Willow Research Articles

Discerning the Multi-dimensional Role of Salicin: Bioactive Glycoside Beyond Analgesic: Different Perspectives

: Salicin is a glycoside that can be found in several Salix and Populus species. Salicin is also connected to the glycoside populin, commonly known as benzoyl Salicin, in the Salicaceae tree barks. D-glucose is a component of the alcoholic glycoside Salicin (C13H18O7). The willow tree, as well as other trees like poplar and aspen, contains the natural chemical Salicin, which is a member of the salicylate family. Salicin is an anti-inflammatory and analgesic used in conventional medicine, and it served as the inspiration for the creation of aspirin. This molecule may have important human pharmacological actions that need to be considered in determining the efficacy and safety of willow herbal medicines. The extracts obtained from the bark of the tree, belonging to the Saliceae family in different solvents have been known for possessing many important medicinal values by potent pharmacological actions. The current effort deals with exquisite detailed aspects and concerns related to Salicin, which will be fruitful for the futuristic approaches to Salicin.

The Enderby Bark Shield: A New Model for the Ancient World

A 2300 year old bark shield found in Enderby, Leicestershire, in 2015 is the only known example of its type. Made from the bark of a willow tree, it has a woven basket boss, a roundwood handle, and a rim of split roundwood edging and lime bast bindings. Pre-Roman shields made from organic materials rarely survive in Britain and Ireland and those without metal components are exceptionally rare. Contemporaneous wooden shields are known from anaerobic environments in Scandinavia but, unlike Enderby, none of these has a body of tree bark. The complexity of the design of the Enderby shield, the skill with which it was made, and the similarities between this and metal examples suggests it was a tried and tested design, rather than a one-off. With no other example against which to compare it, experiments in reproducing the shield have been used as a tool for interpretation and have proved vital to understanding the original design. As a result of this research, it is proposed that this single artefact represents a more commonly available form of shield in the 1st millennium bc than does any metal enhanced version.

A Study on Evaluating Factors Influencing Behavioral Intentions Toward Purchasing Kashmir Willow Bat

Kashmir, a region renowned for its breath-taking scenery and deep cultural legacy, has long been a hub for handicrafts. Salix alba, or willow trees, are native to the area and thrive there solely due to its special climate. Willow trees have long been used to make premium cricket bats. The Kashmir willow bat is highly sought-after by cricket players all over the world because of its exceptional performance and lightweight design, which have made it synonymous with the game. The purpose of the study is to evaluate the factors influencing behavioral intentions toward purchasing Kashmir willow bats. SEM technique was used to analyze the collected data. The outcome of the study indicated that there is a significant impact of attitude, perceived behavioral control, and subjective norms on behavioral intention.

Обобщенные модели фитомассы деревьев ивы (род Salix L.): мета-анализ

Climate change has a negative impact on the environment, including forest ecosystems. However, forests are not only passive objects affected by climate change, but also, due to their ability to absorb and accumulate carbon, they themselves can significantly influence this process. Carbon sequestration by forest ecosystems plays an important role in mitigating the effects of climate change. Therefore, it is necessary to know about the amount of carbon stored in forest phytomass, and it is becoming increasingly important to accurately determine the phytomass of forest trees. Due to the absorption of carbon dioxide during plant growth and its release during wood burning, forests are a carbon-neutral energy source. The idea of using phytomass as an energy source to replace fossil fuels is most promising for fast-growing species. These include willows (genus Salix L.), native to Europe, Asia, America and Africa and found from the tundra to the tropics. Willow is successfully used as fuel in many countries, showing excellent growth and productivity even at juvenile stages and, under certain climatic conditions, having the highest capacity among woody plants to convert solar radiation into phytomass. Short-rotation willow plantations represent an ecologically promising energy resource for reducing greenhouse gas levels. Since the development of phytomass models is a laborious process, so-called “generic meta-models” are used. The aim of this study has been to construct generic models of both aboveground phytomass and phytomass fractions (foliage, branches, stem, roots) of willow trees based on meta-analysis of data. In the course of the work, the models have been constructed for assessing the aboveground phytomass of trees both in diameter at the stem base and in diameter at breast height, the information content of which is close to functional, and the biases are only about 2 %. Since each fraction of phytomass has a specific carbon-sequestering capacity and makes a different contribution to the carbon balance, generic models have been developed to estimate the mass of foliage, branches, stems and roots in relation to the aboveground phytomass of trees, explaining from 82 % (for foliage) to 99 % (for stems and roots) of the total variability of phytomass.

Engineering a novel pathway for efficient biosynthesis of salicin in Escherichia coli

Salicin is a natural glycoside compound widely used to treat fever, inflammation, and analgesia. Currently, salicin is primarily extracted from willow bark, which is not only cumbersome in terms of extraction and separate steps, but also subject to seasonal and geographic limitations. In this study, a highly efficient biosynthetic pathway for salicin synthesis was designed and constructed in E. coli. The most important precursor in the synthetic pathway of salicin designed in this study is salicyl alcohol. Building on a previously constructed biosynthetic salicylic acid metabolic pathway, the production of salicyl alcohol in shake flask fermentation reached 1.7 g/L by increasing the supply of shikimic acid pathway precursor PEP and salicyl alcohol precursor chorismate. According to the principle of substrate similarity, this study identified the key enzyme OsSGT1 from Oryza sativa, which uses E. coli endogenous UDP-glucose as a glycosyl donor to glycosylate salicyl alcohol into salicin. By redefining the optimal substrate of OsSGT1, and balancing metabolic flux along with increasing the supply of UDP-glucose, salicin production in shake flasks reached 4 g/L. Finally, culturing the high-yield strain in a 3-L fermenter resulted in the synthesis of 14.62 g/L of salicin. To the best of our knowledge, this achievement marks the highest salicin production through microbial fermentation to date.

A comparative study of pulsed electric field, ultrasound, milling and soaking as pre-treatments for assistance in the extraction of polyphenols from willow bark (Salix alba)

White willow (Salix alba) has a long history of use as an herbal remedy for treating common pain and inflammation. Pre-treatment is a crucial step that assists the subsequent extraction process and may affect the extraction efficiency of polyphenols from plant materials. The objective of this work was to study the impact of pre-treatment methods on the hot water extraction of polyphenols from willow bark. Pulsed electric field (PEF) and ultrasound (US) pre-treatments were compared to commonly used pre-treatment methods, milling and soaking. All pre-treatments significantly increased the total phenolic content (TPC) and antioxidant activity (p < 0.05) in willow extracts. At a similar energy level, PEF with 400 pulses yielded a higher TPC (44.33mg GAE/g d.w.) and antioxidant activity (DPPH of 74.58mg AAE/g and FRAP of 186.41mmol TE/g) than US pre-treated samples, but a small increase in ultrasonic energy resulted in the highest TPC (46.20mg GAE/g d.w.) and antioxidant activity (DPPH of 76.18mg AAE/g and FRAP of 220.20mmol TE/g) of all the pre-treatments. Compared with PEF and US, milling (42.69mg GAE/g d.w.) and soaking (40.29mg GAE/g d.w.) were less effective in recovering polyphenols but they were comparable with PEF and US when employed at low energy levels. Overall results indicate emerging technologies PEF and US can be alternatives to milling to enhance the extractability of polyphenols and to reduce energy consumption. The obtained willow extracts were a rich source of polyphenols that could be used for food and pharmaceutical applications.

A new lattice approach for risk-minimization hedging under generalized autoregressive conditional heteroskedasticity models

This paper explores the calculation of risk-minimization hedging strategies, specifically local and global risk minimization strategies for contingent claims under affine and non-affine GARCH models with the known closed forms of its first four moments across times under the physical measure. A unified and efficient willow tree method is introduced for various GARCH models. Unlike methods that provide option values and hedging ratios solely at the inception time, the proposed willow tree method generates a comprehensive table of option values and hedging ratios at each discrete time step across possible asset prices. Additionally, the method showcases robust performance in hedging at lower frequencies than the underlying asset’s modeling frequency (e.g., weekly or monthly hedging using a daily GARCH model). Lastly, the willow tree method outperforms the Monte Carlo method, offering greater efficiency, accuracy, and flexibility in solving risk-minimization hedging problems.

The first detection of the poplar bark aphid, Pterocomma populeum (Hemiptera: Aphididae), in Australia

AbstractPterocomma (Hemiptera: Aphidinae) are large aphids found across the northern hemisphere on various willow (Salix) and poplar (Populus) trees. We provide the first records of the Poplar Bark Aphid, Pterocomma populeum in Australia from Tasmania and New South Wales, a potential pest of poplar trees. Morphological character measurements and DNA (cytochrome oxidase subunit 1) sequences are provided along with discussions around difficulties in species separation.

Enrichment of novel entomopathogenic Pseudomonas species enhances willow resistance to leaf beetles

BackgroundPlants have evolved various defense mechanisms against insect herbivores, including the formation of physical barriers, the synthesis of toxic metabolites, and the activation of phytohormone responses. Although plant-associated microbiota influence plant growth and health, whether they play a role in plant defense against insect pests in natural ecosystems is unknown.ResultsHere, we show that leaves of beetle-damaged weeping willow (Salix babylonica) trees are more resistant to the leaf beetle Plagiodera versicolora (Coleoptera) than those of undamaged leaves. Bacterial community transplantation experiments demonstrated that plant-associated microbiota from the beetle-damaged willow contribute to the resistance of the beetle-damaged willow to P. versicolora. Analysis of the composition and abundance of the microbiome revealed that Pseudomonas spp. is significantly enriched in the phyllosphere, roots, and rhizosphere soil of beetle-damaged willows relative to undamaged willows. From a total of 49 Pseudomonas strains isolated from willows and rhizosphere soil, we identified seven novel Pseudomonas strains that are toxic to P. versicolora. Moreover, re-inoculation of a synthetic microbial community (SynCom) with these Pseudomonas strains enhances willow resistance to P. versicolora.ConclusionsCollectively, our data reveal that willows can exploit specific entomopathogenic bacteria to enhance defense against P. versicolora, suggesting that there is a complex interplay among plants, insects, and plant-associated microbiota in natural ecosystems.Graphical 5putw3esi-W9k4EYdexs12Video

Preparation of Polyphenol-Rich Herbal Beverages from White Willow (Salix alba) Bark with Potential Alzheimer’s Disease Inhibitory Activity In Silico

White willow (Salix alba) is a medicinal plant traditionally used to treat pain and inflammation. The aims of this study were to produce polyphenol-rich herbal beverages from willow bark with different ethanol content, temperatures, and solvent pH and to explore neuroprotective potentials of willow polyphenols. The phenolic compounds quantified in the willow infusions were salicin, chlorogenic acid, epicatechin, p-salicylic acid, and p-coumaric acid; the former three compounds exhibited promising inhibitory potentials against acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) in molecular docking studies. Total phenol content and antioxidant activity were maximum when prepared with 50% ethanol-in-water at room temperature. Although aqueous infusions contained fewer total phenols than those extracted with 50% hydroalcoholic solutions, they enhanced the extraction of chlorogenic acid and salicin content, which may possess promising neuroprotective potentials. The addition of citric acids in hot water infusions led to a higher proportion of non-tannins and had a lighter appearance, which may result in less astringent mouthfeel and better consumer acceptance. Overall, the obtained results indicate that willow bark prepared with hot water and/or with addition of citric acids is rich in bioactive compounds with high antioxidant activity and possible neuroprotective activities in silico, which could serve as valuable ingredients for inclusion in functional beverages.

Exploring phytoremediation potential of willow NJU513 for cadmium-contaminated soil with and without epibrassinolide treatment

There has been a growing concern over soil cadmium (Cd) pollution, underscoring the importance of finding effective remediation strategies. Willow trees have emerged as promising candidates for phytoremediation of Cd-contaminated soils. Nevertheless, the specific potential of a novel willow genotype, NJU513, in remediating Cd-polluted soil remains unexplored. Hence, the primary objectives of this study were twofold: firstly, to ascertain the suitability of the willow genotype NJU513 for remediating Cd-contaminated soil; and secondly, to elevate its remediation efficciency with the application of epibrassinolide (Brs). In the pot-culture experiment without Brs, its leaf and stem Cd concentrations were 203 mg kg−1 and 65.1 mg kg−1, with a bioaccumulation factor (BCF) of 20.8 and 6.68, respectively. In the pot-culture experiment with Brs, the corresponding Cd concentrations were 226 mg kg−1 and 59.2 mg kg−1, with a BCF of 23.1 and 6.06, respectively. In addition, the extracted Cd contents were higher in the Brs treatments (1.11–1.37 mg plant−1) than in the no-Brs treatments (0.78–0.96 mg plant−1) because Brs increased the plant biomass and leaf BCF. The mechanism underlying the Cd accumulation of NJU513 leaves with and without Brs was revealed by a transcriptome analysis. The expression levels of genes related to metal ion binding, channel activity, and transporters in leaves were up-regulated, which contributed to the high Cd accumulation and stress tolerance. Analyses of soil metabolites and bacteria in the presence and absence of Brs spraying on willow leaves indicated that soil organic compounds with carboxyl and amino groups may induce Cd activation and passivation, respectively. This study provides valuable insights for developing woody plant varieties that can be used for remediating Cd-contaminated soil.

Potential skin anti-aging effects of main phenolic compounds, tremulacin and tremuloidin from Salix chaenomeloides leaves on TNF-α-stimulated human dermal fibroblasts

The genus Salix spp. has long been recognized as a healing herb for its use in treating fever, inflammation, and pain relief, as well as a food source for its nutritional value. In this study, we aimed to explore the potential bioactive natural products in the leaves of Salix chaenomeloides, commonly known as Korean pussy willow, for their protective effects against skin damage, including aging. Utilizing LC/MS-guided chemical analysis of the ethanol extract of S. chaenomeloides leaves, with a focus on major compounds, we successfully isolated two main phenolic compounds, tremulacin (1) and tremuloidin (2). Subsequently, we investigated the protective effects of tremulacin (1) and tremuloidin (2) in TNF-α-stimulated human dermal fibroblasts (HDFs). The results revealed that both tremulacin (1) and tremuloidin (2) inhibited TNF-α-stimulation-induced ROS, suppressed matrix metalloproteinase-1 (MMP-1) expression, and enhanced collagen secretion. This implies that both tremulacin (1) and tremuloidin (2) hold promise as preventive agents against photoaging-induced skin aging. Furthermore, we assessed the activity of mitogen-activated protein kinases (MAPKs), cyclooxygenase-2 (COX-2), and heme oxygenase 1 (HO-1) to elucidate the mechanism of photoaging inhibition by tremuloidin (2), which exhibited superior efficacy. We found that tremuloidin (2) inhibited ERK and p38 phosphorylation and notably suppressed COX-2 expression while significantly upregulating HO-1 expression. These findings suggest potent anti-inflammatory and antioxidant properties of tremuloidin (2), positioning it as a potential candidate for combating photoaging-induced skin aging.

Accumulation of airborne microplastics on leaves of different tree species in the urban environment

Microplastics (MPs) are omnipresent in the environment and they are linked to ecosystem and human health problems. The atmospheric transport of MPs and the role of tree leaves in MP atmospheric deposition has not been adequately studied. MP concentrations on the leaves of different tree species in urban regions of the Netherlands and Portugal, along with related MP deposition, were investigated in this study. We collected leaves from cedar, eucalyptus, oak, pine and willow trees, together with monthly deposition of particles under the trees and in the open space in Coimbra (Portugal). In Wageningen (the Netherlands), we collected leaves from a fir and a holly tree at different heights above the ground and with dry and wet weather conditions. MPs were extracted through density separation and quantified under a microscope. Polymer types were identified using μ-FTIR. The results showed a higher number of MP particles on the needle-shaped leaves from fir (2.52 ± 2.14 particles·cm−2) and pine (0.5 ± 0.13 particles·cm−2) and significantly lower numbers of MPs per cm2 of leaf area on the bigger leaves from eucalyptus (0.038 ± 0.003 particles·cm−2) and cedar (0.037 ± 0.002 particles·cm−2). All tree leaves seemed to filter airborne MPs, especially the smallest particles. A non-significantly higher number of particles on leaves was detected on lower tree branches and after dry periods. The deposition of MPs under trees was generally higher than in the open space. Our results indicated that part of the MPs retained by the tree leaves floats down to lower branches and to the soil surface. We also saw that different tree species had different capacities to retain particles on their leaves over time. To control the transport of MPs through the atmosphere, it is essential to consider the role of different vegetation types in filtering small particles, especially in cities.

A systematic analysis of GASA family members in the Salix matsudana genome: Characterization, expression profile, and putative function in antioxidation

The gibberellic acid stimulated Arabidopsis (GASA) gene family, specific to plants, plays a pivotal role in growth, development, and response to diverse environmental stresses. Despite their importance, GASA genes in willow trees have been little studied. Here, 35 SmGASAs were identified from the Salix matsudana genome, which exhibited similar physical and chemical proprieties to GASAs in other species. A phylogenetic analysis revealed that GASAs from Populus trichocarpa, Vitis vinifera, Nicotiana tabacum, Oryza sativa, Arabidopsis thaliana, and S. matsudana are categorized into three distinct subfamilies. It appeared that polyploidization and segmental duplication have contributed to the expansion and diversification of the SmGASA family. These genes were significantly enriched in response to GA and oxygen-containing compounds. The diverse expression patterns observed across willow varieties suggested functional variation of SmGASAs throughout their evolutionary history. The expression profiles of SmGASAs were further analyzed in response to different treatments (i.e., salt, submergence, and polyethylene glycol (PEG)), indicating a potential role for SmGASAs in adapting to these stressors in willows. Remarkably, SmGASAs were shown to detoxify hydrogen peroxide (H2O2), highlighting their potent antioxidant properties. Overall, the comprehensive genomic analysis of willow SmGASAs shed light on their role in stress responses, offering valuable insights for future research and supporting the hypothesis of their involvement in stress adaptation mechanisms.

Targeted Chemoprofiling and Bioactivity Screening of Willow Bark

AbstractThe chemoprofile of willow bark (Salix cortex) for pharmaceutical use was investigated using a combination of in vitro bioassays and analytical techniques. Salicylates were isolated by means of (semi‐)preparative HPLC, and their structure was elucidated by means of LC‐MS and 1D/2D‐NMR experiments. Bioactivity assays identified key compounds of selected Salix extracts contributing to the overall anti‐inflammatory potential. Finally, these phytochemicals were mapped quantitatively by means of LC‐MS/MS.

Herbal Modification of Allopathic Analgesic Drug

The integration of herbal medicine with allopathic analgesic drugs has gained attention as a strategy to improve pain management outcomes. This systematic review synthesizes the existing literature on herbal modification of allopathic analgesic drugs. Key herbs such as turmeric (Curcuma longa), ginger (Zingiber officinale), and willow bark (Salix spp.) are explored for their analgesic properties and potential synergies with conventional pain medications. Mechanisms of action, pharmacokinetic interactions, and clinical evidence supporting their combined use are discussed. Challenges including standardization, safety, and regulatory considerations are also addressed. This review provides insights into the integration of herbal remedies into allopathic pain management protocols and identifies areas for future research.

Policy analysis for informing climate adaptation, environmental resilience, and irrigation demands in the Rio Grande Basin

Water policymakers internationally face the challenge of adapting to climate, supporting environmental resource needs, and meeting irrigation demands for food security in the world's arid and semi-arid regions. Much recent work has assessed the economic performance of environmental river flows to support endangered species habitat protection. However, little published work to date has systematically formulated and applied methods to identify the economic performance of various policy measures that adapt to climate, support endangered species, and meet irrigation demands for water. This work's original contribution with international relevance is to address those gaps by identifying the economic performance of various water shortage sharing methods for handling climate water stress while supporting protection of critical habitat to protect the endangered Southwestern willow flycatcher (Empidonax traillii extimus) along with Willow tree (Salix bonplandiana) habitat in the middle part of the Rio Grande Basin in North America, a region facing a number of conflicts between commercial uses of water and protection of key ecological assets. It develops a hydroeconomic optimization model containing information on crop water use and endangered species requirements in that region to identify the economic performance of three climate adaptation policy scenarios for handling water shortages while respecting endangered species habitat protection requirements. Results show how water shortages as well as policy responses for handing those shortages affect the economic value of water in agriculture for food security both with and without critical habitat to support the endangered flycatcher. This work's international relevance comes from its capacity to inform policy debates on the costs of protecting endangered species habitat under various climate scenarios and climate policy adaptation measures. Findings provide a general framework to address existing gaps in understanding and measuring the economic performance of measures to promote environmental resilience.

A Novel Approach for Pain and Inflammation Management

In search for healthy, natural pain relief options is still underway, and salicin from willow bark is a historically significant molecule. The goal of this work is to create a salicin-enriched topical gel formulation as a cutting-edge method of treating pain and inflammation. The objective of this study is to create and assess a salicin- enriched gel made from willow bark, which may be used topically to treat pain and inflammation in place of oral or synthetic drugs. Willow bark was used to extract salicin, which was then added to a topical gel base. The permeability, salicin concentration, and physical stability of the formulation were evaluated.Efficacy was evaluated through in-vitro skin permeation studies and in-vivo anti- inflammatory and analgesic models. The developed salicin- enriched gel demonstrated good physical stability and consistent release of salicin. In-vitro permeation studies indicated effective skin absorption, while in-vivo tests revealed significant reduction in inflammation and pain indicators compared to controls. The gel was well-tolerated with no adverse effects observed. The salicin-enriched gel from willow bark represents a promising topical alternative for pain and inflammation management. Its efficacy and safety profile suggest potential for further development and clinical use. Future studies focusing on larger-scale clinical trials and formulation optimization are warranted to fully establish its therapeutic value.

Effect of the pyrolysis conditions and type of feedstock on nanobiochars obtained as a result of ball milling

Currently, the production of nanobiochar (n-BC) using ball milling is a promising and cost-effective method. Studies concerning the physicochemical properties of bulk biochar (b-BC) in relation to pyrolysis temperature, various feedstocks or types of carrier gas have been thoroughly investigated. However, there is a lack of information on how the mentioned conditions determine the properties of the obtained n-BCs. In this study, b-BCs produced from different feedstocks (willow (WL), sewage sludge (SSL), rice husk (RH) and oilseed rape (OSR)), temperatures (450–750 °C) and carrier gases (N2 or CO2) were ball-milled to produce n-BCs. The specific surface area (SBET), elemental composition (C, H, N, O), morphology (SEM), functional groups (FT-IR), and crystalline and amorphous nature of the carbon (RAMAN) were determined. The size of n-BCs depended on the feedstock used (particles ranged from 30 to 87.9 nm). The type of feedstock mostly determined the properties of n-BCs. The most visible differences between n-BCs and b-BCs were observed for surface properties and C content. For all n-BCs, an SBET increase was observed after ball milling, which may enhance the adsorption potential of biochar. The most intense SBET changes were noted for WL-derived n-BCs obtained at 450 °C (increase from 7.2 to 146.3 m2/g) and at 750 °C (increase from 3.9 to 160.8 m2/g) and for RH-derived n-BCs produced at 550 °C (increase from 3.7 to 158.6 m2/g). The C content decreased for n-BCs produced from plant biomass (WL, RH and OSR) and increased (from 20 to 28%) for n-BCs derived from sewage sludge (SSL). Other physicochemical properties mainly depended on the feedstock used for biochar production.

Physical Modelling Tests With Flexible Woody Vegetation Mimics

Riparian forests in front of dikes can dampen incoming waves and thereby contribute to flood safety. In real-scale flume experiments with live pollard willow trees (forming a 40-m-long forest), it was observed that during storm conditions, a maximum reduction of 20 % in incoming wave height could be achieved (van Wesenbeeck, et al., 2022). Notably, this amount of wave damping occurred at a water depth of 3 meters, aligning with the section of the trees with the maximum frontal-surface area. For a larger water depth, measured wave damping however declined. This is potentially partly caused by the natural tapering form of the trees. Typically, trees are characterized by smaller branch diameters and more flexible branches higher up in the canopy (McMahon &amp; Kronauer, 1976); and flexible vegetation mimics are known to dampen less than rigid mimics due to motion (Van Veelen, T, Reeve, &amp; Karunarathna, 2020). Hence, both the frontal-surface area and branch rigidity decrease along the height of the willow trees, potentially leading to less wave damping by the forest when subject to large waves at higher water levels.