There are many different applications of heterocyclic molecules in the pharmaceutical and materials science fields, which make them an important family of compounds. Among these heterocyclic compounds, nitrogen-containing heterocyclic (N-heterocyclic) compounds have attracted a lot of interest among researchers due to their various applications across a wide variety of fields. Many studies have been performed over the past few years to study the synthesis of N-heterocycles under different reaction conditions, such as solvent-free, catalytic, reactants immobilized on a solid support, one-pot synthesis, and microwave irradiation. It has been demonstrated by our research group that microwaves can be utilized for rapid and efficient synthesis of biologically active compounds. In this review, we provide an overview of the microwave-assisted non-catalytic and catalytic preparation of nitrogen-containing heterocycles, mostly polycyclic N-heterocycles, five-membered N-heterocycles, six-membered N-heterocycles, and fused N-heterocycles. Mostly in this article, we explore the microwave-assisted preparation of biologically important compounds, such as pyrimidines, thiazoles, imines, tetrazoles, steroidal derivatives, quinolines, indolizine, triazoles, beta-lactams, pyrroles and quinoxalines.

This study explores the potential of Curcuma longa byproducts, called Curcuminoid removed turmeric oleoresin (CRTO), to extend the shelf life of peanut butter. CRTO, rich in curcuminoids, was added to peanut butter formulations to assess its preservative effects, flavour impact, and nutritional benefits. Results demonstrated that CRTO oil and curcuminoids effectively prolonged peanut butter shelf life by delaying rancidity. The study also compared results using oxygen scavenger film (OSF) packaging. Over time, water activity and oil separation increased, but CRTO oil and OSF helped to mitigate these effects. Sensory evaluations favored CRTO oil and curcuminoids, while microbial analysis confirmed safety of both the control and OSF samples for six months at 27 °C and 65% RH, and for four months at 37 °C and 95% RH. This study proposes a natural and sustainable method for extending peanut butter shelf life while enriching it with curcuminoids, with significant implications for the food industry.

The by-products of the grain processing industry are a vital resource for the valorization methods in the food industry. In comparison to the whole grain, the broken kernels and seeds own similar nutrient and bioactive compounds having multifaceted health properties. This study aims to develop a nutritional bar by utilizing the by-products from barnyard millet and foxnut with added sweeteners. Furthermore, high-resolution mass spectrometry (HR-MS) metabolomics was carried out in positive and negative both ion modes to identify the major bioactive compounds formed in the matrix of the best-optimized valorized bar. The formulation of the bar having 15 % foxnut flour and the barnyard flour each, was elucidated highest rheological and sensory scores. A sum of 29 bioactive metabolites has been observed in the obtained metabolome. Major metabolites were palmitoyl serinol, glycitein, persin, bufagargarizin, apigenin, carvone, etc. covering a wide area in the mass spectrum. The therapeutic value of these compounds is heart health promotion, anti-inflammatory, anti-carcinogenic, anti-diabetic, anti-microbial, etc. This work highlights the bioactivity of the valorized nutritional bar employing robust and accurate tool of mass spectrometry. The developed snack is a functional food for the consumers.

The latent potential of active ingredients derived from agro-industrial waste remains largely untapped and offers a wealth of unexplored resources. While these types of materials have applications in various fields, their ability to benefit human health needs to be further explored and investigated. This systematic review was conducted to systematically evaluate non-clinical studies that have investigated the biological effects of fractions, extracts and bioactive compounds from agro-industrial wastes and their potential therapeutic applications. Articles were selected via PubMed, Embase and Medline using the descriptors (by-products[title/abstract]) AND (agro-industrial[title/abstract]). The systematic review was registered in the International Prospective Register of Systematic Reviews (Prospero) under the number CRD42024491021. After a detailed analysis based on inclusion and exclusion criteria, a total of 38 articles were used for data extraction and discussion of the results. Information was found from in vitro and in vivo experiments investigating a variety of residues from the agro-industry. The studies investigated peels, pomace/bagasse, pulp, seeds, aerial parts, cereals/grains and other types of waste. The most studied activities include mainly antioxidant and anti-inflammatory effects, but other activities such as antimicrobial, cytotoxic, antiproliferative, antinociceptive, hypoglycemic, antihyperglycemic and anticoagulant effects have also been described. Finally, the studies included in this review demonstrate the potential of agro-industrial waste and can drive future research with a focus on clinical application.

