Encapsulation of curcumin in electrosprayed gelatin microspheres enhances its bioaccessibility and widens its uses in food applications

Curcumin has uses as a food colorant and functional ingredient, these uses being restrained owing to its low solubility in water, which limits its dispersion in food matrices and its bioaccessibility. Curcumin–gelatin microparticles produced by electrohydrodynamic atomization were developed to overcome these problems. Microparticles with a size up to 1.2 μm in diameter, in which curcumin was in the amorphous state, were obtained. Both curcumin water solubility and bioaccessibility were significantly improved by encapsulation (38.6 and 11.3-fold higher than commercial curcumin, respectively). A gellified fish product was used to evaluate the coloring capacity of microencapsulated curcumin, finding a better dispersion for microencapsulated curcumin than for commercial one. However, curcumin bioaccessibility was similar owing to curcumin solubilization into the protein matrix. In spite of this, a protective effect of curcumin was observed, as the antioxidant activity of the bioaccessible fraction of the gel supplemented with microencapsulated curcumin was higher.Industrial relevanceCurcumin is a potential natural food coloring and functional ingredient which impairs an attractive yellowish-orange color to food and possesses a wide range of biological activities. However its use in food is restrained owing to its low solubility in water. Curcumin encapsulation using a soluble polymer is a promising strategy to widen the use of curcumin as an ingredient in the food industry.     

姜黄素在食品保鲜中应用的研究进展

姜黄素是一种绿色天然的食品保鲜剂,无毒无害,而且具有抗菌、抗氧化等保鲜效果。但由于姜黄素的水溶性差,生物利用率不高等问题,限制了其应用领域,所以增加姜黄素的生物利用率是拓宽其应用领域的重要因素。文章介绍了姜黄素的结构和食品保鲜原理,还综述了近年来姜黄素在食品保鲜领域中利用微胶囊、静电纺丝、纳米络合和胶体等方式提高其生物利用率的研究进展,为了姜黄素在食品保鲜领域中进一步的开发和利用提供一定的参考。     

The biological activities,chemical stability,metabolism and delivery systems of quercetin: A review

BackgroundQuercetin, one of the most well-known flavonoids, has been included in human diet for a long history. The use of quercetin has been widely associated with a great number of health benefits, including antioxidant, anti-inflammatory, antiviral and anticancer as well as the function to ease some cardiovascular diseases (i.e., heart disease, hypertension, and high blood cholesterol). However, poor water solubility, chemical instability and low bioavailability of quercetin greatly limit its applications. Utilization of delivery systems can improve its stability, efficacy and bioavailability.Scope and approachIn this review, biological activities, chemical stability, metabolism and toxicity of quercetin and different delivery systems for quercetin were discussed.Key findings and conclusionsQuercetin digested in human body (e.g., mouth, small intestine, liver, kidneys) undergoes glucuronidation, sulfation or methylation. During the food processing and storage, many factors such as heat, pH, metal ions, could affect the chemical stability (including oxidation and degradation) of quercetin. Utilization of delivery systems including lipid-based carriers, nanoparticles, inclusion complexes, micelles and conjugates-based encapsulation has the potential to improve both the stability and bioavailability and thus health benefits of quercetin. Each delivery system has its unique advantages and shortcomings, and the specific selection should be based on the application domains. Moreover, the exploration of natural food-grade ingredients as main compositions of delivery systems for quercetin might be required in the future.     

Encapsulation systems for lutein: A review

BackgroundThe increased demand by consumers for clean labels has encouraged industry to search for replacements of synthetic ingredients in food products, and in particular, colorants. Lutein, a xanthophyll found in marigolds and corn, can be used in food products as a natural colorant replacing yellow food dyes. Moreover, lutein is considered a nutraceutical due to its potentially beneficial health effects, such as prevention of macular degeneration, role in the development of the visual and nervous systems of fetuses, and its antioxidant properties. However, incorporation of lutein into foods is often limited because of its low-water solubility, chemical instability, and poor oral bioavailability. For this reason, colloidal encapsulation systems have been developed to facilitate the incorporation of lutein into aqueous food and beverage products.Scope and approachThis review focuses on exploring encapsulation options for lutein using various emulsion-based, nanoparticle- and microparticle-based and molecular inclusion encapsulation systems, as well as additives that can be used to increase its chemical stability in these systems. This review covers all aspects of lutein encapsulation, including both food-grade and pharmaceutical-grade encapsulation systems.Key findings and conclusionsThough lutein-loaded encapsulation systems are extensively explored in this review, emulsions are of the most interest in industry as they are cost efficient and can be designed to increase the stability of lutein by selecting the proper emulsifiers and emulsification techniques. Despite the extensive amount of research carried out on the encapsulation of hydrophobic bioactive molecules such as lutein, there are still opportunities to develop encapsulation systems that further protect these molecules during storage and also increase their bioavailability after ingestion.     

