Showing papers in "Trends in Food Science and Technology in 2018"
TL;DR: Principal component analysis (PCA) and hierarchical cluster analysis (HCA) are criticized as their indiscriminate use to assess the association between bioactive compounds and in vitro functional properties is criticized.
Abstract: Background The development of statistical software has enabled food scientists to perform a wide variety of mathematical/statistical analyses and solve problems. Therefore, not only sophisticated analytical methods but also the application of multivariate statistical methods have increased considerably. Herein, principal component analysis (PCA) and hierarchical cluster analysis (HCA) are the most widely used tools to explore similarities and hidden patterns among samples where relationship on data and grouping are until unclear. Usually, larger chemical data sets, bioactive compounds and functional properties are the target of these methodologies. Scope and approach In this article, we criticize these methods when correlation analysis should be calculated and results analyzed. Key findings and conclusions The use of PCA and HCA in food chemistry studies has increased because the results are easy to interpret and discuss. However, their indiscriminate use to assess the association between bioactive compounds and in vitro functional properties is criticized as they provide a qualitative view of the data. When appropriate, one should bear in mind that the correlation between the content of chemical compounds and bioactivity could be duly discussed using correlation coefficients.
535 citations
TL;DR: In this paper, a review of different plasma sources employed for PAW generation, its physico-chemical properties and potential areas of PAW applications is presented. And the role of plasma in improving the agricultural practices, for example, promoting seed germination and plant growth, is also presented.
Abstract: Background Cold plasma is an emerging non-thermal disinfection and surface modification technology which is chemical free, and eco-friendly. Plasma treatment of water, termed as plasma activated water (PAW), creates an acidic environment which results in changes of the redox potential, conductivity and in the formation of reactive oxygen (ROS) and nitrogen species (RNS). As a result, PAW has different chemical composition than water and can serve as an alternative method for microbial disinfection. Scope and approach This paper reviews the different plasma sources employed for PAW generation, its physico-chemical properties and potential areas of PAW applications. More specifically, the physical and chemical properties of PAW are outlined in relation to the acidity, conductivity, redox potential, and concentration of ROS, RNS in the treated water. All these effects are in microbial nature, so the applications of PAW for microbial disinfection are also summarized in this review. Finally, the role of PAW in improving the agricultural practices, for example, promoting seed germination and plant growth, is also presented. Key findings and conclusions PAW appears to have a synergistic effect on the disinfection of food while it can also promote seedling growth of seeds. The increase in the nitrate and nitrite ions in the PAW could be the main reason for the increase in plant growth. Soaking seeds in PAW not only serves as an anti-bacterial but also enhances the seed germination and plant growth. PAW could potentially be used to increase crop yield and to fight against the drought stress environmental conditions.
432 citations
TL;DR: These properties suggest that postbiotics may contribute, to the improvement of host health by improving specific physiological functions, even though the exact mechanisms have not been entirely elucidated.
Abstract: Background It has been recognized that a number of mechanisms mediating the health benefits of beneficial bacterial cells do require viability. However, new terms such as paraprobiotic or postbiotic have emerged to denote that non-viable microbial cells, microbial fractions, or cell lysates might also offer physiological benefits to the host by providing additional bioactivity. Scope and approach This review provides an overview of the postbiotic concept, evidence of their health benefits and possible signaling pathways involved in their protective effects, as well as perspectives for applications in foods and pharmaceuticals. Key findings and conclusions Postbiotics refers to soluble factors (products or metabolic byproducts), secreted by live bacteria, or released after bacterial lysis, such as enzymes, peptides, teichoic acids, peptidoglycan-derived muropeptides, polysaccharides, cell surface proteins, and organic acids. These postbiotics have drawn attention because of their clear chemical structure, safety dose parameters, long shelf life and the content of various signaling molecules which may have anti-inflammatory, immunomodulatory, anti-obesogenic, antihypertensive, hypocholesterolemic, anti-proliferative, and antioxidant activities. These properties suggest that postbiotics may contribute, to the improvement of host health by improving specific physiological functions, even though the exact mechanisms have not been entirely elucidated.
429 citations
TL;DR: In this article, a review of pectin extraction from food waste and by-products is presented, focusing on the conventional and innovative processing techniques (microwave extraction, enzymatic extraction, ultrasound-assisted extraction).
Abstract: Background A large amount of food wastes and by-products are produced from farm to plate. They represent valuable sources for the production of high-added value compounds such as pectin. Pectin is the methylated ester of polygalacturonic acid and presents a wide range of applications in pharmaceutical and cosmetic products as well as in food industry such as gelling agent in fruit-based products, stabilizer in fruit and milk beverages and fruit filling for bakery and confectionary products, among others. Therefore, pectin recovery is of great importance. Scope and Approach The commercially available pectin is almost exclusively derived from citrus peels or apple pomace, by-products from fruit juice manufacturing. But, nowadays the number of novel food waste and by-products sources for pectin extraction are increasing. Moreover, the application of innovative approaches is necessary due to the limitation of conventional processes. The present review will focus on the conventional and innovative processing techniques (microwave extraction, enzymatic extraction, ultrasound-assisted extraction) to extract pectin from different wastes and by-products. Key Findings and Conclusions The pectin extraction differs according to the matrix studied as well as temperature, pH, time, solvents, and solid to liquid ratio. The use of innovative extraction processes such as ultrasound, microwave and enzymes can be a useful tool to increase pectin yield and quality, and reducing extraction time, temperature, use of toxic solvents and strong acidic conditions for pectin recovery. Moreover, the combination of solvent modelling and the use of particular extraction processes can enable the selective recovery of pectin.
