Search Results (215)

White lupin (Lupinus albus) is a very important legume crop, having seeds with high protein content but also quantities of antinutritional alkaloids. Regarding cultivation, it is sensitive to neutral or alkaline soil conditions, although it is well adapted to drought conditions. In this study, the adaptability of 17 L. albus (14 commercial varieties and 3 advanced lines) genotypes to neutral-pH soils was investigated in relation to morphological, agronomical, and yield attributes. An extended characterization of seed composition for total alkaloids, trypsin inhibitors, phenolics, tannins, total nitrogen, NDF, ADF, and lignin was also performed. Furthermore, a prebreeding program consisting of 140 targeted crosses was initiated to develop new F1 combinations for genotypes with low alkaloid profiles; at the same time, controlled self-fertilization of elite lines was carried out. The results indicated that the morphological response of L. albus to neutral pH was positive and significantly genotypically dependent. Among the varieties tested, ‘Magnus’ and ‘Figaro’ showed low alkaloid and lignin contents. On the other hand, the advanced lines (LKAP, LKML, LKAU) had high antinutritional components, even though they were high-yielding. This research proposes a model of combined evaluation and selection processes for identification of particular genotypes that can perform well in neutral soils and provides the basis for breeding and producing low-alkaloid genotypes for multi-locational exploitation. Full article

Recent studies on novel protein sources unveiled lupins as a promising substitute for meat consumption. However, lupin cultivation and processing include significant safety concerns, such as quinolizidine alkaloids (QAs) and the possible growth of toxigenic fungi as Diaporthe toxica, which produces the mycotoxin phomopsin-A (PHO-A). Therefore, this study aims to assess the influence of gaseous and aqueous ozone on lupin beans as environmentally sustainable methods for detoxifying QAs and PHO-A mycotoxins, thereby addressing both these safety challenges. Three distinct aqueous and gaseous ozone treatments (4, 6, and 8 h, at 7.00 ppm O₃ concentration) were applied on lupin seeds inoculated with D. toxica DSM 1894. A good effectiveness of aqueous O₃ in the reduction in PHO-A (about 20%) was demonstrated, independently of the treatment duration, along with the reduction in some QAs typically encountered in lupin. Additionally, a significant reduction in D. toxica count was observed after 4 h treatment with aqueous O₃. In contrast, results for gaseous O₃ treatments did not show any significant effectiveness on either PHO-A or QAs. Conversely, none of the treatments applied significantly affected lupin color. In conclusion, aqueous ozone treatment demonstrated significant potential for the reduction in PHO-A and QAs, and the insights acquired from this work may aid in mitigating the dangers associated with lupin intake. Nevertheless, additional research is required to cover current knowledge gaps. Specifically, toxicological assays on PHO-A degradation by-products or O₃ combination with other hurdles is required to enhance treatments and preserve lupins’ nutrients. Full article

Lupin (Lupinus spp.), a legume known for its high protein content, holds great promise as a sustainable protein source to meet future global demands. Despite its nutritional benefits, including substantial dietary fibre and bioactive compounds, lupin remains underutilised in human diets due to several techno-functional and sensory limitations. This review delves into the techno-functional limitations of lupin, which include poor foaming capacity, low water and oil absorption, inadequate emulsification properties, and poor solubility. Lupin’s techno-functional limits are tied to the compact, heat-stable nature of its conglutin storage proteins and high insoluble fibre content. While research has been conducted on fermenting other legumes such as soybeans, chickpeas, peas, and lentils with Exopolysaccharide (EPS) producing bacteria, its application to lupin remains largely unexplored. Crucially, this work is one of the first reviews to exclusively link lupin’s unique protein and fibre structure with the specific polymer chemistry of bacterial EPS as a targeted modification strategy. Current research findings suggest that EPS-producing Lactic Acid Bacteria (LAB) fermentation can significantly improve the techno-functional properties of legumes, indicating strong potential for similar benefits with lupin. The analysis highlights various studies demonstrating the ability of EPS-producing LAB to improve water retention, emulsification, and overall palatability of legume-based products. Furthermore, it emphasises the need for continued research in the realm of fermentation with EPS-producing bacteria to enhance the utilisation of lupin in food applications. By addressing these challenges, fermented lupin could become a more appealing and nutritious option, contributing significantly to global food security and nutrition. Full article

Lupin (Lupinus spp.) is increasingly incorporated into processed foods as a gluten-free ingredient and alternative protein source, but it is also a regulated allergen in the European Union due to cross-reactivity with other legumes, especially peanut. Reliable methods for detecting undeclared lupin traces in complex food matrices are therefore essential for consumer protection. In this study, a loop-mediated isothermal amplification (LAMP) assay was developed for rapid and sensitive detection of lupin DNA. Several nuclear and chloroplast regions were evaluated for primer design, and gene encoding the Lup a 1 allergen was selected as the optimal target. Amplification was monitored by real-time fluorescence, agarose gel electrophoresis, and visual colorimetry. The selected primer set achieved a detection limit of 25 pg of lupin DNA and consistently detected lupin in binary mixtures down to 10 mg/kg, with no cross-reactivity against closely related legumes or tree nuts. Application to processed foods confirmed detection in products declaring lupin and revealed potential undeclared presence in some commercial samples. Colorimetric detection provided reliable results comparable to real-time monitoring, enabling simple readouts without specialized equipment. Overall, the developed LAMP assay represents a rapid, specific, and sensitive alternative to PCR-based methods for allergen monitoring and food safety management. Full article

Miso is a traditional Japanese seasoning produced by fermenting soybean. However, in Portugal, most soybean is imported. This study focused on producing sustainable and innovative misos using legumes traditionally consumed in Portugal—chickpea, lupin, and cowpea—and assessing their fermentation. Each legume was blended with 3% or 12% NaCl and inoculated with a selected microbial consortium comprising Aspergillus oryzae (koji), Debaryomyces hansenii, Zygosaccharomyces rouxii, Candida versatilis, Lactiplantibacillus plantarum, Leuconostoc mesenteroides, and Tetragenococcus halophilus. Fermentation was carried out at 20 ± 1 °C for 18 months. During this period, microbial viability, pH, total soluble solids, soluble protein, phenolic compounds, reducing sugars, and organic acids were monitored. Soybean misos were also produced and analysed at the beginning and end of fermentation for comparison. Chickpea misos showed the highest accumulation of soluble protein, phenolic compounds, reducing sugars, and organic acids. In contrast, cowpea misos exhibited the lowest levels of these soluble fractions. Lupin misos displayed the most pronounced salt-dependent behaviour. Compared to the alternative legume-based misos, soybean misos did not exhibit distinct final characteristics. These findings highlight the potential of these legumes as alternative substrates for miso production, supporting the development of sustainable, innovative, lower-salt foods with strong cultural and regional relevance. Full article

Buckwheat (Fagopyrum esculentum) and lupins (Lupinus spp.) are traditional crops gaining renewed attention due to their nutritional value, ecological adaptability, and potential role in sustainable agriculture. Both are rich in high-quality proteins, essential amino acids, and bioactive compounds that support human health and meet the growing demand for plant-based foods. In addition to their nutritional importance, these crops can be cultivated on marginal soils with low fertilizer requirements, making them valuable components of climate-resilient cropping systems. Beyond nutrition, both crops generate processing by-products such as husks and ashes, which are increasingly important in the context of fertilizers, bioenergy, and biomaterials, illustrating the dual value of these crops in sustainable and circular systems. This review summarizes data on cultivation, yield, and chemical composition and highlights the multiple pathways for by-product valorisation across food, energy, and environmental applications, contributing to the development of bio-based and circular economy strategies. Full article

Sustainability of animal production requires reducing reliance on soybean meal by identifying viable alternative protein sources. Within the framework of the Italian Agritech National Research Center, seven Italian research groups collaborated to evaluate unconventional feed ingredients and their effects on animal performance and product quality. Alternative legume seeds (peas, chickpeas, faba bean, and lupins) can partially or completely replace soybean meal without impairing productivity, while enhancing product health value and shelf-life through bioactive compounds. Microalgae (Chlorella, Spirulina) improved carotenoid content, antioxidant activity, fatty acid profile, and cholesterol levels in poultry products, with limited effects in pigs. Insects supported optimal growth in fish at 25–30% inclusion, whereas maximum recommended levels are 15% in broilers and 24% in laying hens to sustain growth, egg production, and quality. Camelina by-products are suitable for poultry diets at up to 5–10%, beyond which performance declines. Whole-plant soybean silage, tef (Eragrostis tef), and triticale–lupin intercropping represent promising protein-rich resources for ruminants, provided diets maintain balanced protein-to-energy ratios, adequate fibre characteristics, and appropriate harvest timing under drought-prone conditions. Collectively, these findings highlight the potential of diverse protein sources to improve the sustainability of livestock systems while preserving productivity and enhancing the nutritional quality of animal-derived foods. Full article

Phytic acid is an antinutritional factor present in lupine seeds, which limits the bioavailability of essential minerals such as calcium, iron, and zinc. This study evaluated different methods of reducing phytic acid in bitter lupine (Lupinus angustifolius) and investigated the effects of the resulting reduction in phytic acid on the composition of gut microbiota. Bitter lupine is a legume rich in protein and fiber, but its high phytic acid content can limit mineral bioavailability. Four processing methods were compared as follows: thermal treatment, enzymatic hydrolysis with phytase, spontaneous fermentation, and controlled fermentation using lactic acid bacteria. Controlled fermentation resulted in the highest phytic acid reduction (96.37%), significantly improving mineral availability. Simulated digestion revealed that the fermented lupine feed positively influenced gut microbiota, increasing Lactobacillus abundance. Enzymatic and thermal treatments preserved more protein. However, they were less effective at removing phytic acid. These findings highlight controlled fermentation as a promising strategy for improving the nutritional value of lupine-based feed, offering a sustainable alternative to soybean-based livestock diets. Full article

Yellow lupin seeds are a rich source of protein, which is why they are grown for animal feed and human consumption. At the same time, there is growing interest in organic farming. However, this type of cultivation is more susceptible to diseases, including viral ones. Yellow lupin is most commonly affected by the bean yellow mosaic virus (BYMV) and cucumber mosaic virus (CMV). We have therefore determined the occurrence of these two pathogens in six new Polish yellow lupin cultivars (Goldeneye, Salut, Diament, Puma, Mister and Bursztyn) grown in accordance with organic farming rules. Field experiments were conducted over three years, from 2022 to 2024, in three locations in eastern Poland. The Goldeneye cultivar was the most susceptible to BYMV, with an average infection rate of 59.17% of plants. In contrast, the Puma cultivar was the least susceptible to BYMV infection, with an average infection rate of 23.34%. However, even within this cultivar, most plants were infected under conditions of strong pathogen pressure (up to 90% in one of the locations in 2024). CMV infections were less frequent, with no statistical differences being found between cultivars in terms of the number of infected plants. Full article

The aim of this study was to evaluate the influence of genotype and diet on geese from crossbreeding meat lines Tapphorn (T) and Eskildsen (E). This study was conducted on 240 crossbred geese assigned to two dietary groups: an SBM diet group fed a standard soybean-based diet and an LPS diet group fed a yellow lupin-based diet. Birds were reared under identical management conditions and slaughtered at 17 weeks of age. The following traits were recorded: meat colour (CIELab), pH₂₄, cooking loss, breast and thigh muscle texture (shear force and energy), and sensory traits. The results showed a significant effect of both genotype and diet on meat quality. The LPS diet lowered shear force and energy (by ~11%, p < 0.001), reduced cooking loss in breast muscles (by ~5%, p < 0.001), and improved the juiciness and flavour of thigh muscles. The ET genotype positively influenced the meat colour intensity (lower L*, higher a*), while the lupin-based diet improved technological parameters, especially the water-holding capacity. The results confirm that replacing soybean meal with yellow lupin protein is an effective nutritional strategy that can improve goose meat quality and sustainability without compromising the sensory quality. These outcomes support developing soy-free feeding strategies in goose production to meet consumer expectations and reduce reliance on imported feed. Full article

The growing demand for plant-based protein alternatives has driven interest in protein modifications to enhance their functional properties in food applications. Enzymatic cross-linking using laccases derived from Rhus vernicifera (LR) and transglutaminase (TG) offers a promising strategy to enhance protein solubility, emulsifying properties, and foaming properties of food proteins. This study varied the enzymatic reaction conditions, including enzyme concentration, pH, temperature, incubation time, and ferulic acid addition, for the most effective cross-linking between proteins in lupin flour (LF) and soy protein isolate (SPI), resulting in changes in physicochemical and functional properties of the cross-linked proteins. LR-induced cross-linking in lupin and soy proteins was most favourable at 142.5 U/100 mg protein, pH 6, and 20 °C, where ferulic acid enhanced cross-linking efficiency with prolonged incubation (20 h). TG-induced cross-linking in lupin and soy proteins was most favourable at 1.25 U/100 mg protein, pH 6 and 30 °C, where high-molecular-weight aggregates were observed. Cross-linking modified protein surface characteristics, increasing ζ-potential and particle size due to protein aggregation, while ferulic acid further enhanced polymerisation. Morphological analysis revealed a porous powder structure across all samples with increased porosity in cross-linked samples as evidenced by the predominance of small fragments within the particles. Prolonged incubation led to partial disaggregation in LR-treated samples unless they were stabilised by ferulic acid. Under mild conditions (1 h, pH 6, 20 °C), LR and ferulic acid-added samples showed minor and significant improvements in protein solubility and foaming stability, respectively. Additionally, a significant increase in foaming ability was observed in ferulic acid-added LR samples after prolonged incubation (20 h), compared to the corresponding control. In contrast, prolonged incubation (20 h) or TG treatment had a lower foaming stability compared to the mild LR treatment. Emulsifying ability and emulsion stability showed limited variation across treatments. These findings suggest that cross-linking conditions influence specific functional properties, highlighting the need for further optimisation to achieve desired protein functionality in food applications. Full article

The increasing frequency of extreme weather events, exacerbated by climate change, has caused significant physical damage to crops worldwide. This study explores the potential of repurposing crop plants that exhibit structural breakage due to hailstorms and strong winds and were originally cultivated for seed production (amaranth, borage, camelina, flax, quinoa, soybean, and white lupin) as alternative forages for ruminants. Their nutritional value was assessed by analyzing chemical composition, in vitro dry matter degradability (DMD), in vitro neutral detergent fiber degradability (NDFD), estimated dry matter intake (DMI), and relative feed value (RFV) compared to conventional forages (alfalfa and ryegrass hay from undamaged plant). Results revealed significant variability among the damaged crops. Borage, amaranth, and white lupin exhibited superior DMD, NDFD, estimated DMI, and RFV, positioning them as promising forage alternatives. Soybean and quinoa showed protein content, DMD, NDFD, estimated DMI, and RFV comparable to alfalfa hay, suggesting their suitability as substitutes. However, camelina exhibited limited NDFD, while flax had low DMD, NDFD, estimated DMI, and RFV, indicating the need for pre-treatment strategies to optimize their nutritional value. Overall, repurposing weather-damaged borage, amaranth, white lupin, soybean, and quinoa as alternative forages for ruminants provides a promising approach to mitigating feed shortages, improving feed resource utilization, and optimizing resource utilization in livestock production. Full article

Plant proteins are garnering interest due to the growing demand for plant-based products, but their functionality in gel-based foods remains limited. Ultrasound (US) technology may improve the technological properties of proteins. Thus, the effect of US treatment time (0–15 min) on the structure and gelling properties of pea, lupin, and rice proteins was evaluated. The results showed that the whiteness (~60%) of all freeze-dried proteins remained unchanged (p > 0.05), regardless of the US time. However, FT-IR analysis revealed progressive reductions in α-helix and β-sheet for pea and lupin proteins (~50%) with US time, indicating partial unfolding. In addition, microstructure analysis showed an ~80% reduction in aggregate size for these proteins, while rice protein exhibited minimal changes. Conversely, weak gels were formed with pea and lupin proteins treated after 5 and 10 min of US, respectively, whereas rice protein did not form gels. Furthermore, US treatment time significantly increased (p < 0.05) the mechanical moduli, resulting in more structured gels after longer treatment times (tan δ ~0.3 at 15 min of US). These findings suggest that US treatment enhances the gelling properties of pea and lupin proteins, making them more suitable for plant-based food applications such as yogurt or desserts. Full article

Protein is a fundamental macronutrient in the human diet. It supplies our organisms with essential amino acids, which are needed for the growth and maintenance of cells and tissues. Conventional protein sources, despite their complete amino acid profiles and excellent digestibility, have a proven negative impact on the environment. Furthermore, their production poses many ethical challenges. This review aims to present nutritional, more ethical, and environmentally friendly alternatives that could serve as potential protein sources for the population. The available literature on alternative protein sources has been analyzed. Based on the research conducted, various products have been identified and described, including plant-based protein sources such as soybeans, peas, faba beans, lupins, and hemp seeds; aquatic sources such as algae, microalgae, and water lentils; as well as insect-based and microbial protein sources, and cell-cultured meat. Despite numerous advantages, such as a lower environmental impact, higher ethical standards of production, and beneficial nutritional profiles, alternative protein sources are not without limitations. These include lower bioavailability of certain amino acids, the presence of antinutritional compounds, technological challenges, and issues related to consumer acceptance. Nevertheless, with proper dietary composition, optimization of production processes, and further technological advancements, presented alternatives can constitute valuable and sustainable protein sources for the growing global population. Full article

Pulses are grown worldwide and provide agronomic benefits that contribute to the sustainability of cropping systems. Pulses are high in protein and provide a good source of carbohydrates, dietary fibre, vitamins, minerals, and bioactive constituents. Crops such as lupins, chickpeas, faba beans, field peas, lentils, and mung beans, and the diversity of varieties among them, provide enormous opportunities for processing protein ingredients for use in new and existing food formulations. This review highlights the nutritional properties of pulses, protein quality, functionality, and applications for pulse protein ingredients. Understanding the functionality of pulse proteins, and the unique properties between different pulses in terms of solubility, water- and oil-holding capacity, emulsification, gelation, and foaming properties, will help maximise their use in plant-based meat and dairy alternatives, beverages, bakery products, noodles, pasta, and nutritional supplements. In this review, researchers, food technologists, and food manufacturers are provided with a comprehensive resource on pulses, and the diverse applications for pulse protein ingredients within the context of food manufacturing and the constantly evolving food technology landscape. Full article