Determination of chemical hazards in foods using surface-enhanced Raman spectroscopy coupled with advanced separation techniques

BackgroundSurface-enhanced Raman spectroscopy (SERS) has been validated as a highly accurate and specific technique for the discrimination, identification, and potential quantification of different types of chemical compounds. However, its application for the detection of potential hazardous chemical targets in foods has not yet been well developed due to interferences from the complicated food matrices, which could lead to challenges in spectral deconvolution and interpretation. The accurate separation and enrichment of the analyte from food samples are major challenges for analytical chemists and food technologists.Scope and approachFour promising “capturing” techniques (molecularly imprinted polymers, aptamer, antibody, and microfluidics) coupled with SERS were introduced in this review paper for the reliable and ultrafast determination of chemical hazards in food systems. These developed “one-step” or “two-step” SERS methods can achieve accurate and sensitive detection of trace level chemical hazards in agricultural products including foods.Key findings and conclusionsTandem SERS methods can be applied for rapid and reliable detection of trace level of chemical hazards in foods.     

Recent advances in emulsion-based delivery approaches for curcumin: From encapsulation to bioaccessibility

BackgroundCurcumin 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 approachThis 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 conclusionsKey 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.     

Surface enhanced Raman spectroscopy (SERS): A novel reliable technique for rapid detection of common harmful chemical residues

BackgroundThe 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 approachIn 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 conclusionsSERS 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.     

Chemical and biological properties of feijoa (Acca sellowiana)

BackgroundFeijoa (Acca sellowiana) is native to South America and is recognised in some other parts of the world for its highly aromatic fruit. There has been increasing interest in developing feijoa for food product formulation and as fresh produce for consumption. Understanding the chemical composition and biological activities of different botanical parts of feijoa (fruit peel and flesh, leaf, and flower) provides a basis to support the current exploitation.Scope and approachThis mini-review summarises the recent advances in chemical composition and biological activities of different botanical parts of feijoa (fruit, leaf, and bud). Properties of feijoa are compared with those of other fruits. Processing feijoa for food applications is also reviewed. Future research directions on how to better utilize this crop are suggested.Key findings and conclusionsFejioa contains a range of bioactive components such as phenolic acids and flavonoids, dietary fiber, vitamin C, potassium, and essential oils. These compounds contribute to a range of claimed health effects, including antioxidant, anti-inflammatory, and antimicrobial activities of feijoa extracts. Consumption of fresh feijoa fruit should be moderate due to the presence of a relatively high level of soluble oxalate. Overall, feijoa has great potential to be developed as a sustainable crop.     

多酚的功能性质及与蛋白质、多糖相互作用研究进展

多酚是具有多种化学结构的多相分子群,具有很强的抗氧化性、抗菌性以及预防慢性疾病的能力,在食品和医疗领域具有广泛的应用价值。多酚由于含有多个酚羟基基团使其化学稳定性差,生物利用度低,在功能性食品中的应用受到了限制。蛋白质、多酚、多糖相互作用所形成的复合结构能够有效地提高食品的感官品质以及各生物大分子的功能特性。本文对多酚的结构与功能之间的关系,多酚与蛋白质、多糖三者相互作用的机理,多酚对二者功能性质及对改善乳化液性质的影响,进行了综述,以期为多酚在食品工业中的应用提供理论参考。     

Gold nanoparticles: From synthesis,properties to their potential application as colorimetric sensors in food safety screening

BackgroundFood safety management and guarantee are the basic requirement during food processing, circulation, storage, and marketing. Elevating the ability to evaluate food quality and safety in a rapid, sensitive and reliable manner is of great importance in food industry. Recently, gold nanoparticles due to unique optical property, ease of functionalization and preparation, and high selectivity and sensitivity have received considerable attention in the field of food safety.Scope and approachGold nanoparticles exhibit distinguishable optical characteristic in different aggregated states and thus have been developed into simple colorimetric sensors for the quick detection of chemical contaminants in food samples. Herein, we reviewed the current methods for synthesis and functionalization of gold nanoparticles, strategies for fabrication of gold nanoparticle based colorimetric sensors and their applications in rapid analysis of food contaminant. Moreover, the inherent optical property of gold nanoparticles and their detecting principle have been highlighted. Finally, the main challenges and future efforts in developing such colorimetric sensors for food contaminants detection were discussed.Key findings and conclusionsGold nanoparticles as smart colorimetric sensors conform to the requirement of modern analysis, such as high selectivity, sensitivity, simplicity, celerity, and portability. Thus, they have great potential to be applied as power sensing tools for food safety screening.     

Hempseed in food industry: Nutritional value,health benefits,and industrial applications

Hemp (Cannabis sativa L.) seeds have been consumed in Asian communities since prehistoric times. Recently, Australia, Canada, and the United States have legalized the cultivation and consumption of hempseed at low (<0.3%) tetrahydrocannabinol levels, and there's a growing interest in hempseed due to its nutritional value and pharmaceutical potential. This review aims to summarize the chemical composition, nutritional value, and potential health benefits of hempseed, as researched via in vitro and in vivo trials. The application of hempseed in the food industry is limited due to its poor performance on some functional properties, so the latest processing methods developed to improve these properties were compared. Additionally, manufacturing technologies incorporating hemp seeds into existing food products are also elaborated. This review would promote further in‐depth research on this recently approved food resources and maximize its utilization in new food product development.     

Wheat gluten–based coatings and films: Preparation,properties, and applications

Effective food packaging that can protect foodstuffs from physical, chemical, and biological damage and maintain freshness and quality is essential to the food industry. Wheat gluten shows promise as food packaging materials due to its edibility, biodegradability, wide availability, low cost, film-forming potential, and high resistance to oxygen. The low mechanical properties and poor water permeability of wheat gluten coatings and films limit their wide applications; however, some inferior properties can be improved through various solutions. This work presents a comprehensive review about wheat gluten–based coatings and films, including their formulation, processing methods, properties, functions, and applications. The mechanical and water resistance properties of coatings and films can be reinforced through wheat gluten modification, combinations of different processing methods, and the incorporation of reinforcing macromolecules, antioxidants, and nanofillers. Antioxidants and antimicrobial agents added to wheat gluten can inhibit microbial growth on foodstuffs, maintain food quality, and extend shelf life. Performances of wheat gluten–based coatings and films can be further improved to expand their applications in food packaging. Current research gaps are identified. Future research is needed to examine the optimal formulation and processing of wheat gluten–based coatings and films and their performance.     

Recent developments in applications of radio frequency heating for improving safety and quality of food grains and their products: A review

Abstract

Food grains constitute a vital part of the daily diet of the population worldwide, and are generally considered as safe products with high storage stability due to their low moisture contents. However, post-harvest losses (PHL) caused by insects, fungi, food-borne pathogens, and undesirable enzymes remain a major concern for the grain industry. Thermal treatments are commonly used to reduce the PHL of grains and their products without any chemical residues. Among which, radio frequency (RF) technology has been regarded as a promising alternative to traditional heating methods for improving safety and quality of food grains due to its fast, volumetric, and deep penetration heating characteristics. This review provided comprehensive information about principles of RF technology and its main applications including disinfestation, pasteurization, enzyme inactivation, drying, and roasting for processing food grains and their products. The methods to improve the RF heating uniformity and effects of RF heating on product quality were also reviewed. Finally, the current problems and recommendations for future work related to RF processing of grains and their products were discussed. This review would improve the understanding of RF heating for food grains and their products and promote the application of RF technology in the food grain industry.     