377 citations
TL;DR: Cultured meat is a promising, but early stage, technology with key technical challenges including cell source, culture media, mimicking the in-vivo myogenesis environment, animal-derived and synthetic materials, and bioprocessing for commercial-scale production.
Abstract: Background Cultured meat forms part of the emerging field of cellular agriculture. Still an early stage field it seeks to deliver products traditionally made through livestock rearing in novel forms that require no, or significantly reduced, animal involvement. Key examples include cultured meat, milk, egg white and leather. Here, we focus upon cultured meat and its technical, socio-political and regulatory challenges and opportunities. Scope and approach The paper reports the thinking of an interdisciplinary team, all of whom have been active in the field for a number of years. It draws heavily upon the published literature, as well as our own professional experience. This includes ongoing laboratory work to produce cultured meat and over seventy interviews with experts in the area conducted in the social science work. Key findings and conclusions Cultured meat is a promising, but early stage, technology with key technical challenges including cell source, culture media, mimicking the in-vivo myogenesis environment, animal-derived and synthetic materials, and bioprocessing for commercial-scale production. Analysis of the social context has too readily been reduced to ethics and consumer acceptance, and whilst these are key issues, the importance of the political and institutional forms a cultured meat industry might take must also be recognised, and how ambiguities shape any emergent regulatory system.
363 citations
TL;DR: This review highlights the recent advances in micro and nano-encapsulation of bioactive compounds, and comprehensively discussed the importance of encapsulation, the application of biopolymer-based carrier agents and lipid-based transporters with their functionalities, suitability of encapsulations techniques in micro
Abstract: Background Bioactive compounds possess plenty of health benefits, but they are chemically unstable and susceptible to oxidative degradation. The application of pure bioactive compounds is also very limited in food and drug formulations due to their fast release, low solubility, and poor bioavailability. Encapsulation can preserve the bioactive compounds from environmental stresses, improve physicochemical functionalities, and enhance their health-promoting and anti-disease activities. Scope and approach Micro and nano-encapsulation based techniques and systems have great importance in food and pharmaceutical industries. This review highlights the recent advances in micro and nano-encapsulation of bioactive compounds. We comprehensively discussed the importance of encapsulation, the application of biopolymer-based carrier agents and lipid-based transporters with their functionalities, suitability of encapsulation techniques in micro and nano-encapsulation, as well as different forms of improved and novel micro and nano-encapsulate systems. Key findings and conclusions Both micro and nano-encapsulation have an extensive application, but nano-encapsulation can be a promising approach for encapsulation purposes. Maltodextrin in combination with gums or other polysaccharides or proteins can offer an advantageous formulation for the encapsulation of bioactive compounds by using encapsulation techniques. Electro-spinning and electro-spraying are promising technologies in micro and nano-encapsulation, while solid lipid nanoparticles and nanostructure lipid carriers are exposing themselves as the promising and new generation of lipid nano-carriers for bioactive compounds. Moreover, phytosome, nano-hydrogel, and nano-fiber are also efficient and novel nano-vehicles for bioactive compounds. Further studies are required for the improvement of existing encapsulate systems and exploring their application in food and gastrointestinal systems for industrial application.
354 citations
TL;DR: Nanocapsules with lipid formulations are possible alternatives to micro-sized carriers owing to the enormous surface area and the following features which they offer, such as improved solubility, high bioavailability and establishment of sustained liberation of the nanoencapsulated food constituents and nutraceuticals.
Abstract: Background The encapsulation and liberation technologies for bioactive food ingredients has opened the door to innovative and significant applications in food, nutrition, and pharmaceutical fields via the employment of nanotechnology. Coating materials in the formulation of nanocapsules are mostly lipid, carbohydrate or protein-based. The nanoencapsulation procedure in the food and nutraceutical areas involves the incorporation of natural ingredients, such as volatile additives, polyphenols, aromas, colors, vitamins, enzymes, oils and antimicrobial compounds in nano-sized capsules, providing the opportunities for higher stability and retention for the sensitive molecules against decomposition and loss of nutritional value during the production process or delivery along with offering a sustained release. Scope and approach This review highlights the most recent nanoencapsulation advancements along with the formulations mainly based on lipid components; i.e., nanoemulsions, nanoliposomes and nanostructured lipid carriers in terms of preparation strategies, their classes, composition, attributes, analysis techniques, worked examples, and implementation in functional foods along with their upcoming evolution and future trends. Key findings and conclusions Nanocapsules with lipid formulations are possible alternatives to micro-sized carriers owing to the enormous surface area and the following features which they offer, such as improved solubility, high bioavailability and establishment of sustained liberation of the nanoencapsulated food constituents and nutraceuticals.
286 citations
TL;DR: Compared with micro-sized carriers, nanocapsules based on lipid formulations provide more surface area and have the potential to enhance solubility, improve bioavailability, and ameliorate controlled release of the nano-encapsulated phenolic compounds.
Abstract: Background Phenolic compounds1 are one of the main interested nutraceuticals in the food and pharmaceutical industries. The application of phenolics is limited due to their low bioavailability, low solubility, low stability, and un-targeted release. These limitations could be overcome by novel ‘‘lipid-based nano-encapsulation technologies’’ capable of appropriated and targeted delivery functions into foods. Scope and approach In this review, preparation, application, and characterization of lipid-based nanocarriers for phenolics have been considered and discussed including nano-emulsions, nano-scale phospholipids, and nanostructured lipid carriers. The bioavailability of nano-encapsulated phenolic products and capability of them to produce functional foods have been considered as well. Key findings and conclusions In the food and nutraceutical industries, the main aims of loading phenolics into nanocarriers are masking their undesirable flavor for oral administration, providing high stability and high absorption, and better release in gastrointestinal (GIT) conditions. Compared with micro-sized carriers, nanocapsules based on lipid formulations provide more surface area and have the potential to enhance solubility, improve bioavailability, and ameliorate controlled release of the nano-encapsulated phenolic compounds.
281 citations
TL;DR: Techniques that follow the bottom-up strategy have the potential to resemble the structure of meat most closely, by structuring the proteins hierarchically through assembly of individual structural components.
Abstract: Background Animal-derived protein foods, such as meat, have a large impact on the environment. Meat analogues are products that replace meat in its functionality, i.e. have similar product properties and sensory attributes, which is achieved by the fibrous nature of those products. Scope and approach The techniques used to make fibrous products that mimic muscle meats are outlined and categorized based on their approach. The bottom-up approach refers to assembly of structural elements that are combined. The top-down approach refers to structuring of biopolymer blends using an overall force field. The strengths and weaknesses of these approaches are discussed in terms of ingredient and equipment use, (achievable) product resemblance, robustness, scalability, and resource efficiency. To enlarge the theoretical framework, the techniques with the top-down strategy are further contextualized by relating to structure formation processes of materials with other applications, and the methods to analyse the fibrous structures are further outlined. Key findings and conclusions Techniques that follow the bottom-up strategy have the potential to resemble the structure of meat most closely, by structuring the proteins hierarchically through assembly of individual structural components. The top-down strategy is better scalable, is more efficient in its use of resources, but can only create the desired structure on larger length scales. Significant progress has been made on the methods to analyse structured products from the last category. Most analysis methods focussed on the (micro)structural anisotropy of the fibrous products, however there is also a need for methods that allow in situ analysis of the evolution of the structure during processing.
278 citations
TL;DR: Active packaging is a thriving field given its duality as barrier to external detrimental factors and active role in food preservation and quality as mentioned in this paper, however, research is still in its early stages with a long way to go in the design of innovative and economical active packaging materials containing appropriate active agents.
Abstract: Background The ever-growing world population results in the ineluctable increase of food demand which translates in the augment of the global market of packaging materials. Hence, the concept of active packaging materializes as a technology to enhance the safety, quality and shelf-life of the packaged foods. Active packaging systems can contribute to the reduction of food waste by providing, apart from an inert barrier to external conditions, several functions associated with food preservation, namely absorbing/scavenging, releasing/emitting and removing properties, temperature, microbial and quality control. Scope and approach The purpose of this review is to present a concise (but wide-ranging) appraisal on the latest advances in active agents for active food packaging. Emphasis is placed on active functions such as antimicrobial and antioxidant activity, oxygen and ethylene scavenging, and carbon dioxide emitting. An effort was made to highlight representative articles that prompted research on active agents towards viable market solutions. Key findings and conclusions Active packaging is a thriving field given its duality as barrier to external detrimental factors and active role in food preservation and quality. The use of natural active agents is a flourishing field due to the general concern towards natural-based additives. Nevertheless, research is still in its early stages with a long way to go in the design of innovative and economical active packaging materials containing appropriate active agents. The interaction between packaging, environment and food is the key challenge for achieving commercial translation.
267 citations
TL;DR: In food technology, successful application in meat products strengthens the role of selected peptides as antioxidant additives, although there is a need to observe the effects of the isolated bioactive peptides in other food matrices along with studies to scale-up its production.
Abstract: Background Diseases related to oxidative stress and food quality decay are of major concern worldwide as they can lead to economic losses in both public health and food production. The antioxidant peptides, extracted from food proteins, can be explored as natural new drug and food ingredient. Scope and approach Antioxidant peptides are extracted from non-antioxidant precursor proteins from different origin by the activity of either proteolytic microorganisms or isolated enzymes. In the present review, the main sources of bioactive peptides will be discussed. Moreover, the current strategies to obtain these compounds as well as their health benefits and in vivo biological effects will be evaluated. Considerations for further research and development of strategies to increase the knowledge about this underexplored activity of peptides will be also considered. Key findings and conclusions Bioactive peptides' content and profile differ according to the matrix studied and the method used. The utilization of fermentation processes and enzymes has been established to obtain antioxidant bioactive peptides from proteins, being isolated enzymes the most commonly used method, due to their superior control over releasing and obtaining targeted peptides. Antioxidant peptides have the ability to reduce the formation of oxidative products along with the induction of antioxidant enzymes in vivo. However, at this stage of development more in vivo studies are needed in order to evaluate the specific effects on the health of selected antioxidant peptides. In food technology, successful application in meat products strengthens the role of selected peptides as antioxidant additives, although there is a need to observe the effects of the isolated bioactive peptides in other food matrices along with studies to scale-up its production.
