ABSTRACT
Compound Qinlan Oral Liquid (,CQOL) is derived from Yinqiao San (), which is composed of Jinyinhua (Lonicerae Japonicae Flos), Huangqin (Scutellariae Radix), Lianqiao (Forsythiae Fructus) and Banlangen (Isatidis Radix). It is a common clinical herbal medicine for clearing heat and detoxification, and has antiviral effects. By reviewing the active ingredients of CQOL and the research progress on its anti-influenza virus and severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) efficacy, with view to providing a basis for the clinical use of CQOL in treatment of respiratory diseases caused by SARS-CoV-2.Copyright © 2023 Editorial Office of Chinese Traditional and Herbal Drugs. All rights reserved.
ABSTRACT
Nowadays, lignin is a byproduct of the agricultural and cellulose pulp mill. Lignin is a sustainable, renewable raw material alternative to petroleum‐based chemicals, mainly for the benzene–toluene–xylene (BTX) production of commodities and the sequential secondary, tertiary and manufactured products in the petrochemical industry. It can be mass produced and is used for renewable energy biorefinery or high‐value‐added products. This review aims to outline the important lignin depolymerization technologies and the feasibility of imposing these transforming technologies on a large scale. Finally, this review examines the market prospects for BTX, revealing its R&D progress. However, the harmful effects of BTX and unfavorable conditions resulting from the COVID‐19 pandemic comprise roadblocks to its growth. However, the increasing use of biobased BTX is expected to open new market opportunities. © 2022 Society of Chemical Industry and John Wiley & Sons, Ltd. [ FROM AUTHOR] Copyright of Biofuels, Bioproducts & Biorefining is the property of John Wiley & Sons, Inc. and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full . (Copyright applies to all s.)
ABSTRACT
In this study, hydrogels based on gelatin and lignin were fabricated as efficient drug carriers for Ribavirin. The obtained hydrogels were characterized by scanning electron microscopy (SEM), ATR-FTIR spectroscopy, differential scanning calorimetry (DSC), mechanical compression and rheometry. Results showed that the pore structure, viscoelastic behavior and swelling ability significantly influenced by varying lignin content and crosslinker ratio. By increasing the crosslinker N-(3-Dimethylaminopropyl)-N'-ethylcarbodiimide hydrochloride (EDC) content, the pore size became smaller, while increasing the lignin content resulted in larger pores. In addition, all hydrogels show strong shear thinning behavior. Ribavirin was used as a drug model, and its release rate was enhanced by increasing lignin content in the binary hydrogel structure. A higher Ribavirin cumulative release was observed for gelatin/lignin with higher lignin content (3 %) hydrogel. These findings emphasize the chemical composition on the structure and the release behavior of lignin-containing hydrogels.
ABSTRACT
Microfibres (diameter <5 mm) and textile dyes released from textile industries are ubiquitous, cause environmental pollution, and harm aquatic flora, fauna, animals and human life. Therefore, enzymatic abatement of microfibre pollution and textile dye detoxification is essential. Microbial enzymes for such application present major challenges of scale and affordability to clean up large scale pollution. Therefore, enzymes required for the biodegradation of microfibres and indigo dye were expressed in transplastomic tobacco plants through chloroplast genetic engineering. Integration of laccase and lignin peroxidase genes into the tobacco chloroplast genomes and homoplasmy was confirmed by Southern blots. Decolorization (up to 86%) of samples containing indigo dye (100 mg/L) was obtained using cp-laccase (0.5% plant enzyme powder). Significant (8-fold) reduction in commercial microbial cellulase cocktail was achieved in pretreated cotton fibre hydrolysis by supplementing cost effective cellulases (endoglucanases, ß-glucosidases) and accessory enzymes (swollenin, xylanase, lipase) and ligninases (laccase lignin peroxidase) expressed in chloroplasts. Microfibre hydrolysis using cocktail of Cp-cellulases and Cp-accessory enzymes along with minimal dose (0.25% and 0.5%) of commercial cellulase blend (Ctec2) showed 88%-89% of sugar release from pretreated cotton and microfibres. Cp-ligninases, Cp-cellulases and Cp-accessory enzymes were stable in freeze dried leaves up to 15 and 36 months respectively at room temperature, when protected from light. Use of plant powder for decolorization or hydrolysis eliminated the need for preservatives, purification or concentration or cold chain. Evidently, abatement of microfibre pollution and textile dye detoxification using Cp-enzymes is a novel and cost-effective approach to prevent their environmental pollution.
ABSTRACT
Nowadays, lignin is a byproduct of the agricultural and cellulose pulp mill. Lignin is a sustainable, renewable raw material alternative to petroleum-based chemicals, mainly for the benzene-toluene-xylene (BTX) production of commodities and the sequential secondary, tertiary and manufactured products in the petrochemical industry. It can be mass produced and is used for renewable energy biorefinery or high-value-added products. This review aims to outline the important lignin depolymerization technologies and the feasibility of imposing these transforming technologies on a large scale. Finally, this review examines the market prospects for BTX, revealing its R&D progress. However, the harmful effects of BTX and unfavorable conditions resulting from the COVID-19 pandemic comprise roadblocks to its growth. However, the increasing use of biobased BTX is expected to open new market opportunities. (c) 2022 Society of Chemical Industry and John Wiley & Sons, Ltd.
ABSTRACT
BACKGROUND/AIM: The rapid spread of COVID-19 resulted in the revision of the value of ultraviolet C (UVC) sterilization in working spaces. This study aimed at re-evaluating the anti-UVC activity of four groups of natural products against human melanoma COLO679 and human normal dermal fibroblast (HDFa) cells, based on chemotherapeutic index. MATERIALS AND METHODS: Various cell lines were exposed to UVC for 3 min in the presence of increasing concentrations of test compounds and viable cell numbers were determined with the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay. The anti-UVC activity was quantified by the ratio of the 50% cytotoxic concentration (determined without irradiation) to the 50% effective concentration (which abolished by 50% the UVC-induced loss of viability). Apoptosis was quantified as the subG1 population proportion following cell-cycle analysis. RESULTS: Among four groups of major natural products, six phenylpropanoids showed the highest anti-UVC activity, followed by the lignified products and alkaline products that contain lignin and its degradation products. On the other hand, tannins and flavonoids showed lower activity due to their higher cytotoxicity. UVC-sensitive COLO679 cells lack dectin-1 protein expression. CONCLUSION: These data suggest the prominent anti-UVC activity of lignin degradation products, and the possible involvement of dectin-1 expression in UVC-sensitivity.
Subject(s)
Biological Products , COVID-19 , Melanoma , Humans , Lignin/pharmacology , Ultraviolet Rays , Biological Products/pharmacologyABSTRACT
In recent years, it has been reported that many herbal plants contain antiviral agents which combat a human disease that is caused by pathogenic viruses. The natural products which are obtained from plants as antiviral agents against viruses have gone through researches to check the efficacy and potentials of the herbal products in the prevention of viral disorders. On the basis of randomized controlled studies and in-vivo studies, and in-vitro studies, some agents are utilized all across the globe. Progressively numerous studies on therapy of antivirals have been increased. Though, efficacy remains disputable for antiviral drugs that are employed for viral disorders. The viral diseases are challenging for the health of people around the world cause significant increase in mortality and enhance crises. There are many synthetic antiviral drugs that have a large number of side effects and have narrow therapeutic window range, while in the other hand herbal formulations have minimized side effects. The advantages of herbal formulation over synthetic drugs encourage us to devise and expand new herbal moieties against the emerging viral infections. The medicinal plants contain phytochemicals that have antiviral properties. In this paper, the activity of antiviral agents from medicinal plants which have importance in Ayurveda, are discussed along with their source.
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The review considers two directions of lignin valorization: valorization of technical lignins, as such, without preliminary depolymerization, and valorization through monomeric compounds formed as a result of their selective destruction. The first area includes the production of lignin hydrogels, the use of lignin in medicine and pharmacology, 3D printