Search Results (309)

Introduction: The increasing global interest in plant-based diets has led to the development of innovative meat analogs that not only mimic the sensory properties of traditional products but may also offer potential health benefits. In this study, we investigated the nutritional characteristics and biological activity of potato protein-based vegan burgers (PBBs) enriched with plant-derived iron and fiber sources. Methods: The burgers were subjected to in vitro gastrointestinal digestion, followed by evaluation of their cytotoxic potential against human intestinal cancer cell lines (Caco-2 and HT-29) and normal colon epithelial cells (CCD 841 CoN). Additionally, their influence on the intestinal microbiota composition and enzymatic activity of β-glucosidase and β-glucuronidase was assessed. Results: PBBs demonstrated favorable nutritional profiles, high protein and fiber contents, and a balanced fatty acid ratio (n-6/n-3). After digestion, bioaccessible fractions showed selective cytotoxicity toward cancer cells, while maintaining safety for normal intestinal cells. Furthermore, PBBs modulated the gut microbiota by promoting the growth of beneficial genera (Lactobacillus, Bifidobacterium) and reducing potentially harmful Enterobacteriaceae, accompanied by decreased β-glucuronidase activity. Conclusions: These findings suggest that potato protein-based burgers could represent a functional plant-based alternative to conventional meat products, contributing to intestinal health and potentially reducing colorectal cancer risk. Full article

Dabie Mountain cattle are characterized by their ability to tolerate coarse feed, strong disease resistance, and delicious meat. Lower reproductive efficiency has become one of the key factors limiting its development. Therefore, this study investigated the developmental patterns of Dabie Mountain cattle follicles and screened key candidate genes for in vitro experimental validation. Research collected granulosa cells from small follicles (<5 mm), medium (5–8 mm), and big (>8 mm), followed by RNA extraction for transcriptomic sequencing. A total of 20,775 genes were identified, including 13,777 (66.3%) differentially expressed genes (DEGs). DEGs showing up-regulation and down-regulated in B vs. S, B vs. M, and M vs. S groups were collected. A total of 19 commonly up-regulated DEGs across the three groups were identified, including genes such as DEFB, FAM124A, and RASSF10. Additionally, 227 commonly down-regulated DEGs were identified, including genes such as INSL3, GAS7, and PAQR7. Protein interaction network analysis revealed an interaction between INSL3 and STAR. Bovine ovarian granulosa cells (GCs) were collected to investigate the effect of the INSL3 on GCs proliferation. The results revealed that INSL3 expression was highest in small follicles and was almost absent in big follicles. Subsequently, the INLS3 gene was knocked down in GCs using small interfering RNA. RT-qPCR results demonstrated that both si-INSL3 (239) and si-INSL3 (392) significantly knock down INSL3 expression (p < 0.01), si-INSL3 (239) for follow-up research. CCK-8 was used to assess cell proliferation, revealing that INSL3 knockdown significantly enhanced GCs viability and number at 24, 48, and 72 h (p < 0.05). Flow cytometry was used to detect cell cycle distribution. The results showed that knockdown of INSL3 expression significantly decreased the proportion of G1 phase cells and significantly increased the number of S phase cells (p < 0.01). RT-qPCR was used to detect the expression of cell proliferation-related genes. The results showed that compared with the siNC group, the expression levels of Myc, PCNA, Cytochrome C, and Cyclin D1 were significantly increased in the si-INSL3 group. In conclusion, knockdown of INSL3 affects follicular development in Dabie Mountain cattle by regulating granulosa cell proliferation in the ovaries, providing new insights into the regulatory mechanisms of follicular development in cattle. Full article