TL;DR: In this paper, a review summarizes the recent advances in application of different oil-in-water emulsion-based approaches, such as, conventional emulsions (surfactants-, protein-and protein-polysaccharide-stabilized emelsions), nano-emulsions, and Pickering emulsion that have been specifically used to deliver curcumin.
Abstract: Background Curcumin has been widely acknowledged for its health-promoting effects. However, its application is often limited by its poor water solubility and biochemical/structural degradation during physiological transit that restricts its bioavailability. Emulsion based approaches have attracted the most research attention to encapsulate curcumin and improve its stability, bioaccessibility and bioavailability. Scope and approach This review summarizes the recent advances in application of different oil-in-water emulsion-based approaches, such as, conventional emulsions (surfactants-, protein- and protein-polysaccharide-stabilized emulsions), nanoemulsions, and Pickering emulsions that have been specifically used to deliver curcumin. Particular emphasis is given to factors affecting curcumin solubility, change in crystalline structure of curcumin upon dispersion and encapsulation efficiency. Changes in the droplet size and emulsion stability during in vitro oral-to-gastrointestinal digestion are discussed, with clear focus on the bioaccessibility of the encapsulated curcumin. Key findings and conclusions Key factors that influence curcumin delivery include emulsion droplet size, oil composition, volume fraction, dispersion conditions of curcumin in the oil phase and the type of interfacial materials. Nanoemulsions have been the preferred choice for delivery of curcumin up to now. Although scarce in literature, emulsions stabilized by edible Pickering particles as shown by recent evidence are effective in protecting curcumin in an in vitro gastrointestinal setting due to their high coalescence stability. Further studies with emulsions stabilized by food-grade particles and accurate tracking of the physiological fate ( in vitro to human trials) of different emulsion-based delivery vehicles are essential for rational designing of curcumin-rich functional foods with high bioaccessibility.
TL;DR: In this article, the authors summarized and explained the available analytical and advanced methods for determination of pesticides compound in environment and foodstuffs, also, pesticides classification and its toxicity, and available extraction methods are briefly discussed.
Abstract: Pesticides are widely applied to prevent unwanted pests from attacking crops and livestock which led to their access into the environment. Overuses of pesticides in environment are presence of pesticide residues and their metabolites that are causing serious detrimental effects on human health and all other living organisms. Several severe diseases (Cancer, chronic obstructive pulmonary disease, birth defects, infertility) and more damages of human health are associated with the exposure of pesticides. The maximum residue limits for pesticides have been regulated by the Codex Alimentarius Commission and European Union to protect human health. Thus, monitoring these compounds is extremely important to ensure that only permitted levels of pesticide are consumed. To date, several techniques have been developed for pesticide detection, from conventional analytical to advanced detection techniques. The conventional analytical methods are gas chromatography and high performance liquid chromatography coupled with various detectors involved a sample preparation step prior to further analysis. Advanced detection methods refer to the sensors development such as electrochemical, optical, piezoelectric and molecular imprinted polymer. In this review, we summarized and explained the available analytical and advanced methods for determination of pesticides compound in environment and foodstuffs. Also, pesticides classification and its toxicity, and available extraction methods are briefly discussed.
TL;DR: In this article, the authors provide an update on recent research for aflatoxin decontamination by conventional methods including thermal processing and chemical treatments, including microwave heating, gamma and electron beam irradiation, ultraviolet and pulsed light, electrolyzed water and cold plasma.
Abstract: Background Conventional strategies for mycotoxin reduction includes both prevention and decontamination strategies. Decontamination of aflatoxin has been a continuing challenge for the food industry. Novel processing methods are continuously explored to achieve complete aflatoxin degradation in food products. Scope and approach The present review provides an update on recent research for aflatoxin decontamination by conventional methods including thermal processing and chemical treatments. Novel aflatoxin decontamination technologies like microwave heating, gamma and electron beam irradiation, ultraviolet and pulsed light, electrolyzed water and cold plasma are reviewed in detail. This review provides a brief introduction, decontamination mechanism, degradation efficiency, advantages and limitations of these novel technologies. Key findings and conclusion Although conventional thermal technologies are known to cause aflatoxin degradation, they are not adequate for complete aflatoxin degradation in food products. Novel technologies like pulsed light, electrolyzed water and cold plasma have shown complete degradation of aflatoxin on different substrates. However, application on food products need further studies along with the degradant toxicology and its interaction with food components. Novel processing technologies shows significant potential for future applications in decontaminating aflatoxin in the food industry.
TL;DR: The benefits and limitations of 3D food printing were critically reviewed from a different perspective while providing ample mechanisms to overcome those barriers.
Abstract: Background Digitalizing food using 3-Dimensional (3D) printing is an incipient sector that has a great potential of producing customized food with complex geometries, tailored texture and nutritional content. Yet, its application is still limited and the process utility is under the investigation of many researchers. Scope and approach The main objective of this review was to analyze and compare published articles pertaining 3D food printing to ensure how to reach compatibility between the huge varieties of food ingredients and their corresponding best printing parameters. Different from previously published reviews in the same journal by Lipton et al. (2015) and Liu et al. (2017), this review focuses in depth on optimizing extrusion based food printing which supports the widest array of food and maintains numerous shapes and textures. The benefits and limitations of 3D food printing were critically reviewed from a different perspective while providing ample mechanisms to overcome those barriers. Key findings and conclusions Four main obstacles hamper the printing process: ordinance and guidelines, food shelf life, ingredients restrictions and post processing. Unity and integrity between material properties and process parameters is the key for a best end product. For each group, specific criteria should be monitored: rheological, textural, physiochemical and sensorial properties of the material its self in accordance with the process parameters of nozzle diameter, nozzle height, printing speeds and temperature of printing. It is hoped that this paper will unlock further research on investigating a wider range of food printing ingredients and their influence on customer acceptability.
TL;DR: A review of the different antioxidant groups, describing their properties, function and applicability, as well as indexing the relevant legislation in order to be a guide for academia and industry is presented in this paper.
Abstract: Background Food antioxidants play a critical role in the food industry, and have become one of the most widespread methods of conserving food. Their cheapness and ease of use have made them a part of virtually all foodstuffs. Although different, all groups of food antioxidants have a same common objective, to conserve food for the longest possible time without altering it, conferring taste or color. Consumer trends have shifted the industry to find natural antioxidants for conservation, and although synthetic additives have been the mainstream, their natural counterparts have been gaining interest. Scope and approach This review focuses of the different antioxidant groups, describing their properties, function and applicability, as well as indexing the relevant legislation in order to be a guide for academia and industry. Key findings and conclusions The wide number of antioxidant additives allowed by the different countries if of synthetic origin, and consist of pure molecules. Although consumers are leaning toward natural additives, this offer is still quite limited despite the permission of rosemary extract within the European Union. There is still much work to be done in order to completely demystify the importance and safety of antioxidants as well as to harmonize legislation worldwide.
TL;DR: In this paper, the effects of cell structure and water distribution on the texture and sensory properties of fresh cellular foods are discussed, and novel methods to control the formation of ice crystals and preserve cell structures are also provided.
Abstract: Background Fresh cellular food materials including fruits and vegetables and animal tissues normally consist of fine organized cellular structures. Freezing is a common method to preserve the quality and safety of these cellular foods. However, the formation of ice crystals during food freezing may cause damage to the food microstructure, leading to the deterioration of food quality after thawing. Scope and approach This review offers current knowledge on freezing damage to cell structure of fresh cellular food materials. Effects of cell structure and water distribution on the texture and sensory properties of fresh cellular foods are presented. Mechanisms of cell structure damages caused by freezing are discussed. Novel methods to control the formation of ice crystals and preserve cell structures are also provided. Key findings and conclusions The quality of cellular foods after frozen-thawed is highly correlated with the integrity and viability of tissue cells. The formation of ice crystals, water migration and the inherent characteristics of cell structure are regarded as the main factors affecting the cell structure during freezing. For obtaining better quality of frozen products, further investigation and understanding on freezing damage to cell structure of fresh cellular foods is necessary. It is hoped that the current review will provide more information on improving frozen food quality for the frozen food industry.
TL;DR: Bee bread that is rich in beneficial ingredients has proved to fulfill expectations and constitutes a wholesome, biologically active nutrient, which can be used in the food industry.
Abstract: Background An interest in substances of natural origin has been a subject that is increasing constantly-both those known for many years and recently discovered are of great interest to the researchers. This interest also applies to bee products because of their extensive nutritional and therapeutic properties; these products are known and used for several thousand years, but only recently, they became the subject of sparse documented scientific research. With the passing of time, it is difficult to determine what will be the wishes and requirements of the future consumers, what should be introduced to new technologies to ensure the demand for new products. Scope and approach Recently, there has been an increasing demand for natural products, particularly the bee products. Bee bread and pollen, due to their nutritional and medicinal properties, are used for apitherapeutic purposes. These include about 200 different substances, such as free amino acids and vitamins. Special attention should be attributed to unsaturated fatty acids such as linoleic, linolenic, and arachidonic, which are found in pollen and bee bread. Key finding and conclusion The fashion for a healthy lifestyle leads to a situation where a number of people start taking care of their health. They search for the highest quality products, preferably with health benefits, rich in vitamins, valuable bioelements, and nutrients. Therefore, bee bread that is rich in beneficial ingredients has proved to fulfill these expectations. It constitutes a wholesome, biologically active nutrient, which can be used in the food industry.
TL;DR: In this article, the authors link the isolation of valuable proteins from sustainable sources and eco-innovative technologies which are emerging for this purpose (electrostatic separation, subcritical water extraction, reverse micelles extraction, aqueous two-phase systems extraction, enzyme-, microwave-, ultrasound-, pulsed electric energy- and high pressure-assisted extraction).
Abstract: Background The need for renewable and sustainable sources of proteins is growing. Diets containing more plant protein are increasing due to several reasons: the negative environmental impacts of animal protein production, the increasing vegetarianism and veganism trends, and inadequate consumer acceptance of food grade insects. Scope and approach This paper links the isolation of valuable proteins from sustainable sources – by-products from processing industry of plant origin and eco-innovative technologies which are emerging for this purpose (electrostatic separation, subcritical water extraction, reverse micelles extraction, aqueous two-phase systems extraction, enzyme-, microwave-, ultrasound-, pulsed electric energy- and high pressure-assisted extraction). In this way, not only the key challenges of modern food processing are met-the assurance of cost-effective, sustainable and environmentally friendly production, but also the concept of zero food waste seems more achievable. Key findings and conclusions A number of different techniques have emerged with high potential to assist protein extraction of preserved techno-functional properties, but they are still in the early stage of its industrial applications. In the EU, its industrial application may be hindered by legislative issues. The respective Novel Food Regulation classifies food obtained in a production process not used for food production before 15 May 1997, as “novel food’’ and the regulatory status for each single case must be sought. On the other hand, the utilization of novel processing technologies is regulatory encouraged in EU due to their potential to reduce the environmental impact of food production, enhance food security and bring benefits to consumers.
TL;DR: In this article, a review on applications of zein/zein-based nano-materials in various branches of food (except food packaging) and nutrition sectors is made.
Abstract: Background Zein, a byproduct of corn with renewable resources, unique hydrophobic/hydrophilic character, film/fiber forming and antioxidant properties, is a promising biopolymer for food and nutrition applications. The advantages in properties and efficiencies of nano materials over bulk counterparts are the basis of their unique nature in novel technologies. These advantages also expand their possible applications. Scope and approach An effort has been made to review on applications of zein/zein-based nano-materials in various branches of food (except food packaging) and nutrition sectors. The effects of various parameters affecting preparations and properties of the nano-materials are also discussed. Nano-encapsulation of foods and nutrients is the major section of this study. Key findings and conclusions (i) the average size of zein nanoparticles reported to be 50–200 nm; (ii) the functions of zein nanomaterials were multiples: a carrier of delivery (food, beverage, and nutrient) systems; a shell or a core of encapsulated systems; or a food ingredient; (iii) zein-based nano-materials have been used for encapsulation of food and nutrient components including lipids; essential oils; fat soluble vitamins; food colorants; flavors; and natural anti-oxidants; (iv) the bioavailability of food and nutrient components such as folic acid, vitamin D3, curcumin, beta-carotene, and resveratrol was improved by employing the zein-nanoparticles in comparison with the bulk counterparts; and (v) bioactive substances with potential applications for food and nutrition sectors were stabilized by zein/zein-based nano-materials.
TL;DR: In this article, the main methods of sulfated modification, structural changes and the bioactivities of polysaccharide derivatives are reviewed, in order to reveal the potential mechanism of sulfation on bio-activities.
Abstract: Background Polysaccharides are a kind of biological macromolecular substance with multiple biological effects. Natural polysaccharides derived from plants and fungi are known as ideal raw food supplements for health food and pharmaceuticals due to their few side effects. Sulfated modification could significantly improve structure characteristics, promote bioactivities, and even add new bioactivities to polysaccharides. Thus, sulfated polysaccharides are increasingly causing more attention, as they have been proved to possess a variety of biological activities, including antioxidant, anticancer, and immunoregulatory, and anticoagulant activities. Furthermore, recent advances in synthesis, characterization and bioactivities of sulfated polysaccharides can promote its application in the food industry or pharmaceutics. Scope and approach This paper reviewed the main methods of sulfated modification, structural changes and the bioactivities of sulfated polysaccharide derivatives. We have comprehensively discussed biological activities of sulfated polysaccharides, emphatically the effects of sulfated group, composition, functional groups, as well as their replaced position on the bioactivities of sulfated polysaccharides, in order to reveal the potential mechanism of sulfation on bioactivities of polysaccharides. Key findings and conclusions This paper reviewed the recent research in the sulfated modification of polysaccharides and provided future directions for research in this area. There are many methods for sulfated modification, such as chlorosulfonic acid-pyridine method, concentrated sulfuric acid method, and sulfur trioxide-pyridine method, which could improve anti-coagulant, anti-oxidative, immunoregulation, anti-tumor, and anti-virus activities of polysaccharides. Sulfated modification could change bioactivities of polysaccharides due to their effects on structure characteristics. DS, monosaccharide compositions, replaced position of sulfated groups were considered to contribute to their bioactivities promotion. Further studies are required to explore the application of sulfated polysaccharides in pharmaceutical and food industries.
TL;DR: In this paper, a dry chain is defined to describe initial dehydration of durable commodities to levels preventing fungal growth followed by storage in moisture-proof containers, analogous to the cold chain in which continuous refrigeration is used to preserve quality in the fresh produce industry.
Abstract: Background Even as increasing populations put pressure on food supplies, about one-third of the total food produced for human consumption is wasted, with the majority of loss in developing countries occurring between harvest and the consumer. Controlling product dryness is the most critical factor for maintaining quality in stored non-perishable foods. The high relative humidity prevalent in humid climates elevates the moisture content of dried commodities stored in porous woven bags, enabling fungal and insect infestations. Mycotoxins (e.g., aflatoxin) produced by fungi in insufficiently dried food commodities affect 4.5 billion people worldwide. Scope and approach We introduce the term “dry chain” to describe initial dehydration of durable commodities to levels preventing fungal growth followed by storage in moisture-proof containers. This is analogous to the “cold chain” in which continuous refrigeration is used to preserve quality in the fresh produce industry. However, in the case of the dry chain, no further equipment or energy input is required to maintain product quality after initial drying as long as the integrity of the storage container is preserved. In some locations/seasons, only packaging is required to implement a “climate smart” dry chain, while in humid conditions, additional drying is required and desiccant-based drying methods have unique advantages. Key findings and conclusions We propose both climate-based and drying-based approaches to implement the dry chain to minimize mycotoxin accumulation and insect infestations in dry products, reduce food loss, improve food quality, safety and security, and protect public health.
TL;DR: This review presents the current knowledge and recent findings on the possibility of engaging nonthermal technologies including pulsed light, high pressure processing, irradiation, cold plasma, ultrasound and pulsed electric field, for the elimination of allergenic proteins in foods and their underlying mechanisms.
Abstract: Background The increasing prevalence of food allergy cases is an issue of global concern. As a result, scientific innovations have been taking place to induce chemical modifications for achieving attenuation of allergenic responses in sensitive individuals or for manufacturing hypoallergenic foods using food processing technologies. Conventional processing techniques involving heat treatment are usually exploited, but may be accompanied by dramatic changes in food quality attributes due to high temperature. Therefore, alternative nonthermal technologies may be a new direction for attaining hypoallergenicity. Scope and approach This review presents the current knowledge and recent findings on the possibility of engaging nonthermal technologies including pulsed light, high pressure processing, irradiation, cold plasma, ultrasound and pulsed electric field, for the elimination of allergenic proteins in foods and their underlying mechanisms. In contrast to heat-based methods, nonthermal treatments can adequately retain sensorial and nutritional quality of the food products, while altering allergenicity. Food allergy classification, clinical manifestations, epitope characterization and detection methods are also presented. Key findings and conclusions To date, studies show that nonthermal processes have complicated effects on food allergens. Much further research efforts should be made for using nonthermal processing technologies as alternatives to replace traditional techniques. Nonetheless, it is expected that in the near future, susceptible individuals will benefit from different hypoallergenic products processed with novel nonthermal technologies at an affordable cost.
TL;DR: In this article, the effects of non-thermal plasma on the quality of dairy products, considering a physicochemical, sensory, and microbiology perspective, are discussed, and a review of the fundamentals, parameters, and technology on cold plasma is presented.
Abstract: Background Thermal pasteurization and sterilization are predominantly used in the dairy industry due to their efficacy in improving the product safety and shelf life. However, heat treatment can cause undesirable protein denaturation, non-enzymatic browning, loss of vitamins and volatile flavor compounds, freezing point depression, and flavour changes. Cold plasma is a non-thermal technology that has gained attention in recent years as a potential alternative method for chemical and thermal disinfection in foods using ambient or moderate temperatures and short treatment times. Scope and approach This review aims to describe the fundamentals, parameters, and technology on cold plasma, discussing the critical processing factors involved in this technology. Also, it describes the mechanisms of microbial inactivation and provides an overview of the effects of non-thermal plasma on the quality of dairy products, considering a physicochemical, sensory and microbiology perspective. Key findings and conclusions Cold plasma uses less aggressive mechanisms of action to the milk matrix when compared to the techniques currently used, and has shown an excellent performance on the elimination of pathogenic and spoilage microorganisms besides maintaining, in many cases, the nutritional, functional, and sensory characteristics of the product.
TL;DR: This study provides a brief overview of conventional and modern detection techniques which includes nucleic-acid sequence based techniques to non-destructive imaging techniques and new trends and their practical application in the fields of detection microbiology and food technology.
Abstract: Background Continuous transformation and development of new detection tools for bacteria has converted the laborious scientific work into smart apparatus in recent years. The journey had begun with the culture-based plate enumeration, and now it has evolved into several culture-independent techniques. Polymerase chain reaction (PCR) is on the top of the list that is now a routinely used biological approach to detect bacterial cells. Instrumental techniques are also helpful in this regard, as they are more sensitive for detection of various microbes. Scope and approach In this review, we described new trends and their practical application in the fields of detection microbiology and food technology. This study provides a brief overview of conventional and modern detection techniques which includes nucleic-acid sequence based techniques to non-destructive imaging techniques. Key findings and conclusions Besides the availability of antibiotics and clinical treatments, bacterial infections significantly increase the mortality rate. It is necessary to detect apparent infectious agents beforehand. Therefore, the detection methods for microorganisms should be more rapid, smart and reliable in response to the need. Conventional detection techniques are slow and time-consuming but more accurate and reliable than the modern detection techniques. By combing the mentioned techniques, scientists can achieve better results.
TL;DR: In this article, an overview of the cold plasma technology in food industry is given, including the challenges of the process, its effects on food quality and the future prospects are highlighted, and the authors also highlight different plasma generation systems, various published results of plasma application to inactivate microorganisms in vitro and in various food products, food packages and equipment surfaces.
Abstract: Background The advent of the 21st century has witnessed a growing demand of safe and nutritious foods. The food industry is adopting novel non-thermal food processing technologies. Cold plasma is one such promising non-thermal food processing method which uses charged, highly reactive gaseous molecules and species to inactivate contaminating microorganisms on foods and packaging materials. Scope and approach The paper gives the reader an overview of the cold plasma technology in food industry. It reviews principles of plasma generation, including mechanisms of action of the process on microorganisms. It also highlights different plasma generation systems, various published results of plasma application to inactivate microorganisms in vitro and in various food products, food packages and equipment surfaces. The challenges of the process, its effects on food quality and the future prospects are highlighted. Key findings and conclusions This article aims to review and apprise readers about the important fundamentals and latest trends in the Cold Plasma technology. The on-going studies on plasma technology prove that cold plasma is strongly effective for surface decontamination, with efforts in-progress for liquid processing. The short time of application causes no significant deterioration in food products. Thus, it is an apt alternative processing technology which could also help to counter food allergenicity, seed germination, packaging material printing, waste-water treatment, modify food functionality, extract bio-actives etc. Further research is needed for scaling-up of this process for future commercialization.
