A comprehensive review on Ginger (Zingiber officinale) as a potential source of nutraceuticals for food formulations: Towards the polishing of gingerol and other present biomolecules

Deep eutectic solvents in food contaminants detection: Characteristics, interaction mechanism and application advances from extracting to other roles

Food safety is crucial for public health, yet it faces growing threats from environmental and anthropogenic pollutants. Deep eutectic solvents (DESs) have emerged as green and efficient alternative solvents for detecting trace pollutants. This review highlights the characteristics of DESs, their mechanisms for extracting target analytes and applications in food analysis. Subsequently, the challenges faced by DESs in the detection of food samples and future development trends are further discussed. DESs can selectively interact with various target analytes (including pesticides, veterinary drugs, food additives, heavy metals, toxins, and other residues) during the food safety testing process by forming hydrogen bond networks. Beyond serving as extraction solvents, DESs can act as adsorbents, eluents, and reaction media, thereby simplifying sample pretreatment and enhancing the detection performance of various contaminants. Overall, as customizable functional solvents, DESs hold great promise for advancing next-generation food analysis methods, though some technical barriers remain to be addressed.

Harnessing the power of ginger leaf polysaccharide: A potential strategy to combat Aβ-induced toxicity through the Wnt/β-catenin pathway

Alzheimer's disease (AD) is prevalent in the elderly, with amyloid-β (Aβ) playing a critical role in its progression. Polysaccharides have garnered increasing attention due to their low toxicity and diverse applications in alleviating AD-like symptoms. However, the potential of ginger leaf polysaccharide in mitigating AD-like symptoms has been rarely investigated. In this study, we isolated a polysaccharide (GLP1) from ginger leaf and evaluated its efficacy and underlying mechanisms in alleviating AD-like symptoms using Caenorhabditis elegans and PC12 cells. GLP1 ameliorated AD-like symptoms in C. elegans, as evidenced by a 41.50 % increase in head thrashing frequency and an 87.13 % increase in body bending frequency. Furthermore, GLP1 mitigated cognitive decline by 76.51 %. Additionally, GLP1 enhanced the activity of acetylcholinesterase in C. elegans and maintained the integrity of neural system function. Moreover, GLP1 improved the survival rate of PC12 cells under Aβ induction by activating the Wnt/β-catenin pathway, which also resulted in a reduction in the release of inflammatory factors, specifically IL-1β by 21.15 %, IL-6 by 39.98 %, and TNF-α by 19.66 %. Notably, FITC-labeled GLP1 could be absorbed by PC12 cells. These compelling findings underscored the therapeutic potential of GLP1 in alleviating Aβ-induced AD-like symptoms and supported the advancement of ginger leaf resource utilization.

Methyl jasmonate enabled maintained the postharvest flavor quality of ginger (Zingiber officinale roscoe) by reducing the loss of terpene volatile compounds

Ginger, as a globally vital medicinal and food homologous crop, plays an irreplaceable role in human diet and healthcare. However, during the storage of ginger, the decline of physical properties and degradation of volatile flavor quality have emerged as an industrial concern that severely restricts the market value of the product. MeJA plays an essential role in extending fruit shelf life and regulate the synthesis of volatiles in horticultural products, yet its application in ginger remains unreported. This study investigated whether MeJA could delay the deterioration of external quality and the loss of volatile compounds, thereby maintaining the flavor quality of ginger during storage. The results demonstrated that MeJA retarded weight loss, moisture reduction, texture softening, and color darkening in ginger rhizomes during storage. In addition, dynamic profiles of volatile compounds in the postharvest stage of ginger rhizomes were characterized via HS-SPME/GC-MS methodology. A total of 67 volatile components were identified and quantified precisely, which were divided into terpenes, alcohols, esters, aldehydes, ketones, and others. Terpenes represented by zingiberene, farnesene, β-sesquiphellandrene, α-curcumene, (E)-β-farnesene, and β-elemene, was the most abundant classification of compounds in ginger, comprising approximately 70 % of the total content. Compared with the control group, MeJA reduced the loss rate of total quantity and total content of volatiles, while effectively slowed the loss of various volatiles, especially after 35d of storage. Furthermore, 30 characteristic components with an odor activity values (OAVs) ≥ 1 were identified, predominantly exhibiting spicy, green, floral, fatty, and fruity fragrances. It is noteworthy that the most prominent scent of ginger is the spicy aroma, which can be significantly up-regulated by MeJA. Moreover, MeJA treatment was found to enhance the expression levels of terpene-related genes in ginger. This study clarified the patterns of variation in physical properties, volatile compounds, and aroma intensity during the storage of ginger, providing a theoretical basis for mitigating the deterioration of flavor quality in ginger rhizomes during postharvest storage. This research holds significant importance for promoting the comprehensive utilization and high-quality development of ginger.

Carbon dots derived from Zingiber officinale Rosc (ginger) with hemostatic effects

Introduction

Ginger, as a traditional Chinese medicine (TCM), can be used in clinical practice to treat various diseases. The product of ginger processed at high temperatures is called carbonized ginger (CG), which has a hemostatic effect that ginger originally did not have. The purpose of this study is to investigate the hemostatic effect of CG and the substances that exert hemostatic effects.

Methods

CG was prepared and successfully obtained CG carbon dots (CG-CDs) from its aqueous solution. After fully characterizing its structural information, the hemostatic effect was evaluated using mouse tail bleeding and liver injury bleeding models, and the clotting time was evaluated using capillary coagulation experiments. In addition, the hemostatic mechanism of CG-CDs was explored.

Results

The average particle size of CG-CDs was observed to be 4.07 nm and the lattice spacing was 0.216 nm. It was mainly composed of graphite structured carbon, with the main constituent elements being C, N, and O, containing functional groups such as C=N, C=O, and C-OH. The FL spectrum showed that the maximum excitation wavelength of CG-CDs was 360 nm, and the maximum emission wavelength was 470 nm. The QY of CG-CDs was calculated to be 0.45%. CG-CDs shortened bleeding time, reduced bleeding volume, and also shortened the time for blood clotting. With the increase of CG-CDs, the values of FIB gradually increased, and the PT values gradually decreased. In addition, CG-CDs increased PLT count, increased PLT activating factor TXB2, decreased 6-keto-PGF1α , increased PAI-1, and decreased t-PA.

Conclusion

CG-CDs obtained from CG has hemostatic activity, mainly by activating exogenous coagulation and co-coagulation pathways, increasing PLT count, increasing PLT activating factor TXB2, reducing 6-keto-PGF1α , increasing PAI-1, and reducing t-PA, thereby affecting the fibrinolytic system and other pathways to exert hemostatic effects.

Development of a sodium hyaluronate-enriched therapeutic formulation with stevia glycoside and mogroside V for the comprehensive management of diabetes and its complications

Diabetes prevalence continues to increase as a result of people's increasing sugar intake. Diabetes mellitus and its complications (dry skin, constipation, depression, and dental caries), as well as the prohibition of sweets ingestion, seriously affect patients' physical and mental health. Therefore, it is crucial to develop a long-term food for special medical purposes (FSMP) that aids in managing diabetes and its complications. To ensure effective biomedical function and taste, we developed a FSMP beverage formulation containing stevia glycoside, mogroside V, and sodium hyaluronate (SMH-B), each at a concentration of 0.1 mg/mL. Meanwhile, this study verified that SMH-B is an environmentally friendly and biocompatible formulation. Furthermore, both in vivo and in vitro studies have demonstrated that SMH-B significantly lowers blood glucose and lipid levels, enhances skin moisture and elasticity, prevents dental caries, alleviates constipation, reduces oxidative stress, and mitigates depressive symptoms. Notably, the SMH-B compound formula exhibits a more effective adjuvant therapeutic effect compared to single-ingredient formulation composed of stevia glycosides, mogroside V, and sodium hyaluronate. Moreover, SMH-B provides the sweetness desired by diabetic patients without affecting blood glucose levels, while also offering an auxiliary therapeutic role, making it a potential FSMP for diabetes management.

Ginger leaf polyphenols mitigate β-amyloid toxicity via JNK/FOXO pathway activation in Caenorhabditis elegans

β-Amyloid (Aβ) aggregation is the major pathological feature of Alzheimer's disease (AD), resulting in oxidative stress and further exacerbating Aβ aggregation. Ginger leaf polyphenols (GLP) have been found to possess antioxidant activity, evidencing their potential in addressing AD. GLP is mainly composed of 12 polyphenols, 8 organic acids, and 6 glycosides, of which polyphenols are predominantly composed of apigenin, kaempferol, and quercetin derivatives. Moreover, GLP alleviates reproductive toxicity, longevity toxicity, and neurotoxicity induced by Aβ via regulating the antioxidase system in Caenorhabditis elegans. As shown by the network pharmacology results, GLP might activate the JNK/Foxo signaling pathway to regulate the antioxidase system, which was evidenced by the up-regulation of gene expression levels of jnk-1, daf-16, sod-3, and hsp-16.2. Overall, GLP might be a potential antioxidant for combating AD.

An overview of the research progress on Aconitum carmichaelii Debx.:active compounds, pharmacology, toxicity, detoxification, and applications

ETHNOPHARMACOLOGICAL RELEVANCE

Aconitum carmichaelii Debx. is the most widely distributed species of Aconitum plants in China and has a long history of medicinal use. Because of its toxicity, A. carmichaelii is classified as lower class in the Shennong Bencao Jing (Shennong's Classic of Materia Medica). According to the theory of Chinese medicine, the roots can be used to revive yang for resuscitation, dispel wind, remove dampness, and relieve pain.

AIMS OF THE REVIEW

This review focuses on summarizing the latest reports on the components, pharmacology, toxicity, detoxification mechanism and application of A. carmichaelii. It aims to provide ideas for in-depth research on activity mechanism of A. carmichaelii and expanding the value of exploitation and utilization.

MATERIALS AND METHODS

Information was collected from the following online scientific databases: PubMed, Web of Science, Wiley Online Library, SciFinder, Scopus, PubChem, China National Knowledge Internet (CNKI), etc. Additional data were obtained from other Chinese medicine books.

RESULTS

In this review, 224 compounds were categorized and new compounds discovered in the last five years were highlighted. The main components of A. carmichaelii are C19-diterpene alkaloids(C19-DAs), among which diester-type aconitine is the most toxic and also the main active ingredient, while monoester diterpene alkaloids (MDAs) and aminol diterpene alkaloids (ADAs) are greatly toxicity reduced due to the loss of ester bond. Heating and compatibility are the means to increase the efficiency and reduce the toxicity of A. carmichaelii. In addition, it also contains abundant C20-diterpene alkaloids (C20-DAs). Like C19-DAs, these compounds also have cardiotonic, anticancer, anti-inflammatory and analgesic pharmacological effects, but their toxicity is weaker. The above-ground part contains not only a variety of MDAs and ADAs, but also contains abundant non-diterpenoid alkaloids and active polysaccharides. In addition to pharmacological effects, we further summarized the mechanisms of cardiotoxicity, neurotoxicity and other toxicity of A. carmichaelii. What's more, the application prospects are also discussed. Polysaccharides and diterpenoid alkaloids in A. carmichaelii and related traditional prescriptions have great promising prospects for the development of new drugs.

CONCLUSION

A. carmichaelii has rich alkaloids and polysaccharides, but the new compounds discovered in recent years are only in the activity screening stage. The toxic differences between C19- and C20- DAs and the dose that affect toxicity of A. carmichaelii are still not clear. The non-traditional medicinal parts, such as stems and leaves, show great potential for development and utilization. More extensive and in-depth exploration of low-toxic active compounds, as well as the mechanism of efficacy-enhancement and toxicity-attenuation, will help A. carmichaelii to be better and safer used for clinical.

A glimpse on influences of ginger and its derivatives as a feed additive in finfish farming: A mini-review

Ginger (Zingiber officinale) has emerged as a promising feed additive in aquaculture due to its reported benefits for fish health and growth. Possessing a range of bioactive compounds, ginger exhibits antimicrobial, anti-parasite, immunostimulatory, anti-inflammatory, anti-oxidative, and growth-promoting properties. This review provides a comprehensive overview of recent research on dietary ginger and its derivatives for fish. It explores the various forms, bioactive compounds, biological activities, and preparation methods of these feed additives. The discussion focuses on the impacts of dietary ginger and its derivatives on growth performance, flesh quality, hematology profile, antioxidative responses, immune system, and disease resistance stimulation in fish. Additionally, the review examines the mechanisms of action of these additives and explores the optimal supplementation levels for inclusion in fish diets. Previous studies reported the optimal doses of dietary ginger and its derivatives were ranged from 0.0002 to 4 % of diet whereas 0.0004 % for bathing treatment. Bioactive compounds such as phenolic acids, flavonoids, zingerone, gingerols, shogaols, and paradols were responsible to the ginger and its derivatives beneficial effects. Overall, the findings suggest that dietary ginger and its derivatives hold significant promise for enhancing growth and health in fish farming.

A comprehensive review of effects of ultrasound pretreatment on processing technologies for food allergens: Allergenicity, nutritional value, and technofunctional properties and safety assessment

Many proteins are essential food components but also major allergens. Reducing protein allergenicity while preserving its nutritional value and technofunctional properties has always been the goal of the food industry. Ultrasound (US) is a green processing method for modifying proteins. In addition, US pretreatment combined with other processing techniques (USPCT) has been increasingly used in the food industry. Therefore, this review presents an overview of recent advances in the impact of US and USPCT (US-combined enzymatic hydrolysis [USCE], US-combined glycation [USCG], and US-combined polyphenol conjugation [USCP]) on the allergenicity, nutritional value, and technofunctional properties of food allergens. We discuss the potential mechanisms, advantages, and limitations of these technologies for improving the properties of proteins and analyze their safety, challenges, and corresponding solutions. It was found that USPCT can improve the efficiency and effectiveness of different methods, which in turn can be more effective in reducing protein allergenicity and improving the nutritional value and functional properties of processed products. Future research should start with new processing methods, optimization of process conditions, industrial production, and the use of new research techniques to promote technical progress. This paper is expected to provide reference for the development of high-quality hypoallergenic protein raw materials.

Fermented soy products: A review of bioactives for health from fermentation to functionality

The increasing prevalence of metabolic diseases and the global drive toward achieving Sustainable Development Goals (SDGs) underscore the need for sustainable, nutrient-dense foods. Soybeans (Glycine max), a critical global crop, offer promising solutions; however, their predominant use as animal feed raises concerns regarding food security and environmental sustainability. Fermented soy products-including tempeh, natto, and miso-are rich in bioactive compounds such as peptides and isoflavones, which offer potential therapeutic effects and hold cultural and nutritional significance. These fermented products provide bioactive profiles with unique health-promoting properties. This review critically examines the bioactive compounds generated through fermentation, focusing on their bioconversion pathways in the gastrointestinal tract and their metabolic implications for human health. Recent consumer demand for novel food ingredients with additional biological benefits has fueled research into advanced extraction techniques, enhancing the functional applications of bioactive compounds from these soy-based products. This review further explores innovations in extraction methods that improve bioactive yield and sustainability, reinforcing the applicability of these compounds in health-promoting food interventions. The originality of this review lies in its in-depth exploration of the gastrointestinal bioconversion of fermented soy bioactive compounds alongside the latest sustainable extraction methods designed to optimize their use. Future research should aim to refine fermentation and extraction processes, investigate synergistic microbial interactions, and develop environmentally sustainable production methods. These efforts have the potential to position fermented soy products as essential contributors to global nutritional security and sustainable food systems, addressing both public health and environmental needs.

Biodegradable composites of modified holocellulose, poly(butylene adipate-co-terephthalate), and polylactic acid: Preparation and properties

Holocellulose was extracted from corn cobs by a deep eutectic solvent and modified by various carboxylic acids. The resulting holocellulose esters were further blended with poly(butylene adipate-co-terephthalate) (PBAT) and polylactic acid (PLA) by using a solvent casting method to prepare holocellulose ester/PBAT/PLA composites. The mechanical properties of the composites were affected by the length of the ester side chain of the modified holocellulose. The addition of lauric acid-modified holocellulose, i.e., holocellulose laurate (HCL), effectively improved the compatibility between the components in the composite, and the composite with 4 wt% HCL showed good comprehensive properties. Compared with PBAT/PLA, HCL/PBAT/PLA composite had better mechanical properties, water stability and gas barrier stability, and similar thermal stability. The elongation at break increased by 41.0 %, while the water absorption capacity, water vapor permeability and oxygen permeability decreased significantly. The HCL/PBAT/PLA composite also demonstrated good reprocessability and simulated transport properties. There were no significant changes in the mechanical properties and structure after five cycles of reprocessing and simulated transport, and the mechanical property retention rates were 93.7 % and 95.2 %, respectively. The results showed that modified holocellulose can be used as a toughening agent and filler, which can expand the application of lignocellulose in the field of biodegradable packaging materials.

Multi-functional reinforced food packaging using delivery carriers: A comprehensive review of preparation, properties, and applications

With the rapid development of globalization, food packaging takes on more responsibility, while guaranteeing product quality and safety. In this context, the health risks associated with chemically synthesized additives and inorganic nanoparticles have opened a new chapter in the reinforcement of food packaging with natural active ingredients. Various delivery carriers have been developed to overcome the limitations of poor stability, uneven dispersion, and low bioavailability of natural active ingredients. The combination of encapsulation technologies can increase the biocompatibility of the active ingredient with the packaging material. Moreover, the protective and slow-release effects of the carrier matrix on the active ingredients are desirable for the reinforcement of food packaging. This review presents the latest advances in the application of delivery systems in food packaging, including the types of delivery systems used in food packaging, reinforced properties of food packaging, and potential applications in the food industry. Previous scientific studies found that active ingredient-loaded delivery carriers increased the effectiveness of food packaging in preventing food spoilage. Furthermore, the integration of active packaging with smart food packaging exhibits the synergistic effects of freshness monitoring and quality preservation. This review also discusses the challenges and trends in reinforcing food packaging with delivery carriers under a synergistic strategy that will provide new ideas and insights for the development and application of innovative food packaging.

Supramolecular deep eutectic solvents: Current advances and critical evaluation of cyclodextrins from solute to solvent in emerging functional food

The acceptance of nonconventional solvents as viable substitutes for traditional organic solvents has been widely recognized in order to comply with food-safety and sustainability regulations. Cyclodextrins (CDs), derived from starch, are cyclic oligosaccharides with the ability to form inclusion complexes with a variety of functional substances as the result of their distinctive structure, which enables them to effectively encapsulate bioactive compounds, rendering them highly sought after for use in food applications. In the implementing plan to achieve carbon-neutral emissions by 2050, the novel generation of supramolecular deep eutectic solvents (SUPRADES) has garnered increased attention and interest. The approach of utilizing SUPRADES as emerging solvents was just beginning to be applied to food studies. This review summarizes a revision of the current advances and critical evaluation of cyclodextrin-based SUPRADES (CD-based SUPRADES) as promising solvents for the enhancement of the extraction efficiency, solubilization and stability of bioactive compounds, adsorption and separation of food components, packaging materials, and modification of biopolymers. To meet the sustainable processing needs of the food industry, the emerging categories of CD-based SUPRADES need to be further fabricated. Herein, our review will sort out the potential application of CD-based SUPRADES in the food industry, aiming to provide a better understanding of CD-based SUPRADES within the viewpoint of food science. Formulation intricacies and scalability issues in real functional foods using CD-based SUPRADES as media need more efforts.

Gelatin-chitosan interactions in edible films and coatings doped with plant extracts for biopreservation of fresh tuna fish products: A review

The preservation of tuna fish products, which are extremely perishable seafood items, is a substantial challenge due to their instantaneous spoilage caused by microbial development and oxidative degradation. The current review explores the potential of employing chitosan-gelatin-based edible films and coatings, which are enriched with plant extracts, as a sustainable method to prolong the shelf life of tuna fish products. The article provides a comprehensive overview of the physicochemical properties of chitosan and gelatin, emphasizing the molecular interactions that underpin the formation and functionality of these biopolymer-based films and coatings. The synergistic effects of combining chitosan and gelatin are explored, particularly in terms of improving the mechanical strength, barrier properties, and bioactivity of the films. Furthermore, the application of botanical extracts, which include high levels of antioxidants and antibacterial compounds, is being investigated in terms of their capacity to augment the protective characteristics of the films. The study also emphasizes current advancements in utilizing these composite films and coatings for tuna fish products, with a specific focus on their effectiveness in preventing microbiological spoilage, decreasing lipid oxidation, and maintaining sensory qualities throughout storage. Moreover, the current investigation explores the molecular interactions associated with chitosan-gelatin packaging systems enriched with plant extracts, offering valuable insights for improving the design of edible films and coatings and suggesting future research directions to enhance their effectiveness in seafood preservation. Ultimately, the review underscores the potential of chitosan-gelatin-based films and coatings as a promising, eco-friendly alternative to conventional packaging methods, contributing to the sustainability of the seafood industry.

Impact of high-pressure processing on the bioactive compounds of milk - A comprehensive review

High-pressure processing (HPP) is a promising alternative to thermal pasteurization. Recent studies highlighted the effectivity of HPP (400-600 MPa and exposure times of 1-5 min) in reducing pathogenic microflora for up to 5 logs. Analysis of modern scientific sources has shown that pressure affects the main components of milk including fat globules, lactose, casein micelles. The behavior of whey proteins under HPP is very important for milk and dairy products. HPP can cause significant changes in the quaternary (> 150 MPa) and tertiary (> 200 MPa) protein structures. At pressures > 400 MPa, they dissolve in the following order: αs2-casein, αs1-casein, k-casein, and β-casein. A similar trend is observed in the processing of whey proteins. HPP can affect the rate of milk fat adhering as cream with increased results at 100-250 MPa with time dependency while decreasing up to 70% at 400-600 MPa. Some studies indicated the lactose influencing casein on HP, with 10% lactose addition in case in suspension before exposing it to 400 MPa for 40 min prevents the formation of large casein micelles. Number of researches has shown that moderate pressures (up to 400 MPa) and mild heating can activate or stabilize milk enzymes. Pressures of 350-400 MPa for 100 min can boost the activity of milk enzymes by up to 140%. This comprehensive and critical review will benefit scientific researchers and industrial experts in the field of HPP treatment of milk and its effect on milk components.

Graphical abstract

Advances and challenges in the fractionation of edible oils and fats through supercritical fluid processing

Petrochemical solvents are widely used for the extraction and fractionation of biomolecules from edible oils and fats at an industrial scale. However, owing to its safety concerns, toxicity, price fluctuations, and sustainability, alternative solvents and technologies have been actively explored in recent years. Technologies, such as ultrasound and microwave-assisted extraction, supercritical carbon dioxide extraction, supercritical fluid fractionation, and sub-critical water extraction, and solvents, like ionic liquids and deep eutectic solvents, are reported for extraction and fractionation of biomolecules. Among them, supercritical carbon dioxide extraction and fractionation are some of the most promising green technologies with the potential to replace petrochemical-based conventional techniques. The addition of cosolvents, such as water, ethanol, and acetone, improves the extraction of amphiphilic and polar compounds from edible oils and fats. Supercritical fluid processing has diverse applications, including concentration of solutes, selective separation of desired molecules, and separation of undesirable compounds from the feed material. Temperature, pressure, particle size, porosity, flow rate, solvent-to-feed ratio, density, viscosity, diffusivity, solubility, partition coefficient, and separation factor are the fundamental factors governing the extraction and fractionation of desired biomolecules from lipids. Supercritical fluids stand alone compared to conventional fluids, because of their tunable solvent properties. Overall, it is to be noted that supercritical fluid-based methods have lots of scope to replace conventional solvent-based methods and progress toward the creation of sustainable food-processing techniques. This review critically evaluates the parameters responsible for the extraction and fractionation of biomolecules from edible oils and fats under supercritical conditions.

The emulsifying capacity and stability of potato proteins and peptides: A comprehensive review

The potato has recently attracted more attention as a promising protein source. Potato proteins are commonly extracted from potato fruit juice, a byproduct of starch production. Potato proteins are characterized by superior techno-functional properties, such as water solubility, gel-forming, emulsifying, and foaming properties. However, commercially isolated potato proteins are often denatured, leading to a loss of these functionalities. Extensive research has explored the influence of different conditions and techniques on the emulsifying capacity and stability of potato proteins. However, there has been no comprehensive review of this topic yet. This paper aims to provide an in-depth overview of current research progress on the emulsifying capacity and stability of potato proteins and peptides, discussing research challenges and future perspectives. This paper discusses genetic diversity in potato proteins and various methods for extracting proteins from potatoes, including thermal and acid precipitation, salt precipitation, organic solvent precipitation, carboxymethyl cellulose complexation, chromatography, and membrane technology. It also covers enzymatic hydrolysis for producing potato-derived peptides and methods for identifying potato protein-derived emulsifying peptides. Furthermore, it reviews the influence of factors, such as physicochemical properties, environmental conditions, and food-processing techniques on the emulsifying capacity and stability of potato proteins and their derived peptides. Finally, it highlights chemical modifications, such as acylation, succinylation, phosphorylation, and glycation to enhance emulsifying capacity and stability. This review provides insight into future research directions for utilizing potato proteins as sustainable protein sources and high-value food emulsifiers, thereby contributing to adding value to the potato processing industry.

Mangiferin: A comprehensive review on its extraction, purification and uses in food systems

With the target of fabricating healthier products, food manufacturing companies look for natural-based nutraceuticals that can potentially improve the physicochemical properties of food systems while being nutritive to the consumer and providing additional health benefits (biological activities). In this regard, Mangiferin joins all these requirements as a potential nutraceutical, which is typically contained in Mangifera indica products and its by-products. Unfortunately, knowing the complex chemical composition of Mango and its by-products, the extraction and purification of Mangiferin remains a challenge. Therefore, this comprehensive review revises the main strategies proposed by scientists for the extraction and purification of Mangiferin. Importantly, this review identifies that there is no report reviewing and criticizing the literature in this field so far. Our attention has been targeted on the timely findings on the primary extraction techniques and the relevant insights into isolation and purification. Our discussion has emphasized the advantages and limitations of the proposed strategies, including solvents, extracting conditions and key interactions with the target xanthone. Additionally, we report the current research gaps in the field after analyzing the literature, as well as some examples of functional food products containing Mangiferin.

A comprehensive review on novel synthetic foods: Potential risk factors, detection strategies, and processing technologies

Nowadays, the food industry is facing challenges due to the simultaneous rise in global warming, population, and food consumption. As the integration of synthetic biology and food science, novel synthetic foods have obtained high attention to address these issues. However, these novel foods may cause potential risks related to human health. Four types of novel synthetic foods, including plant-based foods, cultured meat, fermented foods, and microalgae-based foods, were reviewed in the study. The original food sources, consumer acceptance, advantages and disadvantages of these foods were discussed. Furthermore, potential risk factors, such as nutritional, biological, and chemical risk factors, associated with these foods were described and analyzed. Additionally, the current detection methods (e.g., enzyme-linked immunosorbent assay, biosensors, chromatography, polymerase chain reaction, isothermal amplification, and microfluidic technology) and processing technologies (e.g., microwave treatment, ohmic heating, steam explosion, high hydrostatic pressure, ultrasound, cold plasma, and supercritical carbon dioxide) were reviewed and discussed critically. Nonetheless, it is crucial to continue innovating and developing new detection and processing technologies to effectively evaluate these novel synthetic foods and ensure their safety. Finally, approaches to enhance the quality of these foods were briefly presented. It will provide insights into the development and management of novel synthetic foods for food industry.

Pruned tea biomass plays a significant role in functional food production: A review on characterization and comprehensive utilization of abandon-plucked fresh tea leaves

Tea is the second largest nonalcoholic beverage in the world due to its characteristic flavor and well-known functional properties in vitro and in vivo. Global tea production reaches 6.397 million tons in 2022 and continues to rise. Fresh tea leaves are mainly harvested in spring, whereas thousands of tons are discarded in summer and autumn. Herein, pruned tea biomass refers to abandon-plucked leaves being pruned in the non-plucking period, especially in summer and autumn. At present, no relevant concluding remarks have been made on this undervalued biomass. This review summarizes the seasonal differences of intrinsic metabolites and pays special attention to the most critical bioactive and flavor compounds, including polyphenols, theanine, and caffeine. Additionally, meaningful and profound methods to transform abandon-plucked fresh tea leaves into high-value products are reviewed. In summer and autumn, tea plants accumulate much more phenols than in spring, especially epigallocatechin gallate (galloyl catechin), anthocyanins (catechin derivatives), and proanthocyanidins (polymerized catechins). Vigorous carbon metabolism induced by high light intensity and temperature in summer and autumn also accumulates carbohydrates, such as soluble sugars and cellulose. The characteristics of abandon-plucked tea leaves make them not ideal raw materials for tea, but suitable for novel tea products like beverages and food ingredients using traditional or hybrid technologies such as enzymatic transformation, microbial fermentation, formula screening, and extraction, with the abundant polyphenols in summer and autumn tea serving as prominent flavor and bioactive contributors.

A Comparative Study of Encapsulation of β-Carotene via Spray-Drying and Freeze-Drying Techniques Using Pullulan and Whey Protein Isolate as Wall Material

The encapsulation of β-carotene was investigated using pullulan and whey protein isolate (WPI) as a composite matrix at a weight ratio of 20:80, employing both spray-drying and freeze-drying techniques. The influence of processing parameters such as the concentration of wall material, flow rate, and inlet temperature for SP encapsulants, as well as wall-material concentration for FZ encapsulants, was examined in terms of encapsulation efficiency (EE). The morphology, structural characterization, moisture sorption isotherms, and thermal properties of the resulting encapsulants at optimum conditions were determined. Their stability was investigated under various levels of water activity, temperature conditions, and exposure to UV-Vis irradiation. β-carotene was efficiently encapsulated within SP and FZ structures, resulting in EE of approximately 85% and 70%, respectively. The degradation kinetics of β-carotene in both structures followed a first-order reaction model, with the highest rate constants (0.0128 day-1 for SP and 0.165 day-1 for FZ) occurring at an intermediate water-activity level (aw = 0.53) across all storage temperatures. The photostability tests showed that SP encapsulants extended β-carotene's half-life to 336.02 h, compared with 102.44 h for FZ encapsulants, under UV-Vis irradiation. These findings highlight the potential of SP encapsulants for applications in functional foods, pharmaceuticals, and carotenoid supplements.

Nutraceuticals and dietary supplements: balancing out the pros and cons

While the market is full of different dietary supplements, in most countries, legislation is clear and strict towards these products, with severe limitations on their health claims. Overall, the claims cannot go beyond the consumption of a said supplement will contribute to a healthy diet. Thus, the supplement industry has been reacting and changing their approach to consumers. One change is the considerable growth of the nutraceutical market, which provides naturally produced products, with low processing and close to no claims on the label. The marketing of this industry shifts from claiming several benefits on the label (dietary supplements) to relying on the knowledge of consumers towards the benefits of minimally processed foods filled with natural products (nutraceuticals). This review focuses on the difference between these two products, their consumption patterns, forms of presentation, explaining what makes them different, their changes through time, and their most notable ingredients, basically balancing out their pros and cons.

Composite 2D Material-Based Pervaporation Membranes for Liquid Separation: A Review

Today, chemistry and nanotechnology cover molecular separations in liquid and gas states by aiding in the design of new nano-sized materials. In this regard, the synthesis and application of two-dimensional (2D) nanomaterials are current fields of research in which structurally defined 2D materials are being used in membrane separation either in self-standing membranes or composites with polymer phases. For instance, pervaporation (PV), as a highly selective technology for liquid separation, benefits from using 2D materials to selectively transport water or other solvent molecules. Therefore, this review paper offers an interesting update in revising the ongoing progress of PV membranes using 2D materials in several applications, including solvent purification (the removal of water from organic systems), organics removal (the removal of organic molecules diluted in water systems), and desalination (selective water transport from seawater). In general, recent reports from the past 3 years have been discussed and analyzed. Attention has been devoted to the proposed strategies and fabrication of membranes for the inclusion of 2D materials into polymer phases. Finally, the future trends and current research gaps are declared for the scientists in the field.

Valorization of Cork Stoppers, Coffee-Grounds and Walnut Shells in the Development and Characterization of Pectin-Based Composite Films: Physical, Barrier, Antioxidant, Genotoxic, and Biodegradation Properties

The development of sustainable materials from the valorization of waste is a good alternative to reducing the negative environmental impact of plastic packaging. The objectives of this study were to develop and characterize pectin-based composite films incorporated with cork or cork with either coffee grounds or walnut shells, as well as to test the films' genotoxicity, antioxidant properties, and biodegradation capacity in soil and seawater. The addition of cork, coffee grounds, or walnut shells modified the films' characteristics. The results showed that those films were thicker (0.487 ± 0.014 mm to 0.572 ± 0.014 mm), more opaque (around 100%), darker (L* = 25.30 ± 0.78 to 33.93 ± 0.84), and had a higher total phenolic content (3.17 ± 0.01 mg GA/g to 4.24 ± 0.02 mg GA/g). On the other hand, the films incorporated only with cork showed higher values of elongation at break (32.24 ± 1.88% to 36.30 ± 3.25%) but lower tensile strength (0.91 ± 0.19 MPa to 1.09 ± 0.08 MPa). All the films presented more heterogeneous and rougher microstructures than the pectin film. This study also revealed that the developed films do not contain DNA-reactive substances and that they are biodegradable in soil and seawater. These positive properties could subsequently make the developed films an interesting eco-friendly food packaging solution that contributes to the valorization of organic waste and by-products, thus promoting the circular economy and reducing the environmental impact of plastic materials.

Impact of Air-Drying Temperatures on Drying Kinetics, Physicochemical Properties, and Bioactive Profile of Ginger

Ginger (Zingiber officinale Roscoe) is a perishable commodity that requires proper processing to maintain its bioactivity. This study evaluated the effect of different air-drying temperatures (50 °C, 60 °C, and 70 °C) on ginger's drying kinetics and quality attributes. For an enhanced understanding of the drying kinetics, we employed a detailed approach by combining an existing drying model (namely, Midilli) with the Arrhenius model. This combined model facilitates a thorough analysis of how temperature and time concurrently affect the moisture ratio, offering more profound insights into the drying mechanism. A higher drying rate was achieved at 70 °C, yet elevated drying temperatures could compromise the quality attributes of ginger slices. Ginger slices dried at 50 °C displayed improved physicochemical properties and less color browning. The evaluation of the bioactivity profile of resultant ginger extracts also revealed higher total phenolic contents (1875.87 ± 31.40 mg GAE/100 g) and DPPH radical scavenging activity (18.2 ± 0.9 mg TE/kg) in 50 °C treated ginger samples. Meanwhile, the hydroethanolic mixture (70% ethanol) was also reorganized with better extraction efficiency than water and MWF (a ternary blend of methanol, water, and formic acid) solution. The promising outcomes of this study endorse the influence of drying temperature on the quality characteristics and bioactive profile of ginger and the selection of suitable extraction solvents to acquire phenolic-rich extract.

Preparation of Edible Colorant Lake Using Calcium Carbonate and β-Carotene: Structural Characterization and Formation Mechanism Study

This study prepared a novel β-carotene colorant lake using calcium carbonate (CaCO3) and investigated the lake formation process and its basic characteristics. Kinetic adsorption analysis confirmed that medium pH (9.3) and medium temperature (40 °C) were more suitable for lake preparation, while desorption occurred, possibly due to crystalline transformation of CaCO3. The isothermal analysis and model fitting results suggested that the β-carotene and CaCO3 particles combined via a monolayer adsorption process driven by physical force. Electrostatic attraction likely participated in the process due to the net negative surface charges of β-carotene dispersion and positively charged groups on the CaCO3 particle surfaces. Ethanol, ultrasonic treatment, and drying method significantly influenced the immobilization efficiency (IE) of β-carotene in the lake and light stability of the lake, without affecting its crystal form. The thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC) curves confirmed absorption of β-carotene onto CaCO3. Fourier-transform infrared spectroscopy (FTIR) and X-ray photoelectron spectroscopy (XPS) analyses indicated no obvious chemical bonds between β-carotene and CaCO3. Energy-dispersive spectroscopy (EDS) confirmed the presence of β-carotene on surfaces but not in the interior of the CaCO3 particles. The adsorption of β-carotene by calcium carbonate was further confirmed to be a physical adsorption on surface.

Extraction of High Value Products from Zingiber officinale Roscoe (Ginger) and Utilization of Residual Biomass

Zingiber officinale Roscoe (ginger) is a plant from the Zingiberaceae family, and its extracts have been found to contain several compounds with beneficial bioactivities. Nowadays, the use of environmentally friendly and sustainable extraction methods has attracted considerable interest. The main objective of this study was to evaluate subcritical propane (scPropane), supercritical CO2 (scCO2), and supercritical CO2 with ethanol (scCO2 + EtOH) as co-solvent methods for the extraction of high value products from ginger. In addition, the reuse/recycling of the secondary biomass in a second extraction as a part of the circular economy was evaluated. Both the primary and the secondary biomass led to high yield percentages, ranging from 1.23% to 6.42%. The highest yield was observed in the scCO2 + EtOH, with biomass prior used to scCO2 extraction. All extracts presented with high similarities as far as their total phenolic contents, antioxidant capacity, and chemical composition. The most abundant compounds, identified by the two different gas chromatography-mass spectrometry (GC-MS) systems present, were a-zingiberene, β- sesquiphellandrene, a-farnesene, β-bisabolene, zingerone, gingerol, a-curcumene, and γ-muurolene. Interestingly, the reuse/recycling of the secondary biomass was found to be promising, as the extracts showed high antioxidant capacity and consisted of significant amounts of compounds with beneficial properties.

Extraction pathways and purification strategies towards carminic acid as natural-based food colorant: A comprehensive review

As a current trend of fabricating healthier products, food manufacturing companies seek for natural-based food colorant aiming to replace the synthetic ones, which apart from meeting sensorial and organoleptic aspects, they can also act as health promoters offering additional added value. Carminic acid is a natural based food colorant typically found in several insect taxa. However, there are current approaches which pursue the production of this natural pigment via biotechnological synthesis. To date, this colorant has been intensively applied in the manufacture of several food items. Unfortunately, one of the main limitations deals with the establishment of the right protocol of extraction and purification of this component since there is no report analyzing the main extraction techniques for obtaining carminic acid. Therefore, this review, for the first time, comprehensively analyzes the ongoing strategies and protocols proposed by scientists towards either extraction or purification of carminic acid from its origin source, and from biotechnological systems. Emphasis has been focused on the main findings dealing with extraction techniques and the relevant insights in the field. A detailed discussion is provided on the advantages and drawbacks of the reported extraction and purification methods, main solvents used and their key interactions with target molecules.

Immunomodulatory effects and mechanisms of the extracts and secondary compounds of Zingiber and Alpinia species: a review

Zingiber and Alpinia species (family: Zingiberaceae) are popularly used in food as spices and flavoring agents and in ethnomedicine to heal numerous diseases, including immune-related disorders. However, their ethnomedicinal uses have not been sufficiently supported by scientific investigations. Numerous studies on the modulating effects of plants and their bioactive compounds on the different steps of the immune system have been documented. This review aimed to highlight up-to-date research findings and critically analyze the modulatory effects and mechanisms of the extracts and secondary compounds of several Zingiber and Alpinia species, namely, Zingiber officinale Roscoe, Z. cassumunar Roxb., Z. zerumbet (L.) Roscoe ex Sm., Alpinia galanga Linn., A. conchigera Griff, A. katsumadai Hayata, A. oxyphylla Miq., A. officinarum Hance, A. zerumbet (Pers.) Burtt. et Smith, and A. purpurata (Viell.) K. Schum. on the immune system, particularly via the inflammation-related signaling pathways. The immunomodulating activities of the crude extracts of the plants have been reported, but the constituents contributing to the activities have mostly not been identified. Among the extracts, Z. officinale extracts were the most investigated for their in vitro, in vivo, and clinical effects on the immune system. Among the bioactive metabolites, 6-, 8-, and 10-gingerols, 6-shogaol, and zerumbone from Zingiber species and cardamomin, 1'-acetoxychavicol acetate, yakuchinone, rutin, 1,8-cineole, and lectin from Alpinia species have demonstrated strong immunomodulating effects. More experimental studies using cell and animal models of immune-related disorders are necessary to further understand the underlying mechanisms, together with elaborate preclinical pharmacokinetics, pharmacodynamics, bioavailability, and toxicity studies. Many of these extracts and secondary metabolites are potential candidates for clinical development in immunomodulating agents or functional foods to prevent and treat chronic inflammatory disorders.

Natural Products for the Prevention, Treatment and Progression of Breast Cancer

In this review, we summarize the most used natural products as useful adjuvants in BC by clarifying how these products may play a critical role in the prevention, treatment and progression of this disease. BC is the leading cancer, in terms of incidence, that affects women. The epidemiology and pathophysiology of BC were widely reported. Inflammation and cancer are known to influence each other in several tumors. In the case of BC, the inflammatory component precedes the development of the neoplasm through a slowly increasing and prolonged inflammation that also favors its growth. BC therapy involves a multidisciplinary approach comprising surgery, radiotherapy and chemotherapy. There are numerous observations that showed that the effects of some natural substances, which, in integration with the classic protocols, can be used not only for prevention or integration in order to prevent recurrences and induce a state of chemoquiescence but also as chemo- and radiosensitizers during classic therapy.

A Perspective on Missing Aspects in Ongoing Purification Research towards Melissa officinalis

Melissa officinalis L. is a medicinal plant used worldwide for ethno-medical purposes. Today, it is grown everywhere; while it is known to originate from Southern Europe, it is now found around the world, from North America to New Zealand. The biological properties of this medicinal plant are mainly related to its high content of phytochemical (bioactive) compounds, such as flavonoids, polyphenolic compounds, aldehydes, glycosides and terpenes, among many other groups of substances. Among the main biological activities associated with this plant are antimicrobial activity (against fungi and bacteria), and antispasmodic, antioxidant and insomnia properties. Today, this plant is still used by society (as a natural medicine) to alleviate many other illnesses and symptoms. Therefore, in this perspective, we provide an update on the phytochemical profiling analysis of this plant, as well as the relationships of specific biological and pharmacological effects of specific phytochemicals. Currently, among the organic solvents, ethanol reveals the highest effectiveness for the solvent extraction of precious components (mainly rosmarinic acid). Additionally, our attention is devoted to current developments in the extraction and fractionation of the phytochemicals of M. officinalis, highlighting the ongoing progress of the main strategies that the research community has employed. Finally, after analyzing the literature, we suggest potential perspectives in the field of sustainable extraction and purification of the phytochemical present in the plant. For instance, some research gaps concern the application of cavitation-assisted extraction processes, which can effectively enhance mass transfer while reducing the particle size of the extracted material in situ. Meanwhile, membrane-assisted processes could be useful in the fractionation and purification of obtained extracts. On the other hand, further studies should include the application of ionic liquids and deep eutectic solvents (DES), including DESs of natural origin (NADES) and hydrophobic DESs (hDES), as extraction or fractionating solvents, along with new possibilities for effective extraction related to DESs formed in situ, assisted by mechanical mixing (mechanochemistry-based approach).

Extraction, Purification, Structural Characteristics, Biological Activities, and Applications of the Polysaccharides from Zingiber officinale Roscoe. (Ginger): A Review

Zingiber officinale Roscoe. (ginger) is a widely distributed plant with a long history of cultivation and consumption. Ginger can be used as a spice, condiment, food, nutrition, and as an herb. Significantly, the polysaccharides extracted from ginger show surprising and satisfactory biological activity, which explains the various benefits of ginger on human health, including anti-influenza, anti-colitis, anti-tussive, anti-oxidant, anti-tumor effects. Here, we systematically review the major studies on the extraction and purification of polysaccharides from ginger in recent years, the characterization of their chemical structure, biological activity, and structure-activity relationships, and the applications of ginger polysaccharides in different fields. This article will update and deepen the understanding of ginger polysaccharide and provide a theoretical basis for its further research and application in human health and product development.