This experiment was designed to systematically evaluate the immunomodulatory effect of water extract of Artemisia annua L. (WEAA) on sheep, both in vivo and in vitro, and to determine the involvement of the TLR4/NF-κB signaling pathway in mediating these effects. In experiment 1, 32 female sheep (Dorper × Han, 3 months old, 24 ± 0.09 kg each) were designated to 4 groups, with each group receiving a basal diet supplemented with, respectively, 0 (control group), 500, 1000, and 1500 mg/kg WEAA. The serum, liver, and spleen immune indicators and related gene expressions were measured. In experiment 2, the peripheral blood lymphocytes (PBLs) were processed with WEAA (0, 25, 50, 100, 200, and 400 μg/mL), with six replicates assigned to each concentration group, then the cell viability, immune function, and related gene expressions were measured, and the optimal concentration of WEAA was determined. In experiment 3, the experimental groups consisted of PBLs subjected to treatments with or without PDTC (NF-κB inhibitor) and with or without WEAA, forming four distinct treatment groups (six replicates/group): PDTC(−)/WEAA(−) group, PDTC(−)/WEAA(+) group, PDTC(+)/WEAA(−) group and PDTC(+)/WEAA(+) group. The immune indexes and TLR4/NFκB pathway related indexes were determined. The results were as follows: WEAA dose-dependently enhanced the content of immunoglobulins (IgA, IgG, IgM) and cytokines (IL-1β, IL-2, IL-4) in the serum, liver, and spleen tissues, among which IgA, IgG, and IL-4 were the most significantly affected core indicators (p < 0.05). Meanwhile, WEAA dose-dependently upregulated the expression of TLR4/NF-κB pathway-related genes (TLR4, IKKβ, IκBα, NF-κBp65) and their downstream cytokine-related genes (IL-1β, IL-4) in liver and spleen tissues (p < 0.05). Of these genes, liver IL-4, IκBα, and spleen IL-4 were the most prominently regulated core genes (p < 0.05), The optimal supplementary dose of WEAA was determined to be 1000 mg/kg. In addition, adding 100 μg/mL WEAA to the culture medium of PBLs significantly enhanced immune function and cell viability. The underlying mechanism involved the TLR4/NF-κB pathway; that is to say, WEAA enhanced sheep’s immune indicators by upregulating TLR4/NF-κB pathway genes, thereby coordinately regulating humoral and innate immunity, thereby improving the immune indices of sheep. This study provided compelling experimental support for the prospective utilization of WEAA as a functional feed supplement in intensive meat-type sheep production systems. Full article

This study presents a systematic literature review to examine how the axiological values associated with cultured meat influence consumer perception, using the phenomenology of perception as an analytical framework. Fifty-four peer-reviewed qualitative and quantitative studies, identified through the Libraries Worldwide database, were analyzed using NVivo 12 software, based on predefined keywords and a rigorous selection grid. The results highlight several groups of axiological values that shape consumer attitudes, including the previously unexplored “axiological value of co-production” of cultured meat. Specifically, “dogmatic co-production” (e.g., religious or cultural co-production) appears to significantly enhance consumer perception and acceptance of cultured meat. The main limitation of this study lies in the absence of primary phenomenological field data, which may introduce researcher subjectivity inherent in qualitative paradigms. Nevertheless, the use of existing empirical studies ensures the relevance and reliability of this review. This research offers practical implications for communication strategies, suggesting that aligning messages with key axiological values and their amplifiers, particularly those related to co-production, can strengthen trust in and acceptance of cultured meat. For industry stakeholders, these findings provide guidance for value-driven positioning aimed at increasing consumer confidence. Academically, the study offers a novel perspective by integrating axiological analysis with phenomenology in the context of food technology adoption. Socially, it helps identify consumer concerns and expectations regarding the axiological values perceived as essential for the acceptance of cultured meat. The study’s originality lies in its application of phenomenological analysis to axiological frameworks and in highlighting the central role of co-production, particularly dogmatic co-production, in shaping consumer perception. Full article

