Search Results (119)

Biflavonoids, or flavonoid dimers, are characteristic phytochemicals of ginkgo associated with various biological activities, yet they remain far less studied than monomeric flavonoids. For their effective industrial application, optimization of extraction conditions is essential. This study investigated the effect of ethanol–water ratio (0, 10, 30, 50, 70, and 96% ethanol) on the extraction efficiency of major ginkgo biflavonoids (amentoflavone, bilobetin, ginkgetin, isoginkgetin, and sciadopitysin). Three ginkgo tissue types, green leaves, yellow leaves, and sarcotesta, previously reported to accumulate biflavonoids, were analyzed. Biflavonoids were quantified by HPLC-DAD, and total polyphenol content and antioxidant activity were also determined. Biflavonoids were most abundant in yellow leaves, with sciadopitysin identified as the dominant compound. No biflavonoids were detected in water or 10% ethanol extracts, while 30% ethanol extracts contained detectable biflavonoids only in yellow leaves at low concentrations. For most biflavonoids, the highest concentrations were obtained using 70% and 96% ethanol. Considering comparable extraction efficiency and lower toxicity, 70% ethanol was identified as the most suitable solvent. These findings highlight the importance of tissue type and solvent composition for efficient biflavonoid extraction from ginkgo. Full article

A semi-empirical lumped parameter model for the extraction process of traditional Chinese medicine based on thermal equilibrium was established in this work. In this model, the effect of heat dissipation was considered. Differential equations was solved using numerical methods. Key model parameters such as the overall heat transfer coefficient and heat dissipation coefficient were obtained by fitting measured data. In the laboratory scale, Ginkgo biloba leaves were used as the liquid-solid extraction object to systematically investigate the effects of liquid-to-solid ratio, extraction temperature, solvent ratio, and slice particle size on the temperature changes during the extraction process. The average determination coefficient (R²) of the model fitting was 0.9955, and the R² value for the prediction group was 0.9950. In the laboratory scale, extraction experiments of Xiaochaihu Decoction were conducted, and the performance of the model was verified. Furthermore, the model was applied to the mixed decoction process of five medicinal materials (Bupleurum, Glycyrrhiza, Scutellaria, Codonopsis, and Jujube) in industrial-scale for the production of Xiaochaihu capsules. The temperature change curves of three extraction tanks were all fitting well. The fitting results indicated abnormal heat transfer performance in Tank No. 1, providing a prompt for equipment maintenance and process optimization for the enterprise. A feasible method for temperature calculation and abnormal identification in the industrial process of traditional Chinese medicine extraction was provided in this work. Full article

Ginkgo biloba L. plays an important role in biodiversity conservation. Accurate identification of Ginkgo in forest environments remains challenging due to its visual similarity to other broad-leaved species during the green-leaf period and to species with yellow foliage during autumn. In this study, we propose a novel two-stage segment-then-classify (STC) strategy to improve the accuracy of Ginkgo identification from unmanned aerial vehicle (UAV) imagery. First, the Segment Anything Model (SAM) was fine-tuned for canopy segmentation across the green-leaf stage and the yellow-leaf stage. A post-processing pipeline was developed to optimize mask quality, ensuring independent and complete tree crown segmentation. Subsequently, a ResNet-101-based classification model was trained to distinguish Ginkgo from other tree species. The experimental results showed that the STC strategy achieved significant improvements compared to the YOLOv8 model. In the yellow-leaf stage, it reached an F1-score of 92.96%, improving by 24.50 percentage points over YOLOv8. In the more challenging green-leaf stage, the F1-score improved by 31.27 percentage points, surpassing YOLOv8’s best performance in the yellow-leaf stage. These findings demonstrate that the STC framework provides a reliable solution for high-precision identification of Ginkgo in forest ecosystems, offering valuable support for biodiversity monitoring and forest management. Full article

Ginko (Ginkgo biloba L.) is a widely distributed ornamental tree that produces large quantities of leaves annually, turning golden yellow in autumn due to chlorophyll degradation and carotenoid retention. While green ginkgo leaves and standardized extracts have been extensively studied, senescent and naturally fallen leaves remain only scarcely investigated, despite representing a substantial biomass resource. In this study, we analyzed yellow ginkgo leaves collected directly from trees and those naturally shed at four time points during autumn. We determined pigment composition, total polyphenols, flavonoids, phenolic acids, and the concentrations of five major biflavonoids. Chlorophylls decreased progressively in tree-collected leaves, whereas carotenoid levels remained stable or slightly elevated. Polyphenolic compounds were more abundant in fallen leaves. Biflavonoid profiling revealed the presence of amentoflavone, bilobetin, ginkgetin, isoginkgetin, and sciadopitysin, with sciadopitysin as the most abundant. Total biflavonoid content reached up to 8 mg/g dw, with higher levels in fallen leaves compared to those collected from the tree. These findings highlight yellow ginkgo leaves, particularly fallen ones, as a sustainable and non-invasive source of pharmacologically relevant biflavonoids. However, further research is needed to optimize eco-friendly extraction strategies and to evaluate safety aspects. Full article

Background: Gallic acid (GA) is a dietary polyphenol widely found in walnuts, tea leaves, and grapes, and it is recognized for its potent antioxidant and anti-inflammatory properties. Chronic sleep deprivation (CSD) is known to disrupt redox balance, promote neuroinflammation, and impair cognition, while effective nutritional strategies to mitigate these effects remain scarce. This study was designed to evaluate the protective potential of GA against CSD-induced cognitive deficits in mice and to elucidate the underlying mechanisms. Methods: Seventy-two male ICR mice were randomly allocated to six groups, including control, CSD model, Ginkgo biloba extract, and GA at three doses (50, 100, and 200 mg/kg). After 28 days of treatment, cognitive performance was assessed using the open field test (OFT), novel object recognition (NOR), step-through passive avoidance (ST), and Morris water maze (MWM). Redox status and inflammatory mediators were determined by ELISA, while the hippocampal expression of proteins related to antioxidant defense and NF-κB signaling was analyzed by Western blotting. Results: GA supplementation improved exploratory activity, recognition memory, and spatial learning in the CSD mice. Biochemical evaluation revealed that total antioxidant capacity (T-AOC) and superoxide dismutase (SOD) activity were restored, while malondialdehyde (MDA) levels, an indicator of lipid peroxidation, were reduced. These changes were accompanied by decreased circulating concentrations of interleukin-1β (IL-1β), interleukin-6 (IL-6), and tumor necrosis factor-α (TNF-α). At the molecular level, GA enhanced the expression of Nrf2, HO-1, and NQO1, while inhibiting p-p65, iNOS, and COX2 in the hippocampus. Conclusions: These findings demonstrate that GA alleviates CSD-induced cognitive deficits through the activation of the Nrf2/HO-1 antioxidant pathway and inhibition of NF-κB–mediated inflammatory responses. Thus, GA may represent a promising nutraceutical candidate for maintaining cognitive health under chronic sleep loss. Full article

Carbon-based metal-free catalysts, particularly those such as biomass-derived mesoporous activated carbon (AC) nanostructures, hold great promises for cost-effective and sustainable electrocatalysis for enhancing hydrogen evolution reaction (HER) performance in green energy technology. Neem and ginkgo leaves are rich in bioactive compounds and self-doping heteroatoms with naturally porous structures and act as a low-cost, sustainable biomass precursors for high-performance HER catalysts. In this study, mesoporous AC nanoflakes and nanosponges were synthesized using biomass precursors of neem and ginkgo leaves through a KOH activation process. Notably, AC nanosponges derived from ginkgo leaves exhibited outstanding physicochemical characteristics, including a sponge-like porous morphology with a large specific surface area of 1025 m²/g. For electrochemical evaluation in 0.5 M H₂SO₄, the G-AC sample revealed superior electrocatalytic HER performance, with a remarkably low overpotential of 26 mV at −10 mA/cm², a small Tafel slope of 24 mV/dec, and long-term durability over 30 h. These results depict biomass-derived mesoporous AC nanosponges to hold substantial potential for highly efficient hydrogen production, contributing significantly to the advancement of eco-friendly energy solutions. Full article

B-box (BBX) transcription factors, which are specific to the plant kingdom, play a crucial role in regulating light-dependent growth, development, secondary metabolite biosynthesis, and the response to biotic and abiotic stresses. Despite their significance, there has been a lack of systematic investigation into the BBX gene family in Ginkgo biloba. In the present study, we identified nine BBX genes within the G. biloba reference genome, distributed across seven chromosomes, and classified them into four groups based on their phylogenetic relationships with the BBX gene families of Arabidopsis thaliana. Our analysis of gene structure, conserved domains, and motifs suggests that GbBBXs exhibit a high degree of conservation throughout evolutionary history. Additionally, synteny analysis revealed that dispersed duplication events have contributed to the expansion of the BBX gene family in G. biloba. An examination of cis-regulatory elements indicated that numerous GbBBX genes contain motifs associated with light, hormones, and stress, suggesting their potential roles in responding to these signals and environmental adaptation. Expression profiles obtained from RNA-Seq data and quantitative Real-Time PCR (qRT-PCR) analyses of GbBBX genes across various organs, hormone treatments, and leaves with differing flavonoid content, as well as during both short-term and long-term water stress, demonstrated their potential roles in flavonoid regulation and responses to hormones and water stress. Subcellular localization studies indicated that the proteins GbBBX5, GbBBX7, GbBBX8, and GbBBX9 are localized within the nucleus. This study is the first thorough analysis of the BBX gene family in G. biloba, providing a valuable foundation for further understanding their evolutionary context and functional roles in flavonoid regulation and responses to water stress. Full article

Ginkgo biloba leaf flavonoids, while demonstrating antioxidant potential, remain underexplored as natural stabilizers for frying oils under thermo-oxidative stress. This study assessed Ginkgo biloba leaf flavonoids efficacy against synthetic tertiary-butylhydroquinone (0.02%). Ginkgo biloba leaf flavonoids were extracted via optimized ultrasonic-assisted methods (15 mL/g solvent, 80% ethanol, 45 °C, 120 s). Frying stability in flaxseed and soybean oils over 6 days (24 cycles/day) was evaluated using multi-indicator kinetic analysis. Ginkgo biloba leaf flavonoids significantly outperformed tertiary-butylhydroquinone in reducing oxidation markers after 6 days. In flaxseed oil, Ginkgo biloba leaf flavonoids reduced acid value (18.4%), peroxide value (33.79%), and polar compounds (52.03%); reductions in soybean oil reached 61.34% for polar compounds. Ginkgo biloba leaf flavonoids better preserved γ-tocopherol in flaxseed oil (increased 2.09% retention) and key tocopherols in soybean oil. Critically, it mitigated unsaturated fatty acid losses (flaxseed C18:3: 2.72% higher; soybean C18:2: 4.4% higher) and limited saturated fatty acid increases. Optimized Ginkgo biloba leaf flavonoid extraction facilitates its application as a promising natural candidate for high-temperature frying, where its matrix-specific stabilization effect shows potential in commercial functional oil formulations. Full article

The chicken chorioallantoic membrane (CAM) model is an embryonic blood capillary system considered a suitable “in vivo” model for studying the irritation effect of plant extracts on the vascular system, including impacts on hemostasis, hyperemia, hemorrhage, and coagulation. The main aim of the present work was to investigate the irritation effects of different concentrated alcohol extracts of Ginkgo biloba L. (GBE) leaves on the blood vessels of the CAM model during early embryogenesis, evaluated using the Luepke scoring system. The antioxidant properties of GBE were assessed using DPPH radical scavenging and the FRAP method, alongside HPLC-DAD analysis to confirm the presence of major therapeutically relevant metabolites, revealing a strong therapeutic potential of the extract. On embryonic day 9, different concentrations of GBE as well as the controls (saline solution and 30% ethanol) were applied to the CAM surface. Vascular changes were observed immediately after application, with vasoconstriction leading to the temporary “disappearance” of blood vessels. At 30 s post-application, all GBE concentrations and ethanol induced hyperemia and mild hemorrhage, which gradually diminished over time. No changes were observed with saline application. The extent of morphometric changes in the vessels was also influenced by the concentration of GBE used. Concentrations of 20% and 30% GBE induced vasoconstriction. Lower concentrations of GBE induced vasodilation, with maximum values recorded after 240 s for 1% and 15% GBE. The results of this study may help to better characterize the vascular effects of natural Ginkgo biloba under in vivo conditions and promote greater interest in the use of alternative animal models in pharmacological and biomedical research. Full article

Background: The PDX2 gene serves as a critical catalytic component in vitamin B6 (VB6) biosynthesis pathways and plays pivotal regulatory roles in plant growth. Methods: To investigate the metabolic regulation of PDX2 (GbPDX2) from Ginkgo biloba in VB6 biosynthesis during kernel development, we successfully cloned this gene and conducted systematic expression profiling through qRT-PCR across multiple tissues and developmental stages. Results: Bioinformatic characterization revealed that GbPDX2 contains a 765-bp coding sequence encoding a 254-amino acid polypeptide. The encoded protein displays typical hydrophilic properties (average hydrophobicity index: −0.32) and was predicted to be an unstable cytosolic protein (instability index: 45.7) lacking signal peptides or transmembrane domains with cytoplasmic localization. Phylogenetic analysis demonstrated that GbPDX2’s closest evolutionary relationship was with its ortholog in Picea sitchensis, which had an amino acid sequence similarity of 83.7% with spruce PsPDX2. Tissue-specific expression analysis revealed a gradient expression profile of Kernel > Exocarp > Leaves > Stems > Roots. The expression level in kernels was significantly higher than that in other tissues (19.7 times that in roots, 8.3 times that in stems, and 5.9 times that in leaves; p < 0.01), with peak transcript levels observed in mature kernels. HPLC quantification established a strong positive correlation between GbPDX2 expression dynamics and VB6 accumulation patterns during kernel maturation (r = 0.92, p < 0.01), and the peak period of VB6 reached 288.9 ± 7.1 μg/g. Conclusions: Our findings provide the first experimental evidence that GbPDX2 spatiotemporally regulates VB6 biosynthesis in ginkgo kernels, offering novel insights into the evolutionary adaptation of vitamin metabolism in gymnosperms. Full article

SQUAMOSA promoter-binding protein-like (SPL) transcription factors specific to plants are vital for regulating growth, development, secondary metabolite biosynthesis, and responses to both biotic and abiotic stresses. Despite their importance, no systematic investigations or identifications of the SPL gene family in Ginkgo biloba have been conducted. In this study, we identified 13 SPL genes within the Ginkgo biloba reference genome, spanning seven chromosomes, and categorized these genes into six groups based on their phylogenetic relationships with Arabidopsis thaliana SPL gene families. Our analysis of gene structure, conserved domains, motifs, and miR156 target predictions indicates that GbSPLs are highly conserved across evolutionary timelines. Furthermore, synteny analysis highlighted that dispersed duplication events have expanded the SPL gene family in Ginkgo biloba. Examination of the cis-regulatory elements revealed that many GbSPL genes possess motifs associated with light, hormones, and stress, implying their involvement in flavonoid biosynthesis and adaptation to environmental conditions. RNA-Seq and qRT-PCR expression profiles of GbSPL genes across various tissues and low- and high-flavonoid leaves and during both short-term and long-term water stress illustrated their roles in flavonoid biosynthesis and responses to water stress. Subcellular localization experiments showed that GbSPL2 and GbSPL11 proteins are situated within the nucleus. Our research offers the first systematic characterization of the SPL gene family in Ginkgo biloba, establishing a valuable foundation for understanding their evolutionary background and functional roles in flavonoid biosynthesis and water stress response. Full article

With the rapid development of precision agriculture spraying technology, the evaluation and detection of deposition effects have gradually become research hotspots. Rhodamine-B is often used for the quantitative elution detection of droplet deposition due to its fluorescent properties. In contrast, the method of detecting droplet deposition using water-sensitive paper (WSP) is simple to operate. However, it often faces issues with measurement accuracy due to factors such as irregular droplet diffusion and the excessive hydrophilicity of the sampler material. Based on this, the study proposes a method for correcting WSP deposition assays by using the quantitative elution of chemical colorants as a baseline reference. Experiments were conducted using a DJI T30 unmanned aerial spraying system (UASS) as the spray carrier, with four types of samplers—Ginkgo biloba leaves (GBL), Malus spectabilis leaves (MS), polyvinyl chloride (PVC) cards, and WSP—fixed at nine different angles. The deposition amounts of five concentrations of Rhodamine-B stain sprayed on the samplers were then compared. The results indicate that the correction factor can be influenced by various factors, including the environment, the type of sampler, the concentration of the sprayed colorant, and the angle of the sampler. Deposition correction coefficients for WSP with different samplers were determined to be in the ranges of 1.507 to 1.547 (WSP–GBL), 1.471 to 1.478 (WSP–MS), and 1.312 to 1.391 (WSP–PVC), respectively. The study confirmed the feasibility of the proposed fluorescence-corrected aerial spray droplet deposition method, which retains the advantages of two existing typical deposition determination methods. Additionally, pre-tests should be tailored to experimental conditions, and the choice of colorant concentration should be carefully considered. Full article

Ginkgo biloba has unique leaf color and high ornamental value. Here, we conducted seasonal dynamic analyses of leaf color, morphology, physiology, and biochemistry in the new variety Huangjinwanliang (HJWL), using the golden-leaf ginkgo Xiajin (XJ) as a control, and performed genotyping-by-sequencing (GBS) to explore genetic differences. The results showed that both varieties were golden-yellow leaves in spring and autumn, transitioning to green in summer. The total chlorophyll and carotenoid contents in HJWL (1.45~4.84 mg/g and 0.09~0.39 mg/g) were significantly higher than those in XJ (1.42~3.93 mg/g and 0.08~0.34 mg/g). HJWL exhibited a higher number of chloroplasts, with visible single lamellar thylakoids, whereas XJ had fewer chloroplasts. Chloroplast fluorescence and photosynthetic parameters indicated that HJWL possesses a greater capacity for light acclimatization. The total flavonoids and wax content of HJWL (16.67 ± 0.33 mg/g and 18.22 ± 0.15 mg/g) were significantly higher than those of XJ (14.15 ± 0.31 mg/g and 30.19 ± 0.18 mg/g). GBS analysis revealed distinct genome-wide molecular bases between HJWL and XJ. These findings demonstrate that HJWL’s leaf color and extended ornamental period make it a valuable landscape tree species for spring and autumn, suitable for promotion as an ornamental tree. Full article

Airborne particulate matter (PM) is one of the most urgent urban environment problems in the world today. The urban ecosystem has been identified as a potentially promising solution to reduce the airborne PM based on the ability of plants to retain PM. Numerous studies have been conducted to explore the process and mechanism of atmospheric PM retention by plant leaves in the past. In this study, in order to better summarize previous research, particularly the impact of leaf traits on PM retention, and to provide guidance for the selection of tree species for nature-based urban PM solutions, a systematic review was carried out using the method recommended in the PRISMA, and a total of 49 articles were selected. It was found that: 1. Asian countries contribute the majority of the proportion (32, 65%). Following behind are European countries (13, 26.5%). The American countries contribute two cases. 2. Among all the tree species, Ginkgo biloba (16), Euonymus japonicus (11), Magnolia denudate (9), Styphnolobium japonicum (9), Magnolia grandiflora (8), and Prunus cerasifera (8) emerged as hot species in research. 3. Leaf area and shape emerged as the two most frequently discussed macro-indicators, while roughness, hairiness, and stomatal characteristics were the top three micro-indicators explored. 4. Roughness and stomata, respectively, play crucial roles in capturing larger PM particles and retaining fine and ultrafine PM through their recessed structures. Trichomes decrease the likelihood of particle resuspension and boosts the efficiency of PM retention. 5. Leaves with high rigidity and complex multi-faceted leaf shapes are typically presumed to exhibit higher PM retention efficiency for higher edge effects and increased interleaf turbulence. Furthermore, with rigidity and edge effects ensured, a larger leaf area is beneficial for retaining PM. Full article

Leaf functional traits are an important part of plant adaptive strategies and respond differently to different environments, but our understanding of how plants adapt to highly complex urban environments through coordinated changes in leaf functional traits is limited. In order to deeply explore the effects of different urban environments on the leaf functional traits of landscape plants, this study focused on ten common landscape plants in Nanjing, specifically, Euonymus japonicus, Pittosporum tobira, Loropetalum chinense, Photinia × fraseri, Acer palmatum, Euonymus japonicus ‘Aurea-marginatus’, Platanus acerifolia, Camphora officinarum, Ginkgo biloba, and Lagerstroemia indica. The study employed one-way analysis of variance (ANOVA), two-way ANOVA, principal component analysis (PCA), and membership function comprehensive evaluation to explore the responses of green space plants to the environments of urban park green spaces (PAR), urban community green spaces (NL), and urban road green spaces (CR) and to analyze the impact of the trade-off strategies of plants in different green space environments based on leaf functional traits. The results showed that plant leaf functional traits and their adaptive strategies varied in different urban environments in Nanjing. The contents of LDMC, MDA, POD, and CAT in the ten plant species followed the order CR > NL > PAR, and SLA, SOD, SS, and total chlorophyll showed trends of PAR > NL > CR. The microstructures of the leaves of the ten plant species, such as SA, TUE, and TS, were evident in the expression of adaptive adjustments to the different green space environments. The principal component analysis and the comprehensive evaluation of the affiliation function of the indicators of the ten plant species revealed that the adaptability of the ten green space plants to the complex urban environment was as follows: Euonymus japonicus ‘Aurea-marginatus’ > Lagerstroemia indica > Acer palmatum > Photinia × fraseri > Platanus acerifolia> Camphora officinarum > Loropetalum chinense > Ginkgo biloba > Euonymus japonicus > Pittosporum tobira. The results of the study will help to further understand the layout, application, and maintenance of landscape plants in the context of urbanization and provide support for related theories. Full article