Emergence of microgreens as a valuable food, current understanding of their market and consumer perception: A review.

Green leafy vegetables, especially microgreens are gaining popularity due to their high nutritional profiles, rich phytochemical content, and intense flavors. This review explores the growing commercial market for microgreens, especially in upscale dining and premium grocery outlets, highlighting consumer perceptions and their effect on market dynamics. Apart from these, the effect of modern agricultural methods that maximize the growth of microgreens is also examined. The value is anticipated to increase significantly, according to market predictions, from $1.7 billion in 2022 to $2.61 billion by 2029. Positive consumer views on microgreens health benefits drive this growth, although challenges such as varying levels of consumer awareness and income disparities affect sales. The review underscores the need for targeted research and strategic initiatives to enhance consumer understanding and improve cultivation methods to support market expansion in upcoming years.

Valorization of corn silk through incorporation in instant mix and analyzing its shelf life by kinetic modelling.

Corn silk (Zea mays L.), an abundant agricultural waste, contains various bioactive compounds that exhibit promising health benefits. The current study focuses on development and optimization of corn silk-based instant mix using response surface methodology. The optimized product, with 14.66% corn silk, 10% sugar and 0.22% xanthan gum in a skim milk powder base, scored 0.925 desirability. The physico-chemical and sensory parameters of optimized mix closely aligned with expected values. The instant mix packaged in metallised polyester yielded superior preservation of quality indicators over 120 days compared to low-density polyethylene (LDPE) and high-density polyethylene (HDPE). The microbial load in corn silk instant mix was observed across packaging materials and highlighting hydroxyl methyl furfural (HMF) as the primary predictor of product stability, the study calculated a 94.95 days half-life at 10 °C. Corn silk's rich bioactive compound supports its integration into nutraceuticals and instant mixes, mitigating food waste while enhancing nutritional value. Novelty statement. In this study, corn silk powder was utilized for the development of the instant mix. This innovative approach transforms corn silk, typically discarded as agricultural waste, into a commercially sustainable product that delivers the nutrients of corn silk to a broader population. Despite fresh corn silk being a perishable commodity, it has very low storage shelf life. The developed instant mix effectively preserves its nutritional value for up to six months, offering a sustainable and nutritious option for consumers.

Process optimization, growth kinetics, and antioxidant activity of germinated buckwheat and amaranth-based yogurt mimic.

This study aimed to investigate the integration of cereal and germinated pseudocereals into set-type yogurt mimic, resulting in a novel and nutritious product. Four groups of yogurts mimic, namely CPY-1, CPY-2, CPY-3, and CPY-4, were prepared using different probiotic cultures, including L. acidophilus 21, L. plantarum 14, and L. rhamnosus 296 along with starter cultures. Notably, CPY-2 cultured with L. plantarum and L. rhamnosus and incubated for 12 h exhibited the most desirable attributes. The resulting yogurt demonstrated an acidity of 0.65%, pH of 4.37 and a probiotic count of 6.38 log CFU/mL. The logistic growth model fit revealed maximum growth rates (k, 1/h) and maximum bacterial counts (Nm log CFU/mL) for each CPY variant. The results revealed that CPY-2 significantly improved protein, dietary fiber, phenols and antioxidant capacities compared to the control. Scanning electron microscopy showed more structured and compact casein network in CPY-2, highlighting its superior textural characteristics. Overall, this study demonstrates the incorporation of cereal and germinated pseudocereals into set-type yogurt mimic offers health benefits through increased dietary fiber and ß-glucan.

Dandelion (Taraxacum officinale): A Promising Source of Nutritional and Therapeutic Compounds.

BACKGROUND: Taraxacum officinale, commonly referred to as dandelion, is a selfgrowing plant/ weed in various parts of India and the rest of the world (particularly the northern hemisphere). The plant's chemical composition, including sesquiterpene lactones, saponins, flavonoids, phenols, and many other compounds, contributes positively to the human body, promoting overall health. AIM: This review aims to shed light on the therapeutic potential of dandelion by summarizing its nutritional benefits, phytochemical constituents, and effectiveness in addressing health conditions like diabetes, inflammation, and cancer. It also provides insights into the applications of this plant beyond the food industry to gain researchers' attention to unravel the unexplored aspects of this therapeutic plant. It will further help in laying specific considerations, which are required to be taken into account before the development of functional foods incorporated with dandelion. Scope and approach: Being rich in essential vitamins, minerals, and other phytoconstituents, dandelion is a natural remedy for various ailments. Whether consumed raw or cooked, the plant's inclusion in the diet poses potential therapeutic effects on conditions such as diabetes, inflammation, liver disease, and tumors. It also aids in immune system modulation and fights infections by targeting microbes at their root. Researchers have developed various value-added food products by incorporating different parts of dandelion. CONCLUSION: This review highlights the therapeutic potential of dandelion, emphasizing its effectiveness against various health conditions. Insights into dosage, toxicity, and diverse applications further underscore its role as a versatile and promising natural remedy.

Bioactive Compounds from Kinnow Processing Waste and their Associated Benefits: A Review.

We have explored the expansive possibilities of kinnow peel, a frequently ignored by-product of the fruit processing industry, in this thorough analysis. The production of kinnow generates a significant amount of waste, including peel, seeds, and pulp. The disposal of this waste is a major environmental issue, as it can lead to pollution and greenhouse gas emissions. Due to the presence of bioactive substances that may be used in a variety of sectors, kinnow processing waste has the potential to provide a number of advantages. In the culinary, pharmaceutical, and cosmetic industries, the peel, seeds, and pulp from kinnow can be used as natural sources of antioxidants, aromatics, pectin, and dietary fibre. Utilizing kinnow waste promotes eco-innovation, increases sustainability, and aids in waste reduction. The development of a circular economy can be sped up with more study and commercialization of kinnow waste products. This analysis emphasises how important it is to understand and utilise the unrealized potential of agricultural byproducts, like kinnow peel.

Nutritional Significance of Wheatgrass: Cultivation Practices and Opportunities for its Processing and Preservation.

BACKGROUND: This paper aims to provide a comprehensive review of the nutritional composition and bioactive compounds found in wheatgrass, including chlorophyll, vitamins, minerals, flavonoids, and phenolic compounds, as well as their associated health benefits. The review focuses on various cultivation practices, preservation techniques, and the current utilization of wheatgrass as a whole. Additionally, the potential toxicity of wheatgrass has been discussed. Wheatgrass, a nutrient-rich grass, possesses significant pharmacological and therapeutic qualities. In the present scenario, wheatgrass is available in the form of juice, powder, and tablets, and is incorporated into various food products through different processing treatments. METHOD: Information and data regarding wheatgrass cultivation practices, processing, and preservation methods were collected from scientific sources, including Google Scholar, ResearchGate, ScienceDirect, fig, Web of Science, and Scopus databases. RESULT: Wheatgrass is a highly valuable source of diverse nutrient compounds. Various cultivation methods, such as indoor and outdoor techniques using different growing mediums, have been employed for wheatgrass production. Recent methods for wheatgrass preservation have been suggested to enhance the bioactive compounds present in wheatgrass. CONCLUSION: Numerous studies have demonstrated that the consumption of wheatgrass and wheatgrass- based products can help control diabetes, atherosclerosis, kidney and colon diseases, anemia, and certain types of cancer. The smaller size of wheatgrass allows for easier assimilation of its beneficial compounds. Creating awareness among consumers about the nutritional profile and therapeutic properties of wheatgrass is crucial in order to maximize its market potential.

An overview on the types, applications and health implications of fat replacers.

Driven by the demand of consumers for low-fat foods, the field of fat replacers has made a tremendous breakthrough over the past decade. A fat replacer is a substance that replaces whole or part of the fat in food while asserting the same physiological properties. Based on the source, fat replacers can be carbohydrate, protein or lipid-based. They serve two major purposes in food viz. reducing the calorie content and amount of fat used in the preparation of food products as well as impart fat-like properties. Fat replacers exhibit its functionalities by providing texture, acting as stabilizers, emulsifiers, gelling and thickening agents. It is crucial to select the proper kind of fat replacer because fat functionality varies considerably depending on the meal type and the formulation. Evidence suggests that reducing fat intake can help in controlling body weight and the risk of diseases like type-2 diabetes, hypertension and cardiovascular disease. Consumers should not be misled into believing that fat and calorie-reduced foods may be consumed indefinitely. Fat replacers are most beneficial when they aid in calorie control and promote the consumption of meals that provide essential nutrients. This review aims to provide a deep insight into the fact that fat replacers can be utilized in various food commodities in order to meet the dietary guidelines for reducing fat intake with a healthy lifestyle and prudent dietary approach.

Image analysis-based discoloration rate quantification and kinetic modeling for shelf-life prediction in herb-coated pear slices.

The present research study aimed to examine three different herb extract's effects on the discoloration rate of fresh-cut pear slices using an image analysis technique. Pear slices were sprayed and dip-coated with Ocimum basilicum, Origanum vulgare, and Camellia sinensis (0.1 g/ml) extract solution. During 15 days storage period with three days intervals, all sprayed/dip-coated pear slices were analyzed for the quality attribute (TA) and color parameters notably a*, b*, hue angle (H*), lightness (L*), and total color change (ΔE). Further, order kinetic models were used to observe the color changes and to predict the shelf-life. The results obtained showed that the applicability of image analysis helped to predict the discoloration rate, and it was better fitted to the first-order (FO) kinetic model (R2 ranging from 0.87 to 0.99). Based on the kinetic model, color features ΔE and L* was used to predict the shelf-life as they had high regression coefficient values. Thus, the findings obtained from the kinetic study demonstrated Camellia sinensis (assamica) extract spray-coated pear slices reported approximately 28.63- and 27.95-days shelf-stability without much discoloration compared with all other types of surface coating.

Valorization of grape (Vitis vinifera) leaves for bioactive compounds: novel green extraction technologies and food-pharma applications.

Grape leaves, scientifically known as Vitis vinifera, the primary by-product obtained after the processing of grapes, are gathered in enormous amounts and disposed of as agricultural waste. For more sustainable agriculture and better food systems, it is crucial to investigate these byproducts' nutritional values. The primary bioactive compounds present in grape leaves are quercetin, resveratrol, caffeic acid, kaempferol, and gallic acid, which favour pharmacological effects on human health such as antioxidant, anti-inflammatory, anti-obesity, anti-diabetic, and hepatoprotective. Furthermore, grape leaves extract has been used as a functional ingredient for creating both food and non-food products. The aim of the current review is to review the nutritional and phytochemical composition of various varieties of grape leaves, their health-promoting characteristics and their applications. The study also highlights the various extraction techniques including conventional and non-conventional methods for extracting the various bioactive compounds present in grape leaves. Grape leaves bioactives can be extracted using environmentally safe and sustainable processes, which are in line with the rising demand for eco-friendly and healthful products worldwide. These methods are perfectly suited to the changing needs of both customers and industries since they lessen environmental effect, enhance product quality, and offer financial advantages.

Genetics, Nutrition, and Health: A New Frontier in Disease Prevention.

The field of nutrition research has traditionally focused on the effects of macronutrients and micronutrients on the body. However, it has become evident that individuals have unique genetic makeups that influence their response to food. Nutritional genomics, which includes nutrigenetics and nutrigenomics, explores the interaction between an individual's genetic makeup, diet, and health outcomes. Nutrigenetics studies the impact of genetic variation on an individual's response to dietary nutrients, while nutrigenomics investigates how dietary components affect gene regulation and expression. These disciplines seek to understand the impact of diet on the genome, transcriptome, proteome, and metabolome. It provides insights into the mechanisms underlying the effect of diet on gene expression. Nutrients can cause the modification of genetic expression through epigenetic changes, such as DNA methylation and histone modifications. The aim of nutrigenomics is to create personalized diets based on the unique metabolic profile of an individual, gut microbiome, and genetic makeup to prevent diseases and promote health. Nutrigenomics has the potential to revolutionize the field of nutrition by combining the practicality of personalized nutrition with knowledge of genetic factors underlying health and disease. Thus, nutrigenomics offers a promising approach to improving health outcomes (in terms of disease prevention) through personalized nutrition strategies based on an individual's genetic and metabolic characteristics.

Genetic differences among individuals affect the metabolism, gene regulation, and sensitivity of disease in response to diet therefore traditional nutrition research expands to integrate the influence of genetics on the dietary response of an individual.Nutritional genomics which includes the reciprocal and complementary field of nutrigenetics and nutrigenomics, studies the interactions between gene and dietary components.Nutrigenetics studies the genetic effect on the metabolism of nutrients while Nutrigenomics explores the impact of nutrients on genetic expression thus shaping personalized dietary requirements.A personalized dietary approach based on comprehensive genomic profiling (genomics, proteomics, metabolomics, transcriptomics) can help to promote health and prevent illness.

Beetroot Bioactive and its Associated Health Benefits: Considerations for Utilization of Beetroot in Value-added Products.

BACKGROUND: Beetroot is a remarkable source of nutrients needed for the improvement of human health. This paper presents a general overview of beetroot, its bioactive compounds, and its valorization. OBJECTIVE: The study aimed to understand and review the various beetroot bioactive compounds and their utilization in value-added products. METHODS: The findings and data provided in this review are based on the available research investigations and authorized articles. RESULT: Beetroot is a reliable source of a cluster of bioactive compounds, such as betalains, ascorbic acid, phenolic compounds, carotenoids, and nitrates, which have brought it into the spotlight for the preparation of various value-added products for daily consumption for better health. These beneficial compounds show a wide range of health benefits, such as antiinflammatory activity, anti-oxidant activity, anti-anemic activity, and cancer chemopreventive activity. CONCLUSION: This paper has reviewed the studies focused on the utilization of beetroot concerning its varied composition of nutraceutical components. This review briefly accounts for the different bioactive compound extraction methods that are immensely helpful in the food and health industries. The advantages and disadvantages of these extractions are also taken into consideration. There is a wide range of value-added products currently in the market that are generated from the addition of beetroot for the improvement of nutritional as well as sensory attributes of the final products.

Pomegranate Peel Phytochemistry, Pharmacological Properties, Methods of Extraction, and Its Application: A Comprehensive Review.

Pomegranate peel, derived from the processing of Punica granatum L. (pomegranate), has traditionally been considered agricultural waste. However, recent studies have revealed its potential as a rich source of bioactive compounds with diverse pharmacological effects. Pomegranate peel is a rich reservoir of antioxidants, polyphenols, dietary fiber, and vitamins, which contribute to its remarkable bioactivity. Studies have demonstrated the anti-inflammatory, cardioprotective, wound healing, anticancer, and antimicrobial properties of pomegranate peel owing to the presence of phytochemicals, such as gallic acid, ellagic acid, and punicalagin. The extraction of bioactive compounds from pomegranate peel requires a careful selection of techniques to maximize the yield and quality. Green extraction methods, including pressurized liquid extraction (PLE), ultrasound-assisted extraction (UAE), microwave-assisted extraction (MAE), and enzyme-assisted extraction (EAE), offer efficient and sustainable alternatives to traditional methods. Furthermore, pomegranate peel has been utilized in the food industry, where it can significantly enhance the nutritional value, organoleptic characteristics, and shelf life of food products. Pomegranate peel has the potential to be used to develop innovative functional foods, nutraceuticals, and other value-added products, providing new opportunities for the pharmaceutical, cosmetic, and food industries.

Nutritional advantages of barnyard millet and opportunities for its processing as value-added foods.

Barnyard millet (Echinochloa species) has received appreciable attention for its susceptibility to biotic and abiotic stresses, multiple harvests in a year and rich in micronutrients, fibers and phytochemicals. It is believed that the consumption of barnyard millet can possess various health benefits against diabetes, cardiovascular diseases, obesity, skin problems, cancer and celiac disease. The flour of barnyard millet is gluten-free and can be incorporated into the diet of celiac and diabetic patients. Considering the nutritional value of millet, various millet-based food products like bread, snack, baby foods, millet wine, porridge, fast foods and millet nutrition powder can be prepared. Future research and developments on barnyard millet and its products may help cope with various diseases known to humans. This paper discusses barnyard millet's nutritional and health benefits as whole grain and its value-added products. The paper also provides insights into the processing of barnyard millet and its effect on the functional properties and, future uses of barnyard millet in the field food industry as ready-to-cook and ready-to-eat products as well as in industrial uses, acting as a potential future crop contributing to food and nutritional security.

Comprehensive Analysis of Physicochemical, Functional, Thermal, and Morphological Properties of Microgreens from Different Botanical Sources.

Due to the significant increase in global pollution and a corresponding decrease in agricultural land, there is a growing demand for sustainable modes of modern agriculture that can provide nutritious food. In this regard, microgreens are an excellent option as they are loaded with nutrients and can be grown in controlled environments using various vertical farming approaches. Microgreens are salad crops that mature within 15-20 days, and they have tender leaves with an abundant nutritive value. Therefore, this study aims to explore the physicochemical, techno-functional, functional, thermal, and morphological characteristics of four botanical varieties of microgreens, including carrot (Daucus carota), spinach (Spinacia oleracea), bathua (Chenopodium album), and Bengal gram (Cicer arietinum), which are known for their exceptional nutritional benefits. Among the four botanical varieties of microgreens studied, bathua microgreens demonstrated the highest protein content (3.40%), water holding capacity (1.58 g/g), emulsion activity (56.37%), and emulsion stability (53.72%). On the other hand, Bengal gram microgreens had the highest total phenolic content (32.2 mg GAE/g), total flavonoid content (7.57 mg QE/100 g), and DPPH activity (90.60%). Fourier transform infrared spectroscopy analysis of all microgreens revealed the presence of alkanes, amines, and alcohols. Moreover, X-ray diffraction analysis indicated low crystallinity and high amorphousness in the microgreens. Particle size analysis showed that the median, modal, and mean sizes of the microgreens ranged from 110.327 to 952.393, 331.06 to 857.773, and 97.567 to 406.037 µm, respectively. As per the observations of the results, specific types of microgreens can be utilized as an ingredient in food processing industry, including bakery, confectionery, and more, making them a promising nutritive additive for consumers. This study sheds light on various food-based analytical parameters and offers a foundation for future research to fully harness the potential of microgreens as a novel and sustainable food source, benefiting both the industry and consumers alike.

Effect of Spice Incorporation on Sensory and Physico-chemical Properties of Matcha-Based Hard Candy.

The present study was carried out to formulate and determine the sensory, proximate, phytochemical, and antioxidant properties of matcha hard candies incorporated with spices such as ginger (Zingiber officinale Rosc.), cinnamon (Cinnamomum zeylanicum and Cinnamon cassia), and holy basil (tulsi) (Ocimum sanctum L.). Standardized matcha (Camellia sinensis) hard candy was taken as a control, and spices/herbs were incorporated in different concentrations. The best formulation was GC5 (2% ginger powder) for matcha ginger hard candy, CZ10 (0.9% cinnamon powder) for matcha cinnamon hard candy, and TC7 (3% tulsi powder) for matcha tulsi hard candy. These formulations were selected based on the organoleptic evaluation. Furthermore, these selected hard candies were evaluated for the determination of proximate, phytochemical, and antioxidant profiles which exhibited significant results. This study demonstrates the excellent nutritional and phytochemical potential that spiced matcha hard candy has for use as a nutraceutical food product.

Anti-cancerous effect of corn silk: a critical review on its mechanism of action and safety evaluation.

Cancer is a broad collection of diseases that can begin in almost any organ or tissue of the body. Corn silk is the hair-like stigmata of female maize flowers which is generally discarded as waste from maize cultivation. The current study targets the anti-cancer potential of corn silk and its bioactive compounds namely, polyphenols, flavonoids, and sterols. The polyphenols and flavonoids like quercetin, rutin, apigenin and beta-sitosterol are a range of compounds from corn silk which were investigated for their anticancer effect. Corn silk showed apoptotic and antiproliferative effects in cancer cells through different signalling pathways, essentially the serine/threonine kinases (Akt)/lipid kinases (PI3Ks) pathway. The study revealed that corn silk compounds target immune cell responses, induce cell cytotoxicity, and upregulate the expression of proapoptotic genes p53, p21, caspase 9, and caspase 3 in certain cancer cell lines including HeLa cervical cancer cells, MCF-7 breast cancer cells, PANC-02 pancreatic cancer cells and Caco-2 colon cancer cells. Flavonoids derived from corn silk enhance T cell mediated immune response and decrease inflammatory factors. Corn silk bioactive compounds were found to reduce the side effects of cancer therapy. Antioxidants of corn silk, quercetin and rutin help in reducing the nephrotoxicity of chemotherapeutic drugs. The study also suggests that corn silk has anti-cancerous potential as it targets tumour suppression and inhibits metastasis A dose of 500 mg/kg body weight of corn silk has been found safe for human consumption. Corn silk extract can be used as a preventive or therapeutic step to cure cancer. The anti-cancer property, mechanism and role of corn silk in controlling cancer-related side effects have been critically reviewed providing new scope for the use of corn silk in cancer therapy.

Nutritional management and interventions in complications of pregnancy: A systematic review.

Background: Pregnancy, also known as the "gestation period" which lasts for 37-40 weeks, has been marked as the period of "physiological stress" in a woman's life. A wide range of symptoms, from nausea to ectopic pregnancy, are usually aligned with risk factors like abortion, miscarriage, stillbirth, etc. An estimated total of 15% of total pregnant women face serious complications requiring urgent attention for safe pregnancy survival. Over the past decades, several changes in the environment and nutrition habits have increased the possibility of unfavourable changes during the gestation phase. The diagnostic factors, management and nutritional interventions are targeted and more emphasis has been laid on modifying or managing the nutritional factors in this physiologically stressed phase. Aims: This review focuses on dietary modifications and nutritional interventions for the treatment of complications of pregnancy. Nutritional management has been identified to be one of the primary necessities in addition to drug therapy. It is important to set a healthy diet pattern throughout the gestation phase or even before by incorporating key nutrients into the maternal diet. Methods: The published literature from various databases including PubMed, Google Scholar and ScienceDirect were used to establish the fact of management and treatment of complications of pregnancy. Results: The recommendations of dietary supplements have underlined the concept behind the eradication of maternal deficiencies and improving metabolic profiles. Conclusion: Therefore, the present review summarises the dietary recommendations to combat pregnancy-related complications which are necessary in order to prevent and manage the same.

Bioactive compounds of corn silk and their role in management of glycaemic response.

Management of glycaemic response is perhaps the most critical part of antidiabetic therapy. Hypoglycaemia is an avoidable complication caused by conventional drugs used in the treatment of diabetes. It triggers commonly during the intensification of anti-hyperglycemic therapy used to render glycemic control in diabetic patients. The commercial oral hypoglycaemic drugs, insulin, herbal medicines and plant extracts are therefore used as a part of the treatment of diabetes. The demand for treating diabetes, through herbal and plant resources is due to their lesser adverse reactions and better phytochemical benefits. Corn silk has been shown to have anti-allergic, anti-inflammatory, and anti-hypertensive effects when extracted in various solvents. Corn silk has medicinal characteristics and has long been used as a traditional medicine in many nations, although the mechanism of action is unknown. The hypoglycaemic effects of corn silk are investigated in this review. The phytochemical components present in corn silk-like flavonoids, phenolics, terpenoids, tannins, sterols, and alkaloids are phytochemical components that have hypoglycemic activity and a mechanism for lowering blood glucose levels. There is a lack of a homogenized database on the hypoglycemic properties of corn silk thus the present review attempts to critically analyse it and provide specific recommendations of its doses.

3D printed foods-carbs from the lab for better health.

PURPOSE OF REVIEW: The purpose of the review is to describe carbohydrate based 3D food printing technology in light of how it is affected by the use of various ingredients of ink and the properties associated with carbohydrate inks used for printing. Special focus is diverted to evaluate its effect on texture and corresponding health implications associated with carbohydrate based printed foods. RECENT FINDINGS: The focus of 3D food printed products has revolved around texture modulation and carbohydrates are the best possible additives to achieve this modification. Carbohydrate based inks are used to design healthy texturized printed foods to provide various health benefits to consumer in addition to satisfy their aesthetic requirements. Other ingredients such as prebiotics and probiotics are major adjuncts that add value to these carbohydrates based 3D food printed foods and may have synergistic effects. SUMMARY: Although much of the current attention is on texture modulation, health aspects of the foods naturally drive the future course of research associated with the carbohydrate based 3D food printed foods.