Cultured meat has progressed from early in vitro cell culture concepts to regulatory approvals and preliminary commercialization, with recent advancements propelled by interdisciplinary innovations in cell line engineering, serum-free media, bioreactor design, and three-dimensional (3D) assembly technologies. This review synthesizes recent developments from 2023 to 2025, utilizing peer-reviewed publications, patent analyses, regulatory frameworks, and media reports to assess global preparedness for large-scale production. Asia has emerged as a leading hub, with China, Japan, South Korea, and Singapore focusing on scaffold-based 3D cultures, bioinks, and serum-free strategies, complemented by national centers and pilot facilities. The United States leverages its technological advancements and established regulatory framework, as evidenced by recent Food and Drug Administration and United States Department of Agriculture approvals. However, potential complications related to political regional bans and legislation may arise. Europe and the UK prioritize defined media, cell optimization, and structured novel-food regulations, with early commercialization primarily in pet food. Looking ahead, the industrialization of cultured meat is anticipated to be driven by process engineering and hybrid product strategies, with initial pilot-to-demonstration facilities established in countries open to alternative food products. Premium and hybrid cultured meat products are expected to enter the market first, while whole-cut cultured meat is likely to remain a premium offering into the early 2030s. Full article

The growing demand for sustainable food packaging has driven the development of active packaging systems using biopolymers like poly(lactic acid) (PLA) and natural antimicrobials. This study focuses on creating novel nanohybrids by loading carvacrol (CV) and trans-cinnamaldehyde (tCN) onto ZnO nanorods for incorporation into PLA/triethyl citrate (TEC) films. The CV@ZnO and tCN@ZnO nanohybrids were synthesized and characterized using XRD, FTIR, desorption kinetics, and by assessing their antioxidant and antibacterial properties. These nanohybrids were then integrated into PLA/TEC films via extrusion. The resulting active films were evaluated for their physicochemical, mechanical, barrier, antioxidant, and antibacterial properties. The tCN@ZnO nanohybrid exhibited a stronger interaction with the ZnO surface and a slower release rate compared to CV@ZnO. While this strong interaction limited its direct antioxidant activity, it proved highly beneficial for the final film’s performance. Films containing 10% tCN@ZnO demonstrated the strongest antibacterial efficacy in vitro against Listeria monocytogenes and Escherichia coli and functioned as potent mechanical reinforcement fillers. Crucially, in a practical application, the PLA/TEC/10tCN@ZnO film significantly extended the shelf-life of fresh minced pork during 6 days of refrigerated storage. It effectively suppressed microbial growth (TVC), delayed lipid oxidation (lower TBARS values), and preserved the meat’s colour and nutritional quality (higher heme iron content) compared to control packaging. The developed tCN@ZnO nanohybrid is confirmed to be a highly effective active agent for creating PLA/TEC-based packaging that can enhance the preservation of perishable foods. Full article

Socol is an artisanal meat product typical of Southeast Brazil. It is made from pork loin and ripened at room temperature. This work aimed to isolate, quantify, and identify lactic acid bacteria (LAB) in Brazilian dry-cured loin (Socol) as well as evaluate their in vitro probiotic potential. LAB were found in high amounts, varying from 2.5 × 10³ to 9.2 × 10⁶ CFU g⁻¹. Eleven isolated bacteria were identified by Matrix-Assisted Laser Desorption Ionization–Time-Of-Flight/Mass Spectrometry (MALDI-TOF/MS). Of these, six strains (Latilactobacillus brevis SFC1A, Latilactobacillus sakei SFC2A, Latilactobacillus curvatus SFC6A, Pediococcus acidilactici SFC9A, Latilactobacillus curvatus SFC11A, and Pediococcus pentosaceus SFC11B) were submitted to in vitro probiotic tests. All were tolerant to bile salts and five of them to artificial gastric juice, and were all sensitive to tetracycline, chloramphenicol, and erythromycin. L. brevis SFC1A and P. acidilactici SFC9A inhibited all tested pathogenic bacteria and showed the broadest in vitro probiotic activity. Thus, they would be recommended as starter cultures for the elaboration of novel fermented meat products and to compose a bank of indigenous bacteria, as well as contribute to preserving Socol microbiota. Full article

