Search Results (620)

Garlic (Allium Sativum L.) is a source of organosulphur compounds with well-known sensorial and biological activity. Organosulphur precursors of garlic aroma are also detected in the plant leaves, but limited literature on this subject is available. This study is aimed at the characterization of the volatile profile of the floral scapes of Sulmona red garlic (aglio rosso di Sulmona) cultivated in the Abruzzo region (Italy). Floral scapes are manually removed from the plant before flowering and used as an ingredient of local gastronomy. The organosulphur volatile profile of the scapes is investigated by HS-SPME-GC-MS and compared to that provided by the clove. The GC-MS chromatogram of garlic clove, which is characterized by the predominant contribution of a few organosulphur organic compounds, is significantly more intense than that of the scapes. Almost all the organosulphur compounds contributing to the clove aroma were detected in the scape volatile profile, which, however, exhibits a more balanced contribution of major and minor organo sulphur compounds. Moreover, a significantly higher relative abundance of terpenes and aldehydes is observed in the scape aroma. The geographical/varietal origin of clove seeds (Sulmona versus Spain or France) and cultivation area interactively influence the aroma profile of Sulmona red garlic scapes. Full article

Non-alcoholic beer is increasingly popular worldwide but still faces flavor challenges compared to regular beer. These flavor-related challenges include pronounced ‘wort-like’ notes, excessive sweetness, and a lack of desirable aroma complexity. The industry is trying to improve the taste of non-alcoholic beer by trying new techniques and yeasts. A newly isolated maltose-negative brewer’s yeast (M-I) from an industrial-scale brewery collection has attracted attention due to its reduced wort-like flavor. This study aims to characterize the volatile profile of a newly isolated maltose-negative brewer’s yeast (M-I) in comparison with the well-known Saccharomycodes ludwigii. The novelty of this work lies in evaluating the aroma potential of a maltose-negative isolate newly applied in industrial brewing and its contribution to improving the flavor quality of non-alcoholic beer. An SPME-GC/MS system was used to analyze aroma compounds. According to volatile compound analysis, the M-I sample has higher amounts of esters and higher alcohol composition than the S. ludwigii beer sample. Also, it has lower amounts of Strecker aldehydes, which can give a worty off-flavor. Sensory analysis revealed that, interestingly, the control S. ludwigii sample was rated as having stronger ester notes, along with more pronounced sour and bitter characteristics, whereas the M-I sample was perceived as having a more balanced flavor, leading to a more favorable rating by the panelists. Full article

Edamame beans, rich in protein, essential amino acids, and antioxidant compounds, are promising substrates for novel plant-based beverages. This study developed and comprehensively characterized edamame-based beverage formulations with enhanced nutritional and functional attributes. Six formulations were prepared at edamame–water ratios of 1:3 or 1:6, incorporating either coconut water or coconut milk. Physicochemical analyses included particle size distribution, viscosity, amino acid and mineral profiles, antioxidant activity, volatile compounds, and storage stability. Nutritional analysis revealed that the ECM (1:3) formulation exhibited the highest protein content (3.68 g/100 g), while all formulations delivered essential minerals, with calcium levels ranging from 19.25% to 27.64% of total mineral content. ECW formulations were particularly rich in potassium, calcium, and phosphorus, whereas the pure edamame-based beverage had higher concentrations of sulfur and magnesium. The E (1:3) formulation demonstrated the highest total amino acid concentration (24.85 mg/mL), with glutamic and aspartic acids predominating compounds known to contribute to umami taste and buffering capacity. Higher edamame concentrations also resulted in significantly greater total phenolic (16.25 mg GAE/100 mL) and flavonoid content (6.42 mg QE/100 mL), which correlated with improved DPPH radical scavenging activity. The addition of coconut milk significantly reduced particle size, improved emulsion stability, and increased viscosity, while also masking undesirable volatile compounds such as hexanal, commonly associated with the beany aroma of legumes. These findings highlight the synergistic potential of blending edamame with coconut-based ingredients to produce nutrient-dense, sensorially acceptable, and shelf-stable plant-based beverages. Full article

The increasing demand for red wines, supported by their complex sensory features and rich biochemical composition, has encouraged cultivation in non-traditional viticultural regions. This study investigates the antioxidant potential and volatile composition of three red grape cultivars (Feteasca neagra, Merlot, and Pinot noir) cultivated in the Tarnave Vineyard, Romania, a region historically dedicated to white wines but now increasingly favorable to red varieties due to climate change. Antioxidant capacity, assessed via DPPH, Trolox equivalent antioxidant capacity (TEAC), and Ferric reducing antioxidant power (FRAP) assays, identified Feteasca neagra as the most potent (IC₅₀: 115.32 µg/mL; FRAP: 13.45 mmol TE/L). Gas chromatography–mass spectrometry (GC–MS) profiling identified 61 volatile compounds, with Pinot noir showing the highest concentration (99,018.57 µg/L). Multivariate analysis (ANOVA, PCA) confirmed significant varietal differences and terroir-specific influences on wine composition. Pinot noir was characterized by high levels of higher alcohols, esters, and lactones, yielding a floral and fruity aroma, while Feteasca neagra exhibited intense color, high flavonoid content (notably malvidin-3-glucoside), and vanilla–herbal notes. Merlot presented a balanced sensory profile with significant phenolic acid content. These findings highlight the chemical and sensory potential of the Tarnave Vineyard for premium red wine production. Full article

Eryngium foetidum L. belongs to the Apiaceae family and is a perennial herb. The entire plant is rich in essential oils, which have a distinctive aroma similar to cilantro. This plant exhibits significant biological activity and possesses characteristics such as disease resistance and antimicrobial properties, showing great potential in medical and food applications. Additionally, its essential oil has substantial commercial value. Mitochondria play a crucial role as organelles within plant cells; however, the mitochondrial genome of E. foetidum remains underexplored. To fill this research gap, we conducted sequencing and assembly of the mitochondrial genome of E. foetidum, aiming to uncover its genetic mechanisms and evolutionary trajectories. Our investigation reveals that the mitochondrial genome of E. foetidum is a circular structure, similar to that of other species, with a length of 241,660 bp and a GC content of 45.35%, which is within the range observed in other organisms. This genome encodes 59 genes, comprising 37 protein-coding sequences, 18 tRNA genes, and 4 rRNA genes. Comparative analysis highlighted 16 homologous regions between the mitochondrial and chloroplast genomes, with the longest segment spanning 992 bp. By analyzing 37 protein-coding genes (PCGs), we identified 479 potential RNA editing sites, which induce the formation of stop codons in the nad3 and atp6 genes, as well as start codons in the ccmFC, atp8, nad4L, cox2, cox1, and nad7 genes. Meanwhile, the genome shows a preference for A/T bases and A/T-ending codons, with 32 codons having a relative synonymous codon usage (RSCU) value greater than 1. The codon usage bias is relatively weak and mainly influenced by natural selection. Most PCGs are under purifying selection (Ka/Ks < 1), while only a few genes, such as rps7 and matR, may be under positive selection. Phylogenetic analysis of mitochondrial PCGs from 21 species showed E. foetidum at the basal node of Apiaceae, consistent with the latest APG angiosperm classification and chloroplast genome-based phylogenetic relationships. In summary, our comprehensive characterization of the E. foetidum mitochondrial genome not only provides novel insights into its evolutionary history and genetic regulation but also establishes a critical genomic resource for future molecular breeding efforts targeting mitochondrial-associated traits in this economically important species. Full article

Recent climatic extremes, characterized by hot and dry summers, threaten grape yield and berry composition, increasing the need for sustainable mitigation strategies. In this study, a fruit-zone cooling system was tested to reduce sunburn damage and improve vine performance. The system integrates proximal sensors and an automatic misting actuator, triggered when the air temperature exceeds 35 °C. Over two seasons (2022–2023), trials were conducted on Pignoletto vines subjected to four treatments: control (C), misted without defoliation (C + FOG), defoliated (DEF), and defoliated plus misted (DEF + FOG). The effects on microclimate, yield, berry sunburn, and berry composition were evaluated. Misting consistently reduced both air and berry temperature. Treated vines showed increased yield, mainly due to reduced sunburn and higher cluster weight. Although no clear differences in technological maturity were observed, misted vines tended to retain higher acidity under extreme heat. Flavonol synthesis was unaffected by cooling but stimulated by increased light exposure, being higher in defoliated vines. Volatile compounds analysis highlighted misting’s moderating effect on oxidative stress and aroma profile shifts, particularly during the hotter season. Overall, the cooling system proved effective in mitigating summer stress, offering a promising tool for preserving yield and berry composition in white cultivars under climate change. Full article

The substrates of kombucha typically consist of tea and sugar. In this study, the effect of initial sugar concentration on volatile compound and sensory characteristics of raw Pu-erh tea (RAPT) kombucha was investigated. Compared to tea free (S1) and sugar free (S2) samples, the sugared tea (39 g/L sucrose in S3 and 78 g/L sucrose in S4) revealed better sensory quality and higher liking scores after the fermentation process. Hence, high-throughput sequencing analysis was performed to determine the variation in microbial composition between S3 and S4. The result showed that S4 exhibited higher abundances of Komagataeibacter and Brettanomyces as compared to S3. In addition, S4 presented the most favorable sensory qualities characterized by higher intensities of fruity, alcoholic, and fatty aromas, and the highest overall liking score. The metagenomic and metabolomic analysis was employed to further explore the metabolic pathways of RAPT kombucha under the optimal sugar concentration. The metagenomic and metabolomic analyses revealed that the pathways related to carbohydrate and amino acid metabolism were highly active under optimal sugar content, with compounds including glucose 6-phosphate, pyruvate and glutamate suggested to be important metabolites in regulating the sensory quality of the kombucha beverage. This paper provides a scientific basis for optimizing sugar addition in kombucha production. Full article

In this study, we systematically characterize the volatile and non-volatile flavor profiles of coffee beans. Sensory evaluation demonstrated unique aromatic profiles for each coffee, with Colombia excelling in chocolate and nutty notes, while Bench Maji exhibited pronounced fruity characteristics. Yirgacheffe had a prominent roasted aroma, and Baoshan stood out for its stronger woody and caramel notes. The analysis employed solvent-assisted flavor evaporation (SAFE), gas chromatography–mass spectrometry/olfactometry (GC-MS/O), and high-performance liquid chromatography (HPLC). A total of 85 aroma compounds were identified, with furans, ketones, and pyrazines being the predominant contributors to roasted, nutty, and caramel aromas. Key aroma-active compounds, including furfural, guaiacol, and furaneol, exhibited the highest flavor dilution (FD) factors (up to 2187) and odor activity values, highlighting their pivotal roles in coffee aroma, with 4-vinyl-2-methoxyphenol (OAV = 761 in GL) and furaneol (OAV = 250 in BS) being particularly influential. Recombination and omission experiments validated the significance of these compounds. Non-volatile analysis revealed distinct differences in organic acids and chlorogenic acid content, with Colombia samples showing higher quinic acid levels, likely due to roasting-induced degradation. These findings provide a theoretical basis for understanding coffee flavor diversity and offer insights for quality assessment and origin identification. Full article

This study explores the chemical and sensory differentiation of Greek white wines produced from five indigenous grape varieties—Savvatiano, Vidiano, Moschofilero, Assyrtiko, and Malagouzia—across diverse terroirs in Greece. A targeted analytical approach was employed to quantify 12 key volatile aroma compounds derived primarily from amino acid metabolism and lipid degradation, using GC-MS and GC-FID. The selected volatiles, including isoamyl alcohol, phenylethyl alcohol, tyrosol, and hexanoic acid ethyl ester, were chosen for their sensory relevance and their biosynthetic linkage to nitrogenous precursors. Principal Component Analysis (PCA) of wines from the 2019 and 2020 vintages revealed clear varietal clustering, under standardized winemaking conditions. Malagouzia wines were characterized by rich and diverse volatile profiles, particularly long-chain fatty acids and esters, while Vidiano exhibited a consistently restrained aromatic expression. Sensory analysis using sorting and ultra-flash profiling confirmed the chemical clustering, with Moschofilero, Vidiano and Malagouzia wines forming distinct sensory groups. The findings demonstrate that key amino acid-derived volatiles can serve as biochemical markers of varietal typicity and support the use of volatile profiling as a tool for terroir-driven wine classification and quality assessment in Greek white wines. Full article

Imperial chrysanthemum teas ‘Wuyuan Huangju’ (WYHJ) and ‘Jinsi Huangju’ (JSHJ), dried from the flowers of Chrysanthemum morifolium cv. Huangju, are traditional and popular herbal teas in China. However, their metabolite profiles and bioactivities remain unclear. In this study, we aimed to comprehensively elucidate the non-volatile and volatile metabolites of these two imperial chrysanthemum teas and assess their antioxidant activities and inhibitory effects on hyperglycemia and inflammation enzymes. Thus, we employed a widely targeted metabolomics approach based on UPLC-ESI-MS/MS and GC-MS/MS to characterize metabolite profiles of the two teas. In total, 1971 non-volatile and 1039 volatile metabolites were explored, and among these, 744 differential non-volatiles (classified into 11 categories) and 517 differential volatiles (classified into 12 categories) were identified. Further, 474 differential non-volatiles were upregulated in WYHJ, particularly flavonoids, terpenoids, and phenolic acids. In contrast, JSHJ exhibited a greater number of upregulated differential volatiles compared to WYHJ, contributing primarily to its sweet, fruity, and floral aroma. The results of scavenging activities towards DPPH·, ABTS·⁺, OH·⁻, and reducing power demonstrated that both imperial chrysanthemum teas, especially WYHJ, displayed high antioxidant capacity. We also noted that WYHJ exhibited stronger α-amylase, α-glucosidase, xanthine oxidase, and lipoxygenase inhibitory effects owing to its high active substance content. Therefore, this study provides insights into the metabolites of Chinese traditional medicinal herbal teas and highlights strategies for the comprehensive development and utilization of these traditional plant resources. Full article

Zengcheng (ZC), a superior cultivar of Mesona chinensis Benth, is distinguished by its unique sensory attributes and exceptional phytochemical quality, rendering it the cultivar of choice for commercial production. In this investigation, we employed comprehensive targeted metabolomics to systematically delineate the volatile metabolome of ZC in comparison to three relevant counterparts grown under uniform field conditions and harvested at the same developmental stage. Our primary objectives were to (i) quantitatively characterize the metabolomic divergence between ZC and the comparative cultivars, and (ii) elucidate the molecular basis underlying ZC’s characteristic flavor signature. Through high-throughput gas chromatography–mass spectrometry (GC-MS) analysis, a total of 1767 volatile metabolites were confidently annotated, with terpenoids and esters identified as the predominant chemical classes. Notably, ZC exhibited significantly elevated levels of terpenoids, esters, and aldehydes, which collectively conferred an intensified green, sweet, herbal, and fruity aroma. Key discriminatory metabolites included geranyl formate and geranic acid (imparting a pronounced green note), which were identified as pivotal determinants of ZC’s unique flavor profile. These findings provide mechanistic insights into the biochemical pathways governing flavor development in M. chinensis Benth and establish a robust foundation for precision-breeding strategies aimed at enhancing sensory quality and developing elite cultivars. Full article

This study investigates the aroma differences among various peach and nectarine varieties by sensory evaluation, electronic nose (E-nose) analysis, and metabolomics. Peach is a significant fruit crop in China, and identifying unique fragrances is essential for germplasm selection and cultivar improvement. Six peach and nectarine varieties were collected from the National Peach Germplasm Repository in Nanjing, China. Sensory evaluation revealed significant differences in aroma and taste, with ”Zi Jin Hong 3” and “Bai Mi Pan Tao” showing high scores for aroma, sweetness, and overall sensory quality, while “Tachibanawase” had the lowest overall impression score. E-nose analysis showed distinct response values among varieties, with sensors W1S, W1W, and W5S exhibiting the highest sensitivity. GC-MS identified 446 metabolites, including esters and terpenes. PCA and OPLS-DA differentiated metabolite profiles among varieties, revealing significant differences in metabolite expression. The integration of these techniques provides a comprehensive understanding of aroma differences, highlighting the potential for identifying unique germplasms for breeding high-quality cultivars with charming flavor, and offering a theoretical foundation for raw material selection and process optimization in the deep-processing industry of peach fruits in future research. Full article

Fu tea is a unique microbially fermented tea from China, and has two types. The primary distinction between these two types—Fu brick tea (FBT) and Fu loose tea (FLT)—is that FBT is compressed into bricks, whereas FLT is maintained as loose leaves. To investigate the differences in the chemical composition and sensory characteristics between the two types of Fu tea, this study utilized samples produced from the same batch of raw dark tea material to ensure comparability. Multiple analytical approaches were applied, including main active component analysis, sensory flavor evaluation, metabolomics, and differential characteristic component analysis. These methods were employed to comprehensively compare and characterize the two tea types. The results showed that compared to FBT, FLT exhibited a longer-lasting fungal flower aroma and a mellower taste. Furthermore, the quantity of Eurotium cristatum in FLT was 56.7% higher than that in FBT, indicating a significant difference. Untargeted ultrahigh-performance liquid chromatography–mass spectrometry was used to screen metabolites in Fu tea samples, and after multivariate statistical analysis, 12 differential metabolites were finally identified, including phenolic acids and their derivatives, coumarins and their derivatives, phenylpropanoids, and flavonoids and their glycosides. Subsequently, a targeted UHPLC-QQQ-MS/MS-based method was established and validated for the main differential metabolites, phenolic acids and catechins. The results indicated that gallic acid, catechin, and epicatechin can serve as characteristic markers for distinguishing between FBT and FLT. Notably, the content of gallic acid in FLT was 168.6% higher than that in FBT. These findings elucidate the impact of the pressing process on Fu tea, provide guidance for discriminating between FBT and FLT, and are significant for quality control in the industrial production of Fu tea. Full article

Unveiling how vinification technique shapes wine identity, this study provides a comparative insight into the chemical and sensory profiles of Babica wines produced using traditional, enzyme-assisted, and thermovinification approaches. The kinetics of color parameters changes and the phenolic extraction were monitored during the first five days of maceration. Individual phenolics and volatiles were determined using high-performance liquid and gas chromatography, respectively, while the overall sensory quality of the wines was evaluated by panelists. Significant differences in the extraction kinetics of compounds of interest were observed among treatments, particularly during the first days of maceration. By the end of the study, the thermovinified wine exhibited the highest color intensity (3.80), redness (52.5%), and approximately two-fold higher concentrations of total phenolics (2205 mg gallic acid equivalents/L) compared to the other two treatments. It contained the lowest concentration of tannins (100 mg catechin equivalents/L), anthocyanins (117 mg of malvidin-3-glucoside equivalents/L), and esters and showed the highest levels of volatile alcohols. It was also characterized by the most intense blueberry aroma and astringency in sensory analysis. The applied maceration technique affects the chemical and sensory profiles of Babica wines, with thermovinification favoring young and highly colored wines, whereas conventional vinification enhances the wine’s aging potential. Full article

The ‘Annurca’ apple, an EU Protected Geographical Indication product, undergoes a mandatory post-harvest reddening in the ‘melaio’. This traditional practice enhances color and aroma but initiates detrimental textural degradation, creating a paradox where key quality attributes develop in conflict. This study aimed to characterize the sensory evolution of ‘Annurca’ apples during extended cold storage and its impact on consumer preference. A cohort of 551 untrained consumers evaluated the sensory profile at seven time points over a 221-day cold storage period. Multivariate data analyses were employed to identify preference drivers and define consumer segments. Consumer overall liking and market acceptability followed a significant non-linear, U-shaped trajectory, declining from an initial high (89.4% acceptability) to a minimum at day 159 (46.6% acceptability), before partially recovering. This trend inversely correlated with a peak in perceived mealiness, while hardness and crunchiness remained stable. Juiciness and aroma intensity were consistently identified as powerful positive liking drivers, whereas mealiness was the most significant and consistent negative driver. Sweetness’s importance as a preference driver significantly increased over storage time. Cluster analysis on highly rated samples revealed three distinct consumer preference profiles, challenging the traditional notion of a single ideal ‘Annurca’ apple. This study deconstructs the ‘melaio’ paradox, demonstrating that sensory evolution is a dynamic process defined by a trade-off between flavor development and textural decay. The findings provide a data-driven framework for optimizing the commercial strategy for this unique PGI cultivar, suggesting the need to mitigate mealiness and develop targeted marketing strategies for distinct consumer segments. Full article