Current status of emerging food processing technologies in Latin America: Novel non-thermal processing

Non-thermal emerging technologies in the sector of food processing have often been cited by researchers as an alternative to conventionally heat treatments for food processing in order to develop safe foods with minimal damage to nutritional and sensory properties. Non-thermal emerging technologies for foods processing have been widely developed in Europe and U.S.A. However, the interest in these technologies and commercialisation opportunities started catching up in Latin America. Thus, this review describes the basic principles and main effect of this technologies in the food and the recent scientific reports on its applications and potential advantages of the so-called non-thermal emerging technologies like ultrasound, high hydrostatic pressure, pulsed electric field, ionising radiation and atmospheric cold plasma, as alternative food preservation process. This review focuses on the current status in Latin America of novel non-thermal food processing technologies, highlighting the limits for scaling up to industrial level in order to be commercially successful.     

Emerging forward osmosis and membrane distillation for liquid food concentration: A review

As emerging membrane technologies, forward osmosis (FO) and membrane distillation (MD), which work with novel driving forces, show great potential for liquid food concentration, owing to their low fouling propensity and great driving force. In the last decades, they have attracted the attention of food industry scientists in global scope. However, discussions of the FO and MD in liquid food concentration advancement, membrane fouling, and economic assessment have been scant. This review aims to provide an up-to-date knowledge about liquid food concentration by FO and MD. First, we introduce the principle and applications of FO and MD in liquid food concentration, and highlight the effect of process on liquid food composition, membrane fouling mechanism, and strategies for fouling mitigation. Besides, economic assessment of FO and MD processes is reviewed. Moreover, the challenges as well as future prospects of FO and MD applied in liquid food concentration are proposed and discussed. Comparing with conventional membrane-based or thermal-based technologies, FO and MD show outstanding advantages in high concentration rate, good concentrate quality, low fouling propensity, and low cost. Future efforts for liquid food concentration by FO and MD include (1) development of novel FO draw solution (DS); (2) understanding the effects of liquid food complex compositions on membrane fouling in FO and MD concentration process; and (3) fabrication of novel membranes and innovation of membrane module and process configuration for liquid food processing.     

Principles and recent applications of novel non-thermal processing technologies for the fish industry—a review

Thermal treatment is a traditional method for food processing, which can kill microorganisms but also lead to physicochemical and sensory quality damage, especially to temperature-sensitive foods. Nowadays consumers’ increasing interest in microbial safety products with premium appearance, flavor, great nutritional value and extended shelf-life has promoted the development of emerging non-thermal food processing technologies as alternative or substitution to traditional thermal methods. Fish is an important and world-favored food but has a short shelf-life due to its extremely perishable characteristic, and the microbial spoilage and oxidative process happen rapidly just from the moment of capture, making it dependent heavily on post-harvest preservation. The applications of novel non-thermal food processing technologies, including high pressure processing (HPP), ultrasound (US), pulsed electric fields (PEF), pulsed light (PL), cold plasma (CP) and ozone can extend the shelf-life by microbial inactivation and also keep good sensory quality attributes of fish, which is of high interest for the fish industry. This review presents the principles, developments of emerging non-thermal food processing technologies, and also their applications in fish industry, with the main focus on microbial inactivation and sensory quality. The promising results showed great potential to keep microbial safety while maintaining organoleptic attributes of fish products. What’s more, the strengths and weaknesses of these technologies are also discussed. The combination of different food processing technologies or with advanced packaging methods can improve antimicrobial efficacy while not significantly affect other quality properties under optimized treatment.     

Application of emerging technologies to control Salmonella in foods: A review

Salmonella is one of the major causes of foodborne illnesses in United States and many other parts of the world. The ubiquitous nature of the organisms and innumerous serotypes present in various foods make it challenging for researchers to strive for its elimination. In the past decade, various novel technologies have emerged with great potential to inactivate Salmonella and other foodborne pathogens. This review paper aims to compile research works reported in the recent past with emphasis on the use of emerging technologies such as, ozone, ultraviolet light, ultrasound, electrolyzed oxidized water, high pressure carbon dioxide, and bacteriophage. Other novel technologies like high pressure processing, pulsed electric field processing and irradiation were not covered considering their vastness of literature and availability of published reviews. Many of these emerging technologies have already reached commercial adoption in specific applications and many others are very promising. Development of suitable equipment, especially to make continuous processing feasible for a variety of foods and standardizing the process parameters for easy regulatory approval will pave the way for improved food quality and safety.     

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.     

The application of internal grading system technologies for agricultural products – Review

Quality assessment of agricultural products has been the subject of numerous reviews; however, not many papers address internal visualization as a means of quality grading. This paper reviews established as well as emerging visualization techniques utilized in the quality assessment of food products. In this discourse, the authors set out to underscore some of the most novel signal processing techniques employed in the non-destructive grading of agricultural products by way of an automated quality verification system. Such systems utilize advanced engineering principles with imaging, signal processing as well as color differentiation to accomplish the grading task. The materials presented will be useful to agricultural engineers, manufacturing engineers, food engineers and any other researchers in the food and agriculture industries.     

Emerging food processing technologies and factors impacting their industrial adoption

Abstract

Innovative food processing technologies have been widely investigated in food processing research in recent years. These technologies offer key advantages for advancing the preservation and quality of conventional foods, for combatting the growing challenges posed by globalization, increased competitive pressures and diverse consumer demands. However, there is a need to increase the level of adoption of novel technologies to ensure the potential benefits of these technologies are exploited more by the food industry. This review outlines emerging thermal and non-thermal food processing technologies with regard to their mechanisms, applications and commercial aspects. The level of adoption of novel food processing technologies by the food industry is outlined and the factors that impact their industrial adoption are discussed. At an industry level, the technological capabilities of individual companies, their size, market share as well as their absorptive capacity impact adoption of a novel technology. Characteristics of the technology itself such as costs involved in its development and commercialization, associated risks and relative advantage, and level of complexity and compatibility influence the technology's adoption. The review concludes that a deep understanding of the development and application of a technology along with the factors influencing its acceptance are critical to ensure its commercial adoption.     

The renaissance of yeasts as microbial factories in the modern age of biomanufacturing

Yeasts are essential for many processes, including the production of some of our most beloved foods and beverages. Less is known to the public about the far-reaching impacts of yeasts on other products such as biofuels, pharmaceuticals, and industrial products. By leveraging and combining newly discovered yeast genetic diversity with now affordable and efficient genetic engineering and synthetic biology tools, academic and industrial yeast labs have designed yeast cell factories for a wide range of novel applications such as the production of medicines, components of human breast milk, heme for meat substitutes, bioplastics, and other biomaterials. This review covers the newest technologies developed for yeast research including synthetic biology and their use in the engineering of yeast cell factories for emerging applications.     

基于分子动力学模拟研究淀粉与脂质和蛋白质的相互作用：现状分析与未来趋势

淀粉、脂质和蛋白质在热加工中的相互作用会显著影响最终食品的风味、口感、质构、营养特性以及货架期,近年来受到了学术界和工业界的广泛关注。理解淀粉与其他组分在加工过程中的相互作用机制对于食品加工过程品质控制具有重要的理论意义。分子动力学模拟作为一种重要的理论计算分析手段,对于深入揭示淀粉与其他食品组分之间的相互作用机制起着至关重要的辅助作用,近年来引起了人们的广泛关注。作者在简要介绍了淀粉-脂质及淀粉-脂质-蛋白质复合物的形成及结构的基础上,系统综述了分子动力学模拟技术的基本原理、概念和操作流程及其在研究淀粉与脂质和蛋白质相互作用中的应用方面的最新进展,并对未来的发展趋势进行了展望。     

新型热和非热食品加工技术的研究进展及影响其工业应用的因素

近年来,新型食品加工技术在食品加工领域的广泛研究应用,为推进传统食品保存,缓解因消费者需求多样化所带来的压力提供了有力保障。本文简述了新型热和非热食品加工技术的机制、工业应用和商业价值,概述并讨论新型食品加工技术的研究进展和影响其工业应用的因素。从生产水平上看,公司的技术、规模、市场份额和资金吸纳能力会影响新型技术在工业上的应用。从技术层面看,新型技术本身的特征,如技术开发的成本,相关风险和相对优势等也会影响新型加工技术的普及。因此本文深入分析新型热和非热食品加工技术的开发、应用以及影响其接受度的因素,这对新型热和非热食品加工技术的商业化利用至关重要。     

Dairy foods and novel thermal and non-thermal processing: A bibliometric analysis

