Balanced diets in food systems: Emerging trends and challenges for human health

ABSTRACT

Processed foods, generally known as modified raw foods produced by innovative processing technologies alters the food constituents such natural enzymes, fatty acids, micronutrients, macronutrients and vitamins. In contrast to fresh and unprocessed foods, processed foods are guaranteed to be safer, imperishable, long lasting and consist high level of nutrients bioactivity. Currently, the evolution in food processing technologies is necessary to face food security and safety, nutrition demand, its availability and also other global challenges in the food system. In this scenario, this review consists of information on two food processing technologies, which effects on processed foods before and after processing and the impact of food products on human health. It is also very well established that understanding the type and structure of foods to be processed can assist food processing industries towards advancement of novel food products. In connection with this fact, the present article also discusses the emerging trends and possible modifications in food processing technologies with the combination of conventional and modern techniques to get the suitable nutritional and safety qualities in food.     

The emergence of gastronomic engineering

Modern consumers increasingly derive their foods from away-from-home sources. Rising incomes, the emergence of chefs as innovative actors in the food scene, and the growing consumer demand for culinary experiences, are the main driving forces behind haute cuisine. At the same time, food engineering is in urgent need to expand its scope and engage in new collaborations and partnerships. Gastronomic engineering (GE) means using the vast body of knowledge accumulated in food engineering and food materials science to propel the curiosity and creativity of chefs to what is technologically feasible and environmentally sustainable. GE opens new opportunities for food engineering, a discipline that has been mostly oriented to the food processing industry. This article describes the emergence of GE or a new branch of food engineering, as a space of co-creation between chefs and food engineers in a university set-up. Our GE unit consists of an experimental kitchen headed by a chef, a food engineering area and a materials science laboratory. The impact of GE on academic activities (teaching and research) and outreach experiences is discussed.     

Formation of furan in baby food products: Identification and technical challenges

Furan is generally produced during thermal processing of various foods including baked, fried, and roasted food items such as cereal products, coffee, canned, and jarred prepared foods as well as in baby foods. Furan is a toxic and carcinogenic compound to humans and may be a vital hazard to infants and babies. Furan could be formed in foods through thermal degradation of carbohydrates, dissociation of amino acids, and oxidation of polyunsaturated fatty acids. The detection of furan in food products is difficult due to its high volatility and low molecular weight. Headspace solid-phase microextraction coupled with gas chromatography/mass spectrometer (GC/MS) is generally used for analysis of furan in food samples. The risk assessment of furan can be characterized using margin of exposure approach (MOE). Conventional strategies including cooking in open vessels, reheating of commercially processed foods with stirring, and physical removal using vacuum treatment have remained unsuccessful for the removal of furan due to the complex production mechanisms and possible precursors of furan. The innovative food-processing technologies such as high-pressure processing (HPP), high-pressure thermal sterilization (HPTS), and Ohmic heating have been adapted for the reduction of furan levels in baby foods. But in recent years, only HPP has gained interest due to successful reduction of furan because of its nonthermal mechanism. HPP-treated baby food products are commercially available from different food companies. This review summarizes the mechanism involved in the formation of furan in foods, its toxicity, and identification in infant foods and presents a solution for limiting its formation, occurrence, and retention using novel strategies.     

低致敏食品制备技术及其工业化应用研究进展

食物过敏是联合国粮农组织和世界卫生组织认定的全球性食品安全问题之一。在食品加工多元化的背景下,食物过敏患者要完全避免过敏原十分困难,研发低致敏食品对食物过敏患者的安全膳食至关重要。总结了低致敏食品制备技术的加工技术原理;以蒸煮、微波和烘烤为主的热加工技术通过加热诱导蛋白质变性的方式破坏致敏性构象性表位;高压、脉冲电场、脉冲光、低温等离子体、辐照和超声等非热加工技术可以通过过敏原蛋白结构修饰、多肽链断裂、新化学键的产生等方式直接破坏致敏性表位;酶水解、酶交联、糖基化、微生物发酵等其他加工方法则通过改变蛋白质构象或将蛋白质与糖类物质结合,破坏或隐藏过敏原致敏性表位。另外,对工业化低致敏蛋白配料的加工方法和生产现状进行了阐述分析。基于酶法水解的部分水解乳蛋白和深度水解乳蛋白已经可以工业化生产,其他消减食物致敏性的方法以及其他低致敏蛋白配料值得进一步研究。希望可以为工业化生产低致敏食品提供参考。     

农药残留加工因子及其在膳食暴露评估中的应用

从初级农产品到入口的食品通常需要各种加工处理,而加工过程会影响食品中的农药残留水平,从而影响来源于初级农产品检测数据的风险评估结果的准确性,因此在风险评估模型中纳入农药残留加工因子有助于真实反映农药残留膳食暴露风险。本文以常用的食品加工技术如清洗、去皮、烹调、榨汁、杀菌及其他相关技术为出发点,综述了典型的加工方式对食品中农药残留的影响以及目前相应的加工因子在农药残留暴露评估中的应用情况,为掌握食品中农药在加工过程中的残留动态、改进食品加工技术提供参考,也为农药残留膳食暴露评估提供依据,进而真实反映人群中农药残留的暴露风险。     

Developments,applications, and trends of molecular gastronomy among food scientists and innovative chefs

Molecular gastronomy (MG) is a relatively new scientific discipline, which focuses on food preparation mainly at domestic and restaurant levels. The number of scientific papers on MG has increased in the past few years. It is, however, difficult to differentiate specifically between the MG discipline or other research areas in food science and technology. Otherwise, molecular cooking, i.e., an application of MG principles, seems limited to a few “fancy” techniques supported by famous chefs. This paper aims to critically review the recent developments of MG, the most interesting applications, and the outcomes obtained from the fruitful collaboration among food scientists and innovative chefs. The controversies and merits associated with MG are also presented, e.g., the principle of food pairing and consumers’ appreciation of innovative dishes, and a few research papers promising exciting future developments.     

Effects of daily food processing on allergenicity

Daily food processing has the potential to alter the allergenicity of foods due to modification of the physico-chemical properties of proteins. The degree of such modifications depends on factors such as processing conditions, type of food considered, allergenic content, etc. The impact of daily food processing like boiling, roasting, frying or baking on food allergenicity have been extensively studied. The influence of other thermal treatments such as microwave heating or pressure cooking on allergenicity has also been analyzed. Non-thermal treatment such as peeling impacts on the allergenic content of certain foods such as fruits. In this review, we give an updated overview of the effects of daily processing treatments on the allergenicity of a wide variety of foods. The different variables that contribute to the modification of food allergenicity due to processing are also reviewed and discussed.     

Non-thermal technologies and its current and future application in the food industry: a review

In recent years, consumers have been demanding convenient and healthy foods which have ‘fresh-like’ characteristics while still being safe and a long shelf-life. These requirements are hard to achieve using existing traditional thermal food processing technologies and the innovative new food process and preservation technologies based on thermal processing systems are needed. However, non-thermal technologies in food processing do not generate high temperature and use short treatment times. This means that the nutritional components of foodstuffs are better retained, and the sensory properties of foods are less changed compared with traditional thermal processing. The aim of this review was to present non-thermal technologies applications and its mechanism in food industry in recently, and to explore the potential application prospects of combining non-thermal treatments applied in food industry because it not only could overcomes the drawback of single technology, but also can enhances the processing efficiency at lower treatment intensity.     

Reduction strategies for polycyclic aromatic hydrocarbons in processed foods

Polycyclic aromatic hydrocarbons (PAHs) are a large group of carcinogenic compounds. PAHs are ubiquitous in the environment and food, thus human beings may be exposed to PAHs through ingestion (water and food), inhalation (air and smoking), and skin contact in daily life. Dietary intake is the major source of exposure to PAHs in humans. Significant and harmful levels of PAHs can be generated during food processing and cooking. Although the formation of PAHs during processing is almost unavoidable, the levels can be diminished with reduction strategies. This review aims to provide comprehensive insights into the mechanisms underlying the formation of PAHs and factors influencing their formation in processed foods. The strategy for the reduction of PAHs including change in ingredients (i.e., reducing fat content), pretreatment conditions (i.e., reducing the pH), processing methods and parameters (i.e., reducing processing temperature and time), and packaging and storage conditions, are discussed. Potential novel strategies for PAH reduction are also identified and the feasibility is evaluated.     

Molecular Dynamics Simulation for Mechanism Elucidation of Food Processing and Safety: State of the Art

Molecular dynamics (MD) simulation is a useful technique to study the interaction between molecules and how they are affected by various processes and processing conditions. This review summarizes the application of MD simulations in food processing and safety, with an emphasis on the effects that emerging nonthermal technologies (for example, high hydrostatic pressure, pulsed electric field) have on the molecular and structural characteristics of foods and biomaterials. The advances and potential projection of MD simulations in the science and engineering aspects of food materials are discussed and focused on research work conducted to study the effects of emerging technologies on food components. It is expected by showing key case studies that it will stir novel developments as a valuable tool to study the effects of emerging food technologies on biomaterials. This review is useful to food researchers and the food industry, as well as researchers and practitioners working on flavor and nutraceutical encapsulations, dietary carbohydrate product developments, modified starches, protein engineering, and other novel food applications.     

Technologies for enhancement of bioactive components and potential health benefits of cereal and cereal-based foods: Research advances and application challenges

Cereal grains are a major source of human food and their production has steadily been increased during the last several decades to meet the demand of our increasing world population. The modernized society and the expansion of the cereal food industry created a need for highly efficient processing technologies, especially flour production. Earlier scientific research efforts have led to the invention of the modern steel roller mill, and the refined flour of wheat has become a basic component in most of cereal-based foods such as breads and pastries because of the unique functionality of wheat protein. On the other hand, epidemiological studies have found that consumption of whole cereal grains was health beneficial. The health benefit of whole cereal grain is attributed to the combined effects of micronutrients, phytochemicals, and dietary fibre, which are mainly located in the outer bran layer and the germ. However, the removal of bran and germ from cereal grains during polishing and milling results in refined flour and food products with lower bioactive compounds and dietary fibre contents than those from whole grain. Also, the level of bioactive compounds in cereal food is influenced by other food preparation procedures such as baking, cooking, extrusion, and puffing. Therefore, food scientists and nutritionists are searching for strategies and processing technologies to enhance the content and bioavailability of nutrients, bioactive compounds, and dietary fibre of cereal foods. The objective of this article was to review the research advances on technologies for the enhancement of bioactive compounds and dietary fibre contents of cereal and cereal-based foods. Bioactivities or biological effects of enhanced cereal and cereal-based foods are presented. Challenges facing the application of the proposed technologies in the food industry are also discussed.     

The fate of mycotoxins during thermal food processing

Mycotoxins are considered to be heat‐stable molecules. Because of their toxic effects, information about their stability in thermal processes and potential inactivation procedures is needed. Numerous reports in the literature over a number of years have described the fate of mycotoxin during thermal food processing, including cooking, boiling, baking, frying, roasting and pasteurization. This review focuses on the effects of various thermal treatments on mycotoxins, while the fate of mycotoxins during extrusion processing, which is one of the most important technologies employed in the food industry, will also be reviewed. Copyright © 2009 Society of Chemical Industry     

The Impact of Cooling Rate on the Safety of Food Products as Affected by Food Containers

In recent decades, the demand for ready‐to‐eat (RTE) food items prepared by the food catering sector has increased together with the value of cook‐serve, cook‐chill, and cook‐freeze food products. The technologies by which foods are cooked, chilled, refrigerated for storage, and reheated before serving are of prime importance to maintain safety. Packaging materials and food containers play an important role in influencing the cooling rate of RTE foods. Food items that are prepared using improper technologies and inappropriate packaging materials may be contaminated with foodborne pathogens. Numerous research studies have shown the impact of deficient cooling technologies on the survival and growth of foodborne pathogens, which may subsequently pose a threat to public health. The operating temperatures and cooling rates of the cooling techniques applied must be appropriate to inhibit the growth of pathogens. Food items must be stored outside the temperature danger zone, which is between 5 and 60 °C, in order to inhibit the growth of these pathogens. The cooling techniques used to prepare potentially hazardous foods, such as cooked meat, rice, and pasta, must be properly applied and controlled to ensure food safety. This paper critically reviews the effects of cooling and its relationship to food containers on the safety of RTE foods produced and sold through the food service industry.     

Effects of processing on mycotoxin stability in cereals

The mycotoxins that generally occur in cereals and other products are not completely destroyed during food‐processing operations and can contaminate finished processed foods. The mycotoxins most usually associated with cereal grains are aflatoxins, ochratoxins, deoxynivalenol, zearalenone and fumonisins. The various food processes that may have effects on mycotoxins include cleaning, milling, brewing, cooking, baking, frying, roasting, flaking, alkaline cooking, nixtamalization, and extrusion. Most of the food processes have variable effects on mycotoxins, with those that utilize high temperatures having the greatest effects. In general, the processes reduce mycotoxin concentrations significantly, but do not eliminate them completely. This review focuses on the effects of various thermal treatments on mycotoxins. © 2014 Society of Chemical Industry     

Nonthermal Food Processing Alternatives and Their Effects on Taste and Flavor Compounds of Beverages

Food drinks are normally processed to increase their shelf-life and facilitate distribution before consumption. Thermal pasteurization is quite efficient in preventing microbial spoilage of many types of beverages, but the applied heat may also cause undesirable biochemical and nutritious changes that may affect sensory attributes of the final product. Alternative methods of pasteurization that do not include direct heat have been investigated in order to obtain products safe for consumption, but with sensory attributes maintained as unchanged as possible. Food scientists interested in nonthermal food preservation technologies have claimed that such methods of preserving foods are equally efficient in microbial inactivation as compared with conventional thermal means of food processing. Researchers in the nonthermal food preservation area also affirm that alternative preservation technologies will not affect, as much as thermal processes, nutritional and sensory attributes of processed foods. This article reviews research in nonthermal food preservation, focusing on effects of processing of food drinks such as fruit juices and dairy products. Analytical techniques used to identify volatile flavor-aroma compounds will be reviewed and comparative effects for both thermal and nonthermal preservation technologies will be discussed.     

新型食品加工技术提升预制菜肴质量与安全

我国预制菜肴历史悠久,种类多样,满足了现代消费者对食品味道、营养、便捷性的需求,近年来发展迅速。从预制菜肴生产加工出发,明确了其内涵和外延,梳理了我国预制菜肴现阶段面临的原料、质量、安全、标准等方面存在的主要问题,并归纳了相关新型食品加工技术的应用趋势。新型预调理与烹饪技术可以实现菜肴色泽、质构、香气、滋味和营养成分的有效提升;新型杀菌技术依靠较低的处理强度,在保障安全性和保持品质之间达到平衡;快速冷却与冷冻技术在提高生产效率的同时对品质的影响最小;智能包装技术、物流智能控制技术的应用实现了预制菜肴流通中的品质稳定。研究总结和展望了提升预制菜肴质量与安全的加工新技术,以期为未来的研究指明方向,为预制菜肴产业的进一步健康发展提供参考。     

食品中重金属脱除技术的最新研究进展

食品重金属污染问题屡见不鲜,重金属在人体内积累后,会严重损害人体的神经系统和肝肾功能。如何去除食品重金属污染,已成为当今世界范围内一个重要的食品安全问题。因此,开发食品中重金属脱除技术对于保障食品安全具有重要意义。常见食品中重金属脱除技术根据原理可分为物理处理法、化学浸提法、微生物法和吸附法等。近年来,食品中重金属脱除技术发展较快,尤其是在吸附法中出现了很多高效、绿色和选择性高的吸附材料。本文总结了食品中各类重金属脱除技术,重点介绍各种技术的研究新进展以及其优缺点,为食品中重金属污染物的脱除提供基础参考,同时有助于促进脱除技术的新发展,并为保障食品安全提供新思路。     

Dietary oxidised lipids,health consequences and novel food technologies that thwart food lipid oxidation: an update

Processed foods are popular and their consumption is expected to grow globally. Food processing and manufacturing promote lipid oxidation in foods rich in polyunsaturated fatty acids and cholesterol. This review focuses on how various food manufacturing/processing techniques promote lipid oxidation in grains, meats and meat products, dairy and fats/oils. This review also considers emerging evidence from animal and human studies that suggest a link between dietary oxidised lipid consumption and chronic disease risk. An update on novel food technologies that limit food lipid oxidation is discussed so as to inform both food scientists and dietitians/nutritionists to direct future efforts in not only continuing to bring these novel technologies to the market place but also conduct clinical trials to establish their role in human health.     

Processing Strategies to Inactivate Hepatitis A Virus in Food Products: A Critical Review

Hepatitis A infection, caused by hepatitis A virus (HAV), is the leading cause of human viral hepatitis throughout the world and is mainly propagated via the fecal–oral route. Transnational outbreaks of food‐borne infections are reported with increasing frequency as a consequence of international food trade. Food‐borne outbreaks caused by HAV are mainly associated with bivalve molluscs, produce (soft fruits and leafy greens), and ready‐to‐eat meals. The purpose of this paper was to conduct a structured and systematic review of the published literature on the current state of knowledge regarding the stability of HAV in foods as well as the efficacy of food processing strategies and to identify and prioritize research gaps regarding practical and effective mechanisms to reduce HAV contamination of foods. In particular, processing and disinfection strategies for the 3 food categories have been compiled in this review, including common and emerging food technologies. Overall, most of these processes can improve food safety; however, from a commercial point of view, none of the methods can guarantee total HAV inactivation without affecting the organoleptic qualities of the food product.