to eliminate the negative ones. The exceptional value of sea buckthorn can be seen in the presence of both lipophilic antioxidants (mainly carotenoids and tocopherols) and hydrophilic antioxidants (flavonoids, tannins, phenolic acids, ascorbic acid) in remarkably high quantities. Some of the main nutrients, especially lipids of advantageous fatty acid composition, contribute to nutritional benefits of sea buckthorn products for a consumer as well. This review article focuses, besides the above mentioned compounds and vitamins, also on other important components, such as sugars, sugar derivatives, fibre, organic acids, proteins, amino acids and mineral elements. The article also deals with the effects of sea buckthorn components on the course of non-enzymatic browning of food and in vivo glycation. In addition, sensory perception of sea buckthorn and its constituents from the consumers point of view is discussed.

Modelling Contaminant Formation during Thermal Processing of Sea Buckthorn Purée.

Background: The impact of thermal treatment on acrylamide (ACR) and hydroxymethylfurfural (HMF) formation was investigated for thermally treated sea buckthorn purée. Methods: An optimized procedure for minimizing ACR and HMF formation in thermally treated sea buckthorn purée was described. The precursors of ACR and HMF and their impact in heating of sea buckthorn purée to obtain jam-like products were also evaluated. Results: The contaminant content formed in samples was analyzed on thirteen running variants using a temperature range of 59.3-200.7 °C, and for heating durations between 5.9 and 34.1 min. The calculated equations of contaminant formation in sea buckthorn purée have established that the minimum content is formed at the lowest exposure time, between 10 and 20 min, for both ACR and HMF. The lowest ACR content was attained at 5.9-min exposure time and 130 °C temperature (0.3 µg/kg). For HMF the results revealed a lower quantity at 59.3 °C for 20-min exposure time (1.4 mg/kg). Conclusions: the found model is useful for the prediction of the best temperature/time conditions of the thermal treatment to obtain the lowest contaminates levels in the final product.

Antioxidative Capacity of and Contaminant Concentrations in Processed Plum Products Consumed in Romania.

The bioactive compounds (total phenols, anthocyanins, and flavonoids) and antioxidant activity of plum-based products (prunes, jams, and marmalade) were evaluated based on spectrophotometric assays and acrylamide and 5-hydroxymethyl-2-furaldehyde concentrations to determine the quality and safety of these products in the Romanian marketplace. The total polyphenol concentrations in prunes, marmalade, and jams were 0.93 to 5.63 g of gallic acid equivalent per kg of dry matter, and the antioxidant activity was 3.0 to 17.2 mmol/kg. The concentrations of potentially harmful acrylamide in the plum products ranged from the limit of quantitation (<20 µg/kg) to 37.44 µg/kg, and the concentration was higher in prunes (26.66 to 163.72 µg/kg) than in jams. The 5-hydroxymethyl-2-furaldehyde concentrations in plum products were also variable, at 36 to 2,149 mg/kg. These data revealed a very low concentration of acrylamide in thermally processed plum products, and the results for total polyphenols and the antioxidant activity of prunes and plum jams may be relevant for evaluating these products as important sources of bioactive compounds.