Processing dairy products by conventional methods, such as pasteurization, can induce chemical reactions and physicochemical alterations, compromising nutritional and sensory quality. Thus, there is a growing worldwide demand for studies related to emerging processing technologies. This study aims to describe trends related to dairy processing through the application of emerging technologies. In this sense, articles published in this area of research in the last decade were retrieved from scientific databases, and their findings were analyzed through a bibliometric study. Reviews and original articles expressed 40 and 60% of publications, respectively, and novel thermal and non-thermal processing studies showed multidisciplinary approaches. Ohmic heating and microwave heating were the most discussed novel thermal technologies in the processing of dairy products. Among non-thermal technologies, there was a more significant trend in studies on ultrasound, high hydrostatic pressure, and pulsed electric fields. The impact of the application of novel food technologies concerning quality, safety, and energy efficiency compared to traditional methods and the influence of critical operating conditions for process control were the most studied areas. Furthermore, the impact of novel non-thermal food processing technologies from the consumer's point of view is emerging. These results can be used for future innovations by the dairy industry.Industrial relevanceDairy foods are important food matrices considering a nutritional and functional point of view and recommended in a regular diet for consumers of all ages. Therefore, a bibliometric analysis was performed considering dairy foods and novel thermal and non-thermal processing. A higher number of publications considering non-thermal technologies was reported, highlighting the need for food processing without applying high temperatures. High hydrostatic pressure, ultrasonication, and pulsed electric fields were the most discussed non-thermal technologies. At the same time, ohmic heating and microwave heating were the most reported thermal technologies. Furthermore, the most used applications, critical process parameters, and food properties to be evaluated are highlighted and discussed. The results could be used as a basis for the dairy processors to implement non-conventional technologies as an option at their production lines, as they demonstrate the most relevant process parameters and food characteristics to be evaluated, helping them to choose the parameters with higher impact and firstly consider them. Furthermore, consumers studies are important and should evaluate consumer perception about the products and the perceived benefits and risks of the novel technologies.     

Relating Food Engineering to Cooking and Gastronomy

Modern consumers are increasingly eating meals away from home and are concerned about food quality, taste, and health aspects. Food engineering (FE) has traditionally been associated with the industrial processing of foods; however, most underlying phenomena related to FE also take place in the kitchen during meal preparation. Although chemists have positively interacted with acclaimed chefs and physicists have used foods as materials to demonstrate some of their theories, this has not been always the case with food engineers. This review addresses areas that may broaden the vision of FE by interfacing with cooking and gastronomy. Examples are presented where food materials science may shed light on otherwise empirical gastronomic formulations and cooking techniques. A review of contributions in modeling of food processing reveals that they can also be adapted to events going on in pots and ovens, and that results can be made available in simple terms to cooks. Industrial technologies, traditional and emerging, may be adapted to expand the collection of culinary transformations, while novel equipment, digital technologies, and laboratory instruments are equipping the 21st‐century kitchens. FE should become a part of food innovation and entrepreneurship now being led by chefs. Finally, it is suggested that food engineers become integrated into gastronomy's concerns about safety, sustainability, nutrition, and a better food use.     

Cold Plasma‐Mediated Treatments for Shelf Life Extension of Fresh Produce: A Review of Recent Research Developments

Fresh produce, like fruits and vegetables, are important sources of nutrients and health‐promoting compounds. However, incidences of foodborne outbreaks associated with fresh produce often occur; it is thus important to develop and expand decay‐control technologies that can not only maintain the quality but can also control the biological hazards in postharvest, processing, and storage to extend their shelf life. It is under such a situation that plasma‐mediated treatments have been developed as a novel nonthermal processing tool, offering many advantages and attracting much interest from researchers and the food industry. This review summarizes recent developments of cold plasma technology and associated activated water for shelf life extension of fresh produce. An overview of plasma generation and its physical–chemical properties as well as methods for improving plasma efficiency are first presented. Details of using the technology as a nonthermal agent in inhibiting spoilage and pathogenic microorganisms, inactivating enzymes, and modifying the barrier properties or imparting specific functionalities of packaging materials to extend shelf life of food produce are then reviewed, and the effects of cold plasma‐mediated treatment on microstructure and quality attributes of fresh produce are discussed. Future prospects and research gaps of cold plasma are finally elucidated. The review shows that atmospheric plasma‐mediated treatments in various gas mixtures can significantly inhibit microorganisms, inactive enzyme, and modify packaging materials, leading to shelf life extension of fresh produce. The quality attributes of treated produce are not compromised but improved. Therefore, plasma‐mediated treatment has great potential and values for its application in the food industry.     