TL;DR: In this article, a review on the application of metal oxide-based nanoparticles for producing nanocomposites is presented, and an overview of the regulations for nanomaterials in packaging is presented.
Abstract: Background Most nanotechnology applications for food packaging involve the use of silver nanoparticles or nanoclay. However, other nanomaterials can also be incorporated into packaging. Metal oxide nanoparticles have been added to petroleum-based and biopolymers to produce nanocomposites with enhanced mechanical and barrier properties, and their antimicrobial effects have also been reported. However, migration of nanoparticles from packaging is of concern because of their potential toxicity in the human body and the environment. Scope and approach This review focuses on the application of metal oxide-based nanoparticles for producing nanocomposites. Advantages of incorporating metal oxide-based nanoparticles into polymers are presented, and migration of these nanomaterials from packaging into foods is discussed. Furthermore, an overview of the regulations for nanomaterials in packaging is presented. Key findings and conclusions Addition of metal oxide nanoparticles into polymers allows for the production of nanocomposites with increased mechanical strength and water and oxygen barrier properties, and can also confer other benefits including antimicrobial activity and light-blocking properties. Migration studies have demonstrated that only a negligible amount of nanomaterial migrates from packaging into food simulants or foods, suggesting that consumer exposure to these nanomaterials and its associated health risks would be low. However, the regulatory framework for nanomaterials in packaging is still underdeveloped even in major economies.
TL;DR: In this article, surface-enhanced Raman spectroscopy (SERS) is used for detecting harmful chemical residues in agricultural products including pesticides, antibiotics and β2-adrenergic agonists.
Abstract: Background The irrational usage of chemical substances including pesticides and drugs in agricultural and food production is a significant food safety issue due to its residues. Therefore, the detection of harmful residues in foods is an indispensable step for guaranteeing the consumer's health. Conventional methods, such as HPLC, GC-MS and LC-MS are accurate enough, but they fail to meet the requirements of the modern industry for rapid and on-line detection. Novel reliable techniques should thus be developed as alternatives. Scope and approach In this review, fundamentals of surface-enhanced Raman spectroscopy (SERS) is introduced. Recent advances in its usage for detecting harmful chemical residues in agricultural products including pesticides, antibiotics and β2-adrenergic agonists are discussed by two typical ways of detection improvement, and the advantages of SERS are addressed. Finally, future trends to routine use of SERS applications in harmful residues are presented. Key findings and conclusions SERS is a promising detection technique for the detection of common harmful chemical residues with merits of simple sampling, rapid data collection and non-destructiveness. Despite rapid developments in the technology, there is much studies should be done before SERS could be used as a daily tool for the industry.
TL;DR: In this paper, a comprehensive review of cold plasma technology in food and bioprocessing is presented, highlighting the practical implications, and proposes strategies to mitigate the challenges of reactive oxygen species (ROS).
Abstract: Background Cold plasma is an emerging, economical and environment-friendly technology with potential applications in food and bioprocessing industry, including microbial decontamination, enzyme inactivation, shelf-life extension, and physicochemical modification. These advantages stem from the cocktail of reactive species and the physical processes that are associated with gaseous electrical discharges. However, when oxygen is present as a component of the gas in which plasma discharges are made, the reactive oxygen species (ROS) could result in decreased food quality. The lipids oxidation induced by an oxygen-containing cold plasma process can eventually affect the acceptability and shelf-life of foods. Scope and approach Product safety and quality are crucial considerations for the industrial adoption of cold plasma technology, necessitating a comprehensive review. This review critically analyses the oxidative impact of this novel technology on lipids, highlights the practical implications, and proposes strategies to mitigate the challenges. Key findings and conclusions Cold plasma in oxygen-containing inducer gases affects the lipids in several food materials including cereals, edible oils, dairy, and meat products. Therefore, it is necessary to understand and address its oxidative effects in different foods. Processing the appropriate food types under optimized process conditions along with the careful handling of the plasma-treated foods are among the key considerations to minimize the negative impacts on food lipids.
TL;DR: In this article, the authors introduce the fundamentals and advantages of emulsion electrospinning as well as its food applications and highlight the effects of different types of emulsifiers on the formation of the emulsion system and emulsion-based electrospun fibers.
Abstract: Background In the past decades, many natural bioactive compounds with antioxidant, immunoregulatory, antimicrobial, and anticancer activities have been successfully identified in plant and animal materials. However, due to their poor solubility, unfavorable flavor, low bioavailability and instability during food processing and storage, the development of bioactive compounds used in the food industry presents many technological challenges. Scope and approach Emulsion electrospinning is a novel and simple technique to fabricate core-shell nanofibers, and either water-in-oil (W/O) or oil-in-water (O/W) emulsions can be electrospun to directly encapsulate hydrophilic or hydrophobic compounds into core-shell fibers, respectively. This review introduces fundamentals and advantages of emulsion electrospinning as well as its food applications. The effects of different types of emulsifiers on the formation of emulsion systems and emulsion-based electrospun fibers are highlighted. Further, the existing limitations and scope for future research are discussed. Key findings and conclusions Recent studies have found that the emulsion-based electrospun nanofibers can enhance the encapsulation efficiency, stability, and bioavailability of bioactive compounds, as well as achieve targeted delivery and controlled release, thus providing new strategies to improve their barrier performance compared to conventional electrospinning and therefore facilitating the development of emulsion-based electrospun mats in the food industry.