姜黄素的乳化和包埋及其应用研究进展

姜黄素是从姜科、天南星科中的一些植物的根茎中提取的一种化学成分,是植物界很稀少的具有二酮的色素。姜黄素作为我国允许使用的一种天然着色剂,具有一系列生物药理活性,但是其理化稳定性差、生物利用度低,往往需很大用量才能达到作用剂量,将其乳化包埋后不仅可以解决其溶解性的问题,还可以提高其生物利用率,应用前景十分广阔。该文通过总结国内外大量文献,阐述姜黄素的基本性质及其乳状液的基本性质和乳化包埋的方法,同时介绍姜黄素的创新应用,并对其发展前景作出展望。     

姜黄素乳液的研究进展

姜黄素是一种具有多种功能活性的天然多酚类色素,制备乳液对其进行包封,在解决其溶解度低、稳定性差、生物利用度低等问题上显示出较大的优势,并逐步扩大其在食品、医药领域的应用。本文介绍了姜黄素的基本性质以及姜黄素乳液的制备方法和稳定性,并对姜黄素的生物利用度进行综述,最后对其发展前景作出展望。     

Bidirectional interactions between dietary curcumin and gut microbiota

Abstract

Curcumin is a polyphenolic compound with a long history of use as an herbal remedy, dietary spice, and food-coloring agent. Despite curcumin possesses a wide range of biological and pharmacological activities, it exhibits extremely poor bioavailability, which makes its pharmacology intriguing and also hinders its clinical application. In recent years, there is ample evidence supporting the associations between the alteration of gut microbiota and many diseases. Interestingly, after oral administration, curcumin shows its preferential distribution and accumulation in the intestine. In view of the above aspects, we reviewed the updated knowledge regarding the bidirectional interactions between curcumin and gut microbiota from two perspectives: (1) gut microbiota regulation by curcumin and (2) curcumin biotransformation by digestive microbiota. Besides the study deals with 3 potential pharmacological implications: (1) identification of metabolites being more active and bioavaliable than parent curcumin; (2) assessment of contribution of gut microbiota regulation of curcumin to its pharmacological effects and (3) development of gut microbiota regulation-based disease prevention/treatment strategy for curcumin in view of its clinical safety. This review is important to deepen our understanding of the mechanisms of action of curcumin and to provide future directions about how to use this natural compound to combat human diseases.     

Improving the bioavailability of phenolic compounds by loading them within lipid-based nanocarriers

BackgroundPhenolic 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 approachIn 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 conclusionsIn 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.     

Emulsion electrospinning: Fundamentals,food applications and prospects

BackgroundIn 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 approachEmulsion 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 conclusionsRecent 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.     

Sulfated modification of polysaccharides: Synthesis,characterization and bioactivities

BackgroundPolysaccharides 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 approachThis 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 conclusionsThis 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.     

A state-of-the-art review on the elaboration of fish gelatin as bioactive packaging: Special emphasis on nanotechnology-based approaches

BackgroundThe last decade has noticed the expansion of green materials, which aims to reduce the human impact on the environment. Green polymers are clearly tendency subdivision of this stream and numerous bio-sourced plastics have been developed. Recent research has further focused on the development of new bio-based materials such as edible/biodegradable films for food products.Scope and approachFish gelatin (FG), a protein with recreatable reserve, biodegradability, and processability, has a remarkable potential in bio-packaging. However, there have been noticeable issues concerning the use of FG as packing material, including its low mechanical strength, poor moisture stability, and poor water barrier properties. This paper aims to review the state-of-the-art in development of FG-based films and highlights how they play a crucial role in modifying the properties of such films. Various types of nanofillers that have been included into FG to fabricate bio-nanocomposite films, such as nanoclays (montmorillonite, sepiolite), polysaccharide nanofillers (nanowhiskers/nanofibers), metal ions (silver, copper) and metal oxides nanoparticles (ZnO, TiO₂) are reviewed.Key findings and conclusionsCross-linking is a promising technique to improve the performance and applicability of FG-based biomaterials, particularly respecting their water sensitivity, which hinders many of their potential uses as food contact materials. Bio-nanocomposite technology may help to make high-performance materials with extra bio-functional properties, and it is anticipated to be a dynamic research in the future. In general, more research is required to ameliorate application processes of FG films, especially physical aspects, to be suitable for bio-packaging application.