Minimally Processed Functional Foods: Technological and Operational Pathways

This paper offers a concise review of technical and operational concepts underpinning commercialization of minimally processed functional foods (FFs), foods with fresh‐like qualities commanding premium prices. The growing number of permitted nutritional content/health claims, many of which relate to well‐being, coupled with emerging extraction and food processing technologies offers new exciting opportunities for small and medium size enterprises (SMEs) specializing in fresh produce to play an active role in the health market. Supporting SMEs, governments could benefit from savings in healthcare costs and value creation in the economy. Consumers could benefit from novel FF formats such as refrigerated RTE (ready‐to‐eat) meals, a variety of fresh‐like meat‐, fish‐, and egg‐based products, fresh‐cut fruits and vegetables, cereal‐based fermented foods and beverages. To preserve these valuable commodities, mild biological (enzymatic treatment, fermentation and, bio‐preservation) and engineering solutions are needed. The latter include nonthermal techniques such as high‐pressure treatment, cook‐chill, sous‐vide, mirco‐encapsulation, vacuum impregnation and others. “De‐constructive” culinary techniques such as 3D food printing and molecular gastronomy as well as developments in nutrigenomics and digital technologies facilitate novel product formats, personalization and access to niche markets. In the operational sense, moving from nourishment to health improvement demands a shift from defensive market‐oriented to offensive market‐developing strategies including collaborative networks with research organizations.     

食品加工对过敏原活性的影响

近年来, 食物过敏性疾病的发病率明显上升, 已成为影响人类健康最常见的全球性疾病之一。本文对食品加工中常用的几种方法对特定食品过敏原活性的影响进行了综述, 这些加工方法包括热处理、高压处理、研磨、辐照、碱水解、梅拉德反应、酶解、微生物发酵和基因工程等, 并对存在的问题进行了分析。     

Understanding the Role of Plasma Technology in Food Industry

The need for enhancing microbial food safety and quality, without compromising the nutritional, functional, and sensory characteristics of foods, has created an increasing interest in innovative technologies in food industry. Plasma is an emerging, green processing technology offering many potential applications and fulfills the need of the industry. The present review presents the latest developments and applications of plasma technology in food industry. Recent research investigations showed that plasma processing have caught the interest of various areas of industry including cereal, meat, poultry, dairy, fruits, vegetables, packaging, etc. Plasma processing helps to modify the food material for the desirable trait, and maintains the nutritional and textural properties in addition to microbial decontamination.     

Environmental impact of novel thermal and non-thermal technologies in food processing

During the last 25 years, consumer demands for more convenient and varied food products have grown exponentially, together with the need for faster production rates, improved quality and extension in shelf life. These requests together with the severity of the traditional food processing technologies were driving forces for improvements in existing technologies and for the development of new food preservation technologies. Therefore, many technological developments have been directed towards unit operations such as pasteurization, sterilization, cooking and drying, and currently the new technological approaches for food preservation are serious candidates to replace the traditional well-established preservation processes. The aim of this review is to discuss the environmental impact that some of the most promising novel food preservation technologies may represent in terms of energy efficiency, water savings and reduced emissions. The emergence of novel thermal and non-thermal technologies allows producing high quality products with improvements in terms of heating efficiency and, consequently, in energy savings. Most of these technologies are locally clean processes and therefore appear to be more environment-friendly, having less environmental impact than the traditional ones. Novel processing technologies are increasingly attracting the attention of food processors once they can provide food products with improved quality and a reduced environmental footprint, while reducing processing costs and improving the added-value of the products.     

New hybrid drying technologies for heat sensitive foodstuffs

Drying is an indispensable process in many food industries. The drive towards improved drying technologies is spurred by the needs to produce better quality products. Improvement in quality of most food products translates into significant increase in their market value. The recent development of new hybrid drying technologies to improve food quality is in line with the present trend of ‘quality’ enhancement with reduced environmental impact. This review paper summarises some recent developments in hybrid drying technologies of interest to food industry. Numerous emerging technologies are listed and discussed in detail. The potential application areas for these hybrid drying technologies in product quality enhancement are identified.