Search Results (70)

Seafood, rich in nutrients, undergoes rapid quality deterioration, primarily due to microbial activity and lipid oxidation. Conventional petroleum-based packaging is widely used for seafood but lacks the ability to retard spoilage. Carbon dots (CDs), which are nanosized, act as multifunctional additives that can be incorporated into biopolymer films to prepare active, biodegradable packaging. CDs are produced through green synthesis methods using various agro-byproducts, including fruit peels, leaves, and rhizomes, thus aligning well with circular economy principles. CDs have antioxidant and antimicrobial activities, as well as UV barrier properties. CDs from different sources show varying bioactivities and properties. The bioactivities of CDs are enhanced by doping with compounds such as polyphenols and amino acids. When CDs are applied to biopolymer matrices such as chitosan and gelatin, the increases in mechanical strength, water vapor barrier properties, thermal stability, and ultraviolet light-blocking ability can be achieved. Recent investigations into the performance of films containing CDs from different sources for the shelf life extension of various seafood are revisited. The limited commercial implementation, particularly of large-scale synthesis, is addressed. The migration behavior and toxicological profiles are also elucidated. Overall, this review highlights agro-waste-derived CDs as a potential nanomaterial for developing next-generation active packaging systems for seafood preservation and environmental sustainability. Full article

The rising global demand for functional, “clean-label” fermented foods has driven intense interest in versatile microbial starter cultures. Levilactobacillus brevis is an obligately heterofermentative lactic acid bacterium that is highly valued for its robust environmental adaptability and exceptional capacity to synthesize bioactive metabolites, notably γ-aminobutyric acid (GABA) and exopolysaccharides (EPS). This review comprehensively evaluates the recent progress in L. brevis applications across major food fermentations. In dairy systems, L. brevis is most effective in co-cultures, where partner starters compensate for limited proteolysis and acidification, enabling improved texture, aroma profiles, and GABA enrichment. In fermented meats, selected strains contribute to nitrite reduction, flavor formation, and bioprotection, supporting nitrite-reduced strategies while maintaining sensory quality. In fish and seafood fermentations, L. brevis shows promise for controlling spoilage indicators and biogenic amines (notably histamine) in high-salt environments, although strain compatibility in mixed cultures is product-dependent. In plant-based matrices, outcomes are strongly constrained by acidity and nitrogen limitation; however, optimized fermentation can enhance phenolic bioaccessibility, generate high GABA levels, and enable emerging precision-biofortification approaches. Despite these functional advantages, its industrial application is frequently constrained by strain-specific technological limitations, and its use often necessitates synergistic co-culture systems, particularly in challenging matrices. Ultimately, this review highlights current research gaps and proposes future directions, including multi-omics integration and targeted strain evolution, to overcome sensory trade-offs and fully harness the biotechnological potential of L. brevis in next-generation functional foods and agricultural byproduct valorization. Full article

The global seafood industry generates millions of tons of by-products each year, creating environmental and economic challenges but also presenting a valuable opportunity for resource recovery. These by-products, rich in bioactive compounds such as proteins, omega-3 fatty acids, collagen, chitin, and antioxidants, have traditionally been underutilized due to inefficient and energy-intensive conventional extraction processes. Pulsed electric field (PEF) technology has emerged as a promising, non-thermal, and environmentally friendly method for valorizing seafood by-products by enhancing the permeability of biological membranes through electroporation, thereby facilitating the efficient extraction of high-value compounds. This manuscript critically reviews the scientific principles underpinning PEF, including dielectric breakdown and transmembrane potential generation, and explores its mechanisms for improving mass transfer during extraction and dehydration. Applications of PEF for recovering proteins, lipids, and antioxidants from diverse seafood side streams are comprehensively discussed, with emphasis on its advantages such as reduced energy consumption, preservation of thermolabile compounds, and improved product quality compared to conventional methods. Despite demonstrated laboratory-scale successes, industrial adoption of PEF remains limited due to challenges in process optimization, economic feasibility, and regulatory frameworks. This review synthesizes current knowledge and provides guidance for future research to advance the industrial implementation of PEF as a sustainable and efficient tool for seafood by-product valorization. Full article

Repetitive temperature fluctuations during transportation and storage promote ice crystal formation in salmon flesh, leading to protein denaturation, lipid oxidation, and quality loss. Tuna skin, a major by-product of tuna processing, is a potential source of antifreeze peptides (AFPs) but remains underutilized. This study examined the cryoprotective effects of tuna skin-derived AFPs on salmon cubes subjected to repeated freeze–thaw cycles. Cubes treated with AFPs from three groups of protein hydrolysates prepared using trypsin, pepsin, or neutral protease were evaluated for texture, color, water holding capacity (WHC), volatile odor profiles, protein conformation, biochemical indices, and microstructure. AFP treatment improved textural properties, maintained color stability, and reduced thawing, cooking, and centrifugal losses. The neutral protease-treated group exhibited the optimal cryoprotective ability and it also limited aldehyde and sulfide accumulation, preserved the retention rate of α-helix structure at 49% which was higher than 39% in controls, and enhanced Ca²⁺-ATPase activity to 1.75 μmol Pi·mg⁻¹·h⁻¹ with a 45.8% increase compared to controls, and significantly inhibited protein and lipid oxidation. Microstructural analysis showed compact fibers and intact sarcolemma in the neutral protease-treated group samples, contrasting with severe disruption in controls. This study showed that tuna skin AFPs mitigate freeze–thaw damage in salmon cubes by stabilizing proteins and reducing oxidative deterioration, highlighting their potential as natural, healthy cryoprotectants for seafood preservation, meeting the growing demand of the food industry for clean-label, low-calorie preservation solutions, while advancing the circular economy of aquatic processing via the valorization of tuna skin by-products for high-value seafood applications. Full article

Marine byproducts generated from seafood processing represent valuable reservoirs of structurally and functionally distinct biomolecules, whose composition reflects species, habitat, and processing history. This systematic review identified which marine byproducts have been most extensively studied between 2020 and 2025, with emphasis on their composition, valorisation, and suitability for tracing their geographic origin. Following the PRISMA protocol, 6443 publications were initially retrieved, of which 96 peer-reviewed studies were included for data extraction and analysis. The five most frequently investigated byproducts—skin, bones, scales, shells, and roe—were identified as rich sources of proteins (collagen and gelatin), minerals (hydroxyapatite and calcium carbonate), polysaccharides (chitin), lipids (notably polyunsaturated fatty acids (PUFAs), docosahexaenoic acid (DHA) and eicosapentaenoic acid (EPA)), and vitamin B12. Collagen properties, particularly imino acid content, hydroxylation degree, crosslinking density, and thermal stability, correlate more strongly with environmental temperature than taxonomy, supporting their potential as markers for tracing geographic origin. The mineral fractions, dominated by hydroxyapatite in bones and scales, or calcium carbonate in shells, provided complementary inorganic fingerprints based on calcium-to-phosphorus ratios, carbonate substitution, trace element composition, and thermal analyses. While the lipid profile alone could not completely discriminate fish roe, proteomic techniques, such as MALDI-TOF MS, make it possible to reliably identify species. Collectively, these byproducts offer complementary organic and inorganic markers that support integrated strategies that allow tracing their origin and fostering their sustainable valorisation, overcoming a key technical bottleneck for their use. However, their large-scale conversion into market-ready products remains limited by technical complexity, process variability, and cost-related constraints. Full article

Seafood processing generates large volumes of by-products that are often underutilized despite their potential as sources of high-value bioactive lipids. In this study, a hybrid process integrating microwave (MW) pretreatment with Soxhlet (SOX) extraction was developed and optimized to intensify the recovery of astaxanthin (ASX)- and ω-3 PUFA-rich oil from green tiger shrimp (Penaeus semisulcatus) residues. Response surface methodology (RSM) comprising 22 experimental runs was applied to optimize key MW process variables, including power (100–400 W) and irradiation time (30–90 s). Both factors significantly influenced oil yield, with optimal operating conditions identified at 400 W and 75 s. MW pretreatment promoted structural disruption of shrimp shells, as confirmed by scanning electron microscopy, thereby enhancing solvent penetration and mass transfer. Solvent selection further affected extraction performance: hexane:isopropanol (1:1, v/v) achieved the highest oil yield (3.86 g/100 g dry weight), while hexane:acetone produced extracts with the highest ASX concentration (1032.24 µg/g oil), ω-3 PUFA content (29.85%), and antioxidant activity (93.30% DPPH scavenging). Colorimetric analysis supported these results, with increased redness (a* = 18.12) correlating with ASX enrichment. Overall, this integrated MW-SOX process represents an effective process-intensification strategy for sustainable shrimp waste valorization and production of bioactive lipid fractions. Full article

The Esox lucius is a high-quality fish species endemic to northern Xinjiang, having developed into a regional specialty industry with significant market value. However, during storage, it is prone to microbial growth that elevates biogenic amine levels, posing potential food safety risks. Therefore, this study systematically evaluated the effects of protamine—extracted from Esox lucius byproducts and used as a natural preservative—on the succession of microbial communities and biogenic amine accumulation in fish muscle under storage conditions of 4 °C, −3 °C, and −18 °C. A detection method for biogenic amines was also established. Results revealed characteristic changes in fish muscle microbial community α-diversity over storage time. Protamine treatment significantly delayed increases in total colony counts and microbial succession processes without altering the final dominant microbial community composition. By optimizing ultrasonic-assisted extraction and derivatization steps, an analytical method suitable for detecting eight biogenic amines in fish muscle matrices was established. Results indicate that protamine effectively inhibits the accumulation of all eight biogenic amines, with the 1% treatment group showing the most significant effect (p < 0.05). This study not only provides basis for the precise application of protamine in seafood preservation but also offers guidance for the resource utilization of aquatic by-products. Full article

The transition toward sustainable and circular bioeconomies in Agriculture 4.0 demands fertilization strategies that reduce environmental impacts while maintaining agronomic productivity. This article presents a structured narrative review of peer-reviewed literature integrating evidence across waste management, soil science, food safety, and regulatory frameworks to evaluate the potential of seafood processing byproducts including fish offal, shellfish residues, and aquaculture effluents as nutrient-rich fertilizers. These materials provide nitrogen, phosphorus, calcium, and essential micronutrients and may contribute to nutrient recycling within precision and resource-efficient agricultural systems. Evidence from diverse cropping contexts indicates that seafood waste-derived fertilizers can improve crop yield, nutrient use efficiency, and soil biological activity under site-specific conditions. Biological processing methods, including composting, enzymatic hydrolysis, and fermentation, are examined for their roles in enhancing nutrient bioavailability and reducing undesirable constituents. Particular emphasis is placed on food safety considerations, including heavy metals, persistent organic pollutants, antimicrobial resistance, pathogens, and microplastics, with discussion of speciation-based risk assessment and mitigation strategies such as thermal treatment, microbial screening, and compliance with international standards. Regulatory fragmentation, economic feasibility, and lifecycle environmental implications are also critically assessed. Emerging digital tools, including Internet of Things (IoT)-enabled nutrient monitoring and artificial intelligence (AI)-assisted compost optimization, are discussed as enabling technologies for integrating seafood-derived biofertilizers into smart farming systems. Overall, this interdisciplinary synthesis highlights the potential contribution of seafood waste valorization to circular nutrient management, environmental stewardship, and sustainable food production. Full article

The food industry generates large volumes of nutrient-rich by-products that remain underutilised despite their considerable biochemical potential. These materials originate predominantly from the fruit and vegetable, dairy, meat, and fish and seafood sectors and represent a substantial opportunity for sustainable valorisation. Fermentation has emerged as a powerful platform for converting such by-products into high-value ingredients, including bioactive compounds, functional metabolites, enzymes, antimicrobials, and nutritionally enriched fractions. This review synthesises recent advances in microbial fermentation strategies—spanning lactic acid bacteria, filamentous fungi, yeasts, and mixed microbial consortia—and highlights their capacity to enhance the bioavailability, stability, and functionality of recovered compounds across diverse substrate streams. Key technological enablers, including substrate pre-treatments, precision fermentation, omics-guided strain selection and improvement, and bioprocess optimisation, are examined within the broader framework of circular bioeconomy integration. Despite significant scientific progress, major challenges remain, particularly related to substrate heterogeneity, process scalability, regulatory alignment, safety assessment, and consumer acceptance. The review identifies critical research gaps and future directions, emphasising the need for standardised analytical frameworks, harmonised compositional databases, AI-driven fermentation control, integrated biorefinery concepts, and pilot-scale validation. Overall, the evidence indicates that integrated fermentation-based approaches—especially those combining complementary by-product streams, tailored microbial consortia, and system-level process integration—represent the most promising pathway toward the scalable, sustainable, and economically viable valorisation of food industry by-products. Full article

A functional seafood product was obtained by biofortifying fish fillets with polyphenols extracted from artichoke by-products. Two fortification techniques—vacuum immersion (VI) and spray coating followed by electroporation (SCE)—were applied and compared with untreated control (CTR) samples. The treated by vacuum immersion (TRT-VI) group showed the highest antioxidant power (DPPH scavenging: 42.5 ± 3.2% vs. 19.6 ± 1.5% in CTR. Colorimetry revealed significant shifts in lightness (L*), red-green component (a*), and yellow-green component (b*) values in raw and cooked fillets. In the TRT-VI group the microbiological shelf life was extended by approximately 4–5 days. Sensory analysis revealed that, despite of bitterness and astringency, key attributes were maintained. Phenolic profiling identified caffeoylquinic acids as the dominant compounds in both artichoke extracts and fortified fillets (range 0.5–304.5 mg·100 g⁻¹). In this study the development of functional seafood products has been implemented through the valorisation of an agri-food by-product and the exploitation of emerging fortification technologies. Key outputs include the assessment of the nutritional value of the fortified fish fillets and the extension of shelf life without compromising key sensory attributes. Future studies could be directed toward the optimisation of formulations and bioavailability of the incorporated polyphenols. Full article

Astaxanthin, a potent antioxidant, has attracted growing interest for its applications in the food, pharmaceutical, and cosmetic industries. This study aims to optimize the green extraction of astaxanthin from shrimp (Parapenaeus longirostris) by-products using ultrasound-assisted extraction (UAE) with extra virgin olive oil (EVOO) as a sustainable solvent, and explore its application in trahana fortification, a traditional Greek fermented cereal-based product. Response Surface Methodology (RSM) was applied to optimize astaxanthin extraction conditions (extraction time, liquid-to-solid (L/S) ratio, and ultrasound amplitude). Fatty acid analysis was performed with gas chromatography (GC-FID), and sensory analysis was conducted using a 7-point hedonic scale for sensory attributes. The optimal UAE conditions for astaxanthin, determined by RSM, were 228 min extraction time, a 65:1 liquid-to-solid ratio, and 41% ultrasound amplitude, predicting 83.50 μg astaxanthin/g by-product. At the optimal conditions, the experimentally obtained yield of 76.75 ± 1.17 μg astaxanthin/g by-product fell within the 95% confidence interval of the predicted value. The enriched trahanas retained nutritionally relevant levels after cooking (46.35 ± 0.60 μg astaxanthin per 60 g serving). Accelerated storage testing at 65 °C for six days was used to assess the thermal stability of astaxanthin in enriched trahanas. Based on first-order degradation kinetics and Arrhenius-based extrapolation of literature-derived activation energy values, astaxanthin retention above 80% at 25 °C was estimated to be maintained for approximately 27–51 days. Thereafter, progressive degradation is expected, with the estimated half-life ranging from 85 to 159 days. GC-FID analysis revealed favorable incorporation of bioactive lipids, including omega-3 fatty acids (EPA and DHA). Sensory evaluation demonstrated enhanced consumer acceptability, with enriched samples scoring significantly higher in appearance, aroma, and overall acceptance compared to traditional trahanas. These findings highlight UAE as an efficient and environmentally friendly strategy for recovering astaxanthin from seafood by-products and for developing functional cereal-based foods that align with sustainability. This work demonstrates the effective use of extra virgin olive oil as a green extraction solvent that also serves as a nutritional carrier, enabling the enrichment of trahanas with astaxanthin. The approach ensures both nutritional stability and consumer acceptability, providing a practical pathway for the development of sustainable, functional cereal-based foods. Full article

From the first spontaneous fermentations of early civilizations to the precision of modern biotechnology, natural starter cultures have remained at the heart of fermented food and beverage production. Composed of complex microbial communities of lactic acid bacteria, yeasts, and filamentous fungi, these starters transform raw materials into products with distinctive sensory qualities, extended shelf life, and enhanced nutritional value. Their high microbial diversity underpins both their functional resilience and their cultural significance, yet also introduces variability and safety challenges. This review traces the historical development of natural starters, surveys their global applications across cereals, legumes, dairy, vegetables, beverages, seafood, and meats, and contrasts them with commercial starter cultures designed for consistency, scalability, and safety. Within the context of organic food production, natural starters offer opportunities to align fermentation with principles of sustainability, biodiversity conservation, and minimal processing, but regulatory frameworks—currently focused largely on yeasts—pose both challenges and opportunities for broader certification. Emerging innovations, including omics-driven strain selection, synthetic biology, valorization of agro-industrial byproducts, and automation, offer new pathways to improve safety, stability, and functionality without eroding the authenticity of natural starter cultures. By bridging traditional artisanal knowledge with advanced science and sustainable practices, natural starters can play a pivotal role in shaping the next generation of organic and eco-conscious fermented products. Full article

The internal organs of sea cucumbers (SCV) are a byproduct of the seafood processing industry and hold untapped potential as a functional food. This study investigates the antioxidant capacity of SCV and its regulatory effects on the gut microbiota in a mouse model of oxidative stress induced by chronic cold exposure. The results indicate that SCV possesses a rich nutritional composition, containing various components such as calcium, phosphorus, and polysaccharides, and exhibit strong scavenging activity against three types of free radicals in vitro: DPPH, OH⁻, and O₂⁻. SCV significantly reduced MDA levels in both serum and liver, while activating the Keap1-Nrf2/HO-1 pathway, leading to a significant decrease in the expression of HSP70 and HSP90 genes and a marked increase in Nrf2 gene expression, thereby alleviating oxidative damage. Histological analysis revealed that SCV alleviated liver damage, reducing hepatocellular vacuolization and inflammatory cell infiltration. Additionally, SCV modulated the diversity of the gut microbiota, increasing the abundance of Allobaculum, Turicibacter, Bifidobacterium, and Akkermansia, while enriching the synthesis pathway of vitamin B12 (PWY-7377). This study is the first to repurpose sea cucumber viscera waste into a functional food, demonstrating its dual mechanism of alleviating oxidative stress by activating the Keap1-Nrf2/HO-1 antioxidant pathway and regulating the gut microbiota. These findings offer an innovative strategy for the high-value utilization of agricultural by-products and the development of multifunctional health-promoting products. Full article

Background: Sustainable, dual-action ergogenic strategies are underexplored; most products target a single pathway and rarely upcycle seafood sidestreams. We therefore tested an upcycled formulation combining grouper bone hydrolysate and Undaria pinnatifida extract (GU) for ergogenic and microbiota effects in mice. We tested the ergogenic and microbiota modulating effects of GU in mice versus a vehicle and a BCAA control. Methods: GU was prepared via enzymatic hydrolysis of marine by-products and administered to male ICR mice for 4 weeks. Mice were divided into five groups (n = 7/group), receiving a vehicle control, a branched-chain amino acid (BCAA) supplement, or GU at three dose levels (1X, 2X, 3X) based on human-equivalent conversion. Exercise performance was assessed via grip strength and treadmill tests. Biochemical markers of fatigue, body composition, and safety indicators were also analyzed. Gut microbiota was evaluated using 16S rRNA sequencing and constrained principal coordinates analysis (CPCoA). Results: Four weeks of GU supplementation significantly enhanced exercise performance [(treadmill time ↑ Δ = 10.2–11.7 min versus vehicle (q ≤ 0.0002), grip strength ↑ Δ = 40.4–48.5 g (q ≤ 0.05)] and lean body mass [FFM ↑ at GU-1X (Δ = +0.80%, q = 0.0123)], surpassing the commercial BCAA control. Biochemical analyses indicated reduced exercise-induced lactate accumulation [(post-exercise lactate ↓ Δ = −2.71/−2.18 mmol·L⁻¹, q = 0.0006)]. Gut microbiota profiling revealed distinct shifts in community composition in GU-treated groups, notably with an increased abundance of beneficial taxa such as Lactobacillus and Muribaculum. These alterations reflect the prebiotic activity of seaweed-derived polysaccharides, promoting a healthier gut microbial profile. Notably, GU improved metabolic markers (aspartate aminotransferase, [AST]; lactate dehydrogenase, [LDH]) without inducing toxicity. Conclusions: These findings indicate that GU functions as a dual-action supplement, coupling amino acid-mediated muscle anabolism with microbiome modulation to enhance physical performance and metabolic health. As an upcycled marine product, it presents a sustainable and effective strategy for exercise support. Future studies should include 90-day safety, mechanistic assays, and a preregistered human pilot. Full article