Quality control of propolis plays a pivotal role in ensuring the appropriate concentrations of active compounds, limiting unwanted substances, verifying authenticity, and adhering to regulatory standards. This study aimed to assess the identity and quality standards, the individual phenolic composition (LC-ESI-MS/MS), and the antioxidant and antiglycemic potential of commercial propolis extracts (CPEs) from Apis mellifera, Scaptotrigona bipunctata, and Melipona quadrifasciata bees. CPEs met wax content and oxidation activity criteria, surpassing minimum thresholds for total phenolic content (TPC) and flavonoid content (TFC), although stingless bee CPE did not test positive for 10% lead acetate. CPEs exhibited antioxidant and potential antiglycemic activities. Epicatechin among the thirty-three identified phenolics, showed significant correlation with TPC, DPPH, ABTS, and EC50 values of α-amylase enzyme. These promising attributes underscore the potential health benefits of commercial propolis extracts from Apis mellifera and stingless bees for further medicinal and nutritional applications.

Doum palm and turmeric are traditional medicinal plants with a rich history of use. This study investigated the phytochemical composition, proximate analysis, and GC-MS characterization of doum palm and turmeric blends at different ratios (100%, 80:20%, 60:40%, and 50:50%) using ethanol and warm-water extracts. Phytochemical screening revealed the presence of various bioactive compounds, including alkaloids, anthraquinones, flavonoids, glycosides, saponins, tannins, terpenoids, and phenols, in the blends at ratios of 80:20%, 60:40%, and 50:50%. Alkaloids were absent in the 100% doum palm sample. Proximate analysis showed significant variations in moisture, ash, fat, and protein content among the samples. GC-MS characterization identified at most 30 phytochemical compounds in sample A and more additional 9 bioactive compounds in samples B, C and D, including two new compounds, eucalyptol and carotol, found in the doum palm-turmeric blends. These compounds have been known to possess various antioxidant and therapeutic potential. The findings suggest that doum palm and turmeric blends have improved potential health benefits due to their high content of phytochemical compounds and balanced proximate composition. Further research is warranted to determine the most effective doum palm to turmeric ratio (Optimal Blending Ratios) for specific health applications. This includes identifying the blend ratios that maximize the therapeutic benefits for particular conditions or diseases.

The increasing prevalence of particulate matter (PM) has raised significant concerns about its adverse effects on human health. This study investigates the potential of fermented blueberry and black rice (FBBR) in mitigating the effects of PM2.5 in SH-SY5Y cells and mice. Various assays, including MTT, NO, western blot, ELISA, and behavioral studies were conducted. Results showed that PM2.5 induced considerable cytotoxicity and elevated NO production at a concentration of 100 μg/mL of PM2.5 in SH-SY5Y cells. FBBR administration attenuated PM2.5-exposed cytotoxicity and suppressed NO production in SH-SY5Y cells. In an intranasally-exposed mice model, 10 mg/kg body weight (BW) of PM2.5 resulted in cognitive impairments. However, FBBR treatment ameliorated these impairments in both the Y-maze and MWM tests in PM2.5-exposed mice. Additionally, FBBR administration increased the expression of BDNF and reduced inflammatory markers in the brains of PM2.5-exposed SH-SY5Y cells. These findings highlight the detrimental effects of PM2.5 on the nervous system and suggest the potential of FBBR as a nutraceutical agent for mitigating these effects. Importantly, the results emphasize the urgency of addressing the harmful impact of PM2.5 on the nervous system and underscore the promising role of FBBR as a protective intervention against the adverse effects associated with PM2.5 exposure.

The modern food industry is undergoing a rapid change with the trend of production of plant-based food products that are more sustainable and have less impact on nature. Plant-based dairy analogues have been increasingly popular due to their suitability for individuals with milk protein allergy or lactose intolerance and those preferring a plant-based diet. Nevertheless, plant-based products still have insufficient nutritional quality, undesirable structure, and earthy, green, and bean-like flavor compared to dairy products. In addition, most plant-based foods contain lesser amounts of essential nutrients, antinutrients limiting the bioavailability of some nutrients, and allergenic proteins. Novel processing technologies can be applied to have a homogeneous and stable structure. On the other hand, fermentation of plant-based matrix with lactic acid bacteria can provide a solution to most of these problems. Additional nutrients can be produced and antinutrients can be degraded by bacterial metabolism, thereby increasing nutritional value. Allergenic proteins can be hydrolyzed reducing their immunoreactivity. In addition, fermentation has been found to reduce undesired flavors and to enhance various bioactivities of plant foods. However, the main challenge in the production of fermented plant-based dairy analogues is to mimic familiar dairy-like flavors by producing the major flavor compounds other than organic acids, yielding a flavor profile similar to those of fermented dairy products. Further studies are required for the improvement of the flavor of fermented plant-based dairy analogues through the selection of special microbial cultures and formulations.

In the current scenario, obesity is a stimulating health problem and is growing very rapidly in the world. It is a complex disease caused by the imbalance between the energy intake and the energy expenditure. There are various diseases associated with obesity, i.e., diabetes, hypertension, cancer, atherosclerosis, and other cardiovascular problems, which produce a serious impact on the social and financial system of the population. Moreover, changing the lifestyle and other behavioral changes might help in decreasing weight loss, but it is quite challenging to achieve. Nearly 10-20% of males and 20-30% of females come under the obese condition. The most convenient therapy for treating obesity is the use of synthetic drugs available in the markets, like orlistat and sibutramine, but these drugs have serious side effects, along with this surgical procedure, and are also not safe. Various herbal medicines and bioactives are preferred as game changers. Many herbal plants and their bioactive compounds have recently demonstrated promising effects in treating obesity. They achieve this by acting on various signaling pathways, reducing the levels of hormones associated with obesity, and regulating the abundance and composition of gut microbiota. This review concludes by highlighting the potential role of various herbal plants in managing obesity.

Bacteriocins are antimicrobial compounds that have awakened interest across several industries due to their effectiveness. However, their large-scale production often becomes unfeasible on an industrial scale, primarily because of high process costs. Addressing this challenge, this work analyzes the potential of using low-cost whey permeate powder, without any supplementation, to produce bacteriocin-like inhibitory substances (BLIS) through the fermentation of Latilactobacillus sakei. For this purpose, different concentrations of whey permeate powder (55.15 gL-1, 41.3 gL-1 and 27.5 gL-1) were used. The ability of L. sakei to produce BLIS was evaluated, as well as the potential of crude cell-free supernatant to act as a preservative. Raman spectroscopy and surface-enhanced Raman scattering (SERS) provided detailed insights into the composition and changes occurring during fermentation. SERS, in particular, enhanced peak definition significantly, allowing for the identification of key components, such as lactose, proteins, and phenylalanine, which are crucial in understanding the fermentation process and BLIS characteristics. The results revealed that the concentration of 55.15 gL-1 of whey permeate powder, in flasks without agitation and a culture temperature of 32.5 °C, presented the highest biological activity of BLIS, reaching 99% of inhibition of Escherichia coli and Staphylococcus aureus with minimum inhibitory concentration of 36-45%, respectively. BLIS production began within 60 h of cultivation and was associated with class II bacteriocins. The results demonstrate a promising approach for producing BLIS in an economical and environmentally sustainable manner, with potential implications for various industries.