The search for sustainable and health-promoting food ingredients has positioned microalgae as promising candidates for the development of functional products. Haematococcus pluvialis, a unicellular green microalga, is the richest natural source of astaxanthin, a carotenoid with outstanding antioxidant, anti-inflammatory, and neuroprotective properties. In addition to astaxanthin, H. pluvialis provides high-value proteins, essential fatty acids, polysaccharides, and vitamins, which expand its potential applications in the food sector. This review compiles current knowledge on the biology and physiology of H. pluvialis, with emphasis on cultivation strategies, environmental stress factors, and biotechnological tools designed to enhance bioactive compound production. Advances in extraction and purification methods are also discussed, contrasting conventional solvent-based approaches with emerging green technologies. The integration of these strategies with biomass valorization highlights opportunities for improving economic feasibility and sustainability. Applications of H. pluvialis in the food industry include its use as a functional ingredient, natural colorant, antioxidant, and stabilizer in bakery products, beverages, meat analogs, and emulsified systems. Evidence from in vitro, in vivo, and clinical studies reinforces its safety and effectiveness. Looking ahead, industrial perspectives point to the adoption of omics-based tools, metabolic engineering, and circular economy approaches as drivers to overcome current barriers of cost, stability, and regulation, opening new avenues for large-scale applications in food systems. Full article

The study examined how transglutaminase (TG)-induced cross-linking affects the structural, functional, and in vitro digestibility characteristics of rice dreg protein (RDP). Analysis using SDS-PAGE showed that low-molecular-weight fragments vanished, while high-molecular-weight polymers formed. Additionally, Fourier transform infrared (FTIR) spectroscopy demonstrated a reduction in β-sheet content alongside an elevation in β-turn structures as the cross-linking process became more pronounced, which was associated with a reduction in both total and free sulfhydryl groups. The hydrophobic nature of the surface and the emulsifying properties of cross-linked RDP initially rose but began to decrease when TG concentrations surpassed 10 U/g of protein. Conversely, emulsion stability and water-binding capacity decreased, while oil-binding capacity improved compared to native RDP. Solubility and in vitro digestibility decreased with cross-linking, whereas rheological properties significantly improved with higher TG levels. These findings suggest that controlled TG-mediated cross-linking (e.g., 10 U/g) effectively enhances the functional properties of RDP, making it a promising ingredient for applications in plant-based meats, baked goods, and fortified beverages within the food industry. Full article

This work explores the impact of ergosterol (ERG) addition (0%, 0.5%, 1.0%, 1.5%, and 2.0%) on the physicochemical properties, conformational changes, and digestive characteristics of soy protein isolate (SPI) and wheat gluten (WG) processed by high-moisture extrusion. The results demonstrated that the incorporation of ERG significantly reduced the apparent viscosity and dynamic moduli of the feedstock system, enhancing melt fluidity and consequently reducing extrusion torque, die pressure, and specific mechanical energy. An appropriate amount of ERG (1.0%) effectively facilitated the development of a distinct fibrous morphology, increased the fibrous degree, lightened the color, and softened the texture. However, excessive addition weakened the fibrous structure due to excessively high fluidity. ERG influenced protein aggregation behavior through hydrophobic interactions, reduced thermal stability, and induced a transition in secondary structure from β-turns to α-helices. The in vitro digestibility initially decreased and then increased, with the lowest value observed at 1.0% ERG. This study indicates that ERG can elevate the performance and value of extruded products by modulating protein structure and rheological behavior, providing a theoretical basis for its application in plant-based meat analogue products. Full article

Nitrosamines (NAs) pose a risk due to their carcinogenic properties, especially in processed and cured meats where nitrites and nitrates are widely used. The objective of this study was to develop an integrated Ultra-High-Performance Liquid Chromatography–High-Resolution Mass Spectrometry (UHPLC–HRMS) workflow for detecting both volatile (VNAs) and non-volatile (NVNAs) nitrosamines in meat matrices. Comparison of two ionization techniques showed that heated electrospray ionization (HESI) and atmospheric pressure chemical ionization (APCI) provided complementary coverage and sensitivity. Extraction and cleanup were optimized for meat, although recovery rates remained variable, underscoring the analytical complexity. The method was applied to raw, cooked, cured, and grilled meats, as well as to in vitro gastric digestion and co-digestion with spinach. Results revealed that some NAs were present even in untreated raw meat (≈3.0 µg/kg, N-nitrosodi-n-butylamine), while the addition of nitrites and nitrates significantly increased their levels (more than 10 µg/kg, N-nitrosodiethylamine, N-nitrosodimethylamine, N-nitrosodi-n-butylamine). Gastric digestion was the most critical condition, further promoting nitrosamine formation, particularly for N-nitrosodiethylamine, N-nitrosodi-n-butylamine, and N-nitrosopiperidine. Ascorbate exhibited a dual role, acting as an inhibitor at low nitrite concentrations but becoming pro-oxidant at high levels (300 mg/kg). Cooking alone had limited impact, whereas cooking combined with digestion yielded the highest and most consistent nitrosamine concentrations. The inclusion of spinach during digestion modestly altered nitrosamine levels, reflecting both its nitrate content and polyphenolic profile. Nonparametric ANOVA (aligned rank transform) confirmed that preservative treatment, rather than processing or interaction effects, was the main driver of variability (total nitrosamines: H = 24.15, p = 2.33 × 10⁻⁵), with the combination of preservative ascorbate plus nitrite producing significantly higher levels than other treatments (q = 0.000656). N-nitrosodimethylamine consistently emerged as the most relevant marker for dietary exposure, in agreement with EFSA guidance. Overall, this study underscores both the analytical and biochemical complexity of nitrosamine detection and formation in meat products, while highlighting the importance of preservative formulation and the potential role of dietary antioxidants in mitigating exposure. Full article

The Atlantic blue crab (Callinectes sapidus) is an opportunistic invasive species in the Mediterranean that is negatively affecting biodiversity, fisheries, and tourism. In Italy, it is appreciated for its good meat quality, but the processing yield is low (21.87 ± 2.38%), generating a significant amount of by-products (72.45 ± 4.08%), which are underutilized. Valorizing this biomass is in line with circular economy principles and can improve both environmental and economic sustainability. This study aimed to valorize Atlantic blue crab by-products (BCBP), producing protein hydrolysates and assessing their in vitro bioactivities, in order to plan applications in animal food and related sectors. BCBP hydrolysates were obtained by enzymatic hydrolysis using Alcalase and Protamex enzymes. The treatment with Alcalase resulted in a higher degree of hydrolysis (DH = 23% in 205 min) compared to Protamex (DH = 14% in 175 min). Antioxidant activity of the hydrolisates was evaluated through DPPH, ABTS, reducing power and FRAP assays, as well as in vitro test in fibroblasts (HS-68). At 10 mg/mL, hydrolysates from both enzymes exhibited the maximum radical scavenging activity in DPPH and ABTS assays. In HS-68 cells, 0.5 mg/mL hydrolysates protected against H₂O₂-induced oxidative stress, showing a cell viability comparable to cells treated with 0.5 mM N-acetyl cysteine (NAC), as an antioxidant. Statistical analyses were performed using one-way ANOVA followed by Student–Newman–Keuls (SNK) or Games–Howell post hoc tests, with significance set at p < 0.05. Overall, both enzymes efficiently hydrolyzed BCBP proteins, generating hydrolysates with significant antioxidant activity and cytoprotective effects. These results demonstrate the potential to produce high-quality bioactive compounds from BCBPs, suitable for food, nutraceutical, and health applications. Scaling up this valorization process represents a viable strategy to improve sustainability and add economic value to the management of this invasive species, turning a problem in a resource. Full article

The global need for tissue and organ transplantation paved the way for plant-based scaffolds as cheap, ethical, and valuable alternatives to synthetic and animal-derived matrices for tissue regeneration. Over the years, the field has outgrown its initial scope, including the development of tissue models, platforms for drug testing and delivery, biosensors, and laboratory-grown meat. In this scoping review, we aimed to shed light on the frequency of the use of different plant matrices, the main techniques for decellularization, the functionalization methods for stimulating mammalian cell attachment, and the main results. To that purpose, we searched the keywords “decellularized” AND “scaffold” AND (“plant” OR “vegetable”) in online-available databases (Science Direct, Scopus, PubMed, and Sage Journals). From the selection and study of 71 articles, we observed a multitude of plant sources and tissues, along with a large and inhomogeneous body of protocols used for decellularization, functionalization and recellularization of plant matrices, which all led to variable results, with different extents of success (mostly in vitro). Since the field of plant-based scaffolds shows high potential for growth in the next few years, driven by emerging biotechnological applications, we conclude that future research should focus on plant sources with low economic and environmental impacts while also pursuing the standardization of the methods involved and a much deeper characterization of the scaffold performance in vivo. Full article

It was hypothesized that differences in production system and muscle type may influence the formation of lipid oxidation products (LOP) as well as protein oxidation (protein carbonyl compounds, PCC) during the in vitro gastrointestinal digestion of chicken meat. To test our hypothesis, we investigated the formation of LOP and PCC after heating and in vitro gastrointestinal digestion of conventional and organic chicken breast and thigh meat and Wooden Breast meat. Prior to the in vitro digestion, thigh and breast meat was minced and heated. Digests of organic thigh meat had significantly higher levels of all LOP measured compared to conventional thigh meat (between +37% and +173%). Lower levels of LOP were found in digests of breast meat regardless of the production system and Wooden Breast phenotype. LOP correlated positively with heme-Fe and polyunsaturated fatty acids, negatively with anserine, and not with carnosine and α-tocopherol. PCC levels were significantly higher in thigh meat than in breast meat after heating (+43%) and digestion (+25%), irrespective of the production system. Overall, organic thigh meat exhibited the highest oxidative sensitivity during digestion. The cut-dependent differences in composition and oxidative susceptibility between organic and conventional chicken highlight the need for further research to assess potential health implications. Full article

The popularity of processed meats stems from modern demand for ready-to-eat foods, but their saturated and trans fats pose health concerns. Oleogel-based systems, which turn healthy oils into solid fat-like matrices, offer a promising alternative. This study characterized virgin olive oil oleogels structured with chitosan, assessing rheological, thermal, structural, and functional properties, examining how chitosan concentration (1–3%) and oil-to-water ratio (50–60) affect their performance. Rheological tests indicated a predominantly elastic behavior, suggesting the formation of stable gel networks, while a thermogravimetric analysis confirmed thermal stability of up to 237 °C, indicating suitability for moderate thermal processing. Texture analysis showed wider values for hardness (1.25–12.20 N) and color measurements indicated a homogeneous appearance across formulations with oleogels with high luminosity (L* > 50). The oleogels demonstrated high oil-binding capacity (>90%) and reduced oxidative degradation compared to bulk olive oil (peroxide values within regulatory limits for olive oils and TBARS values below 0.6 μmol malonaldehyde). In vitro digestion assays showed a slightly reduced lipid release with respect to pure olive oil, highlighting their potential for controlled lipid delivery and enhanced nutritional value. These findings support the potential of chitosan-based oleogels with virgin olive oil as stable and functional fat replacers in food applications. Full article