Mitigation of Acrylamide Content in Biscuits through Combined Physical and Chemical Strategies

Potential of Hyperthermophilic L-Asparaginase from Thermococcus sibiricus to Mitigate Dietary Acrylamide Assessed Using a Simplified Food System

The Maillard reaction is a network of interconnected interactions yielding in formation a number of toxic derivatives in processed foods. Acrylamide, a potential carcinogen and a product of the Maillard reaction, is formed under food processing, predominantly from asparagine and reducing sugars at temperatures over 120 °C. In this study, we investigated the potency of recombinant hyperthermophilic L-asparaginase from Thermococcus sibiricus TsAI to mitigate dietary acrylamide by hydrolyzing substrate for its synthesis under various operation conditions. Using a simplified food system for self-cooking, high acrylamide levels were found in baked samples regardless of whether L- or D-enantiomer of asparagine was added. TsAI effectively reduced acrylamide content under various pretreatment conditions, such as temperature, concentration, and time of incubation. The lowest acrylamide level of 1.0-1.1% of the control values or 3.52-3.76 µg/kg was observed in samples pretreated with TsAI 20 U/mL at 90 °C for 20-25 min. Due to the exceptionally high D-asparaginase activity of hyperthermophilic TsAI, the dietary acrylamide content formed from D-asparagine was reduced by 54.8% compared to the control. Comparison of the wild-type TsAI and its mutant reveal that an enzyme displaying enhanced stability is more functional for food-processing application. The native TsAI decreased acrylamide level by 98.9%, while the highly active mutant, with increased structural flexibility, decreased it by only 26.8%. TsAI treatment effectively blocked acrylamide synthesis, but not melanoidin formation via the Maillard reaction, thus not affecting sample characteristics such as color (browning) and aroma, which are important for consumer perception.

Strategies to reduce neurotoxic acrylamide in biscuits, a systematic review

In this systematic review, considering the wide consumption of biscuits, the research that has been designed so far to reduce acrylamide in biscuits is discussed. Some methods were the use of antioxidants, some food additives, optimization of baking methods, suppression of acrolein production, and suppression of Maillard reaction. The advantages and disadvantages of each of these methods are discussed in this systematic review. The most important possible mechanism in the formation of acrylamide is the Maillard reaction.The greatest influence of the intervention effects was seen in the studies in which the Maillard reaction was suppressed. In some studies, this efficiency was observed above 90 %. It has also been observed in some studies that acrylamide is significantly reduced by using some antioxidants in the biscuit formulation. In this condition, a decrease in the amount of acrylamide was observed in the range of 50-90 % depending on the type of antioxidant. In this regard, the greatest reduction effect was reported with the use of tropical fruits and bamboo leaves in the formulation of biscuits.

Food process contaminants: formation, occurrence, risk assessment and mitigation strategies - a review

Thermal treatment of food can lead to the formation of potentially harmful chemicals, known as process contaminants. These are adventitious contaminants that are formed in food during processing and preparation. Various food processing techniques, such as heating, drying, grilling, and fermentation, can generate hazardous chemicals such as acrylamide (AA), advanced glycation end products (AGEs), heterocyclic aromatic amines (HAAs), furan, polycyclic aromatic hydrocarbons (PAHs), N-nitroso compounds (NOCs), monochloropropane diols (MCPD) and their esters (MCPDE) which can be detrimental to human health. Despite efforts to prevent the formation of these compounds during processing, eliminating them is often challenging due to their unknown formation mechanisms. It is critical to identify the potential harm to human health in processed food and understand the mechanisms by which harmful compounds form during processing, as prolonged exposure to these toxic compounds can lead to health problems. Various mitigation strategies, such as the use of diverse pre- and post-processing treatments, product reformulation, additives, variable process conditions, and novel integrated processing techniques, have been proposed to control these food hazards. In this review, we summarize the formation and occurrence, the potential for harm to human health produced by process contaminants in food, and potential mitigation strategies to minimize their impact.

Effect of Bioactive Compounds from Pumpkin Powder on the Quality and Textural Properties of Shortbread Cookies

The problem of food with functional ingredients, characterized by low energy intake and a variety of phytonutrients with biological activity, is one of the concerns of the population. The objectives of this study were to investigate the effect of pumpkin powder and its bioactive components on the quality, color and textural properties of shortbread cookies. In the drying process of pumpkin powder (Cucurbita moschata) at 60 ± 2 °C, the physicochemical parameters did not change significantly in relation to fresh pulp. The chromatic parameters L*, a* and b* showed that the pumpkin powder was brighter than the pulp, with a greater presence of yellow pigments. Pumpkin powder presented a rich source of bioactive compounds (polyphenols flavonoids, carotenoids) with an antioxidant potential of 161.52 mmol TE/100 g DW and 558.71 mg GAE/100 g DW. Antimicrobial activity against Gram-positive (Staphylococcus aureus, Bacillus cereus), Gram-negative (Escherichia coli, Salmonella Abony and Pseudomonas aeruginosa) bacteria and high antifungal activity against Candida albicans were attested. The sensory, physicochemical, texture parameters and color indicators of shortbread cookies with yellow pumpkin powder (YPP) added in a proportion of 5-20% were analyzed. The optimal score was given to the sample of 15% YPP. The use of 15-20% YPP contributed to improved consistency due to the formation of complexes between starch and protein.

Formulation and Processing Strategies to Reduce Acrylamide in Thermally Processed Cereal-Based Foods

Acrylamide, a thermal process contaminant, is generated in carbohydrate-rich foods processed at high temperatures (above 120 °C). Since acrylamide indicates a human health concern, the acrylamide contents of various foods and the dietary exposure of the population to acrylamide are very well investigated. Commonly consumed foods in the daily diet of individuals such as bakery products, potato products and coffee are major dietary sources of acrylamide. In recent years, dietary exposure levels of the population and mitigation measures for reducing acrylamide in different food products have gained importance to decrease the public's exposure to acrylamide. Since the complete elimination of acrylamide in foods is not possible, various mitigation measures to reduce acrylamide to levels as low as reasonably achievable have been developed and applied in the food industry. Mitigation strategies should be applied according to the different product categories during agricultural production, formulation, processing and final consumer preparation stages. The aim of this review is to evaluate formulation and processing strategies to reduce acrylamide in various cereal-based food products and to discuss the applicability of mitigation measures in the food industry by taking into consideration the organoleptic properties, nutritional value, cost and regulations in the light of current knowledge.

Influence of baking and frying conditions on acrylamide formation in various prepared bakery, snack, and fried products

The core objective of the present study was to evaluate the influence of baking/frying times and temperatures on the formation of acrylamide in bakery, snack, and fried products such as biscuits, muffins, pizza, cakes, samosa, paratha rolls, nuggets, and potato cutlets during baking/frying at different times and temperature conditions. First of all, the raw material, especially flour, was tested for its proximate composition and rheological characteristics. The quantification of acrylamide produced during the processing of different products was carried out through the HPLC method. A sensory evaluation of these food samples was also carried out to find out the acceptability differences. The raw material was found to have good rheological properties and proximate composition. The results revealed that different times and temperature regimes influenced the formation of acrylamide in those products. Among the bakery products, the highest concentrations of acrylamide were observed in biscuits (126.52 μg/kg) followed by muffins (84.24 μg/kg), cake (71.21 μg/kg), and pizza (62.42 μg/kg). The higher contents of acrylamide were found in paratha roll (165.92 μg/kg) compared to samosa (100.43 μg/kg), whereas among snacks, potato cutlets (135.71 μg/kg) showed higher concentrations than nuggets (43.04 μg/kg). It was observed that baking or frying all the investigated products at higher temperatures produced slightly more acrylamide concentrations. The prepared products in the present study were also accepted sensorially by the panel of judges. So, it was concluded that baking or frying at higher temperatures resulted in higher concentrations of acrylamide compounds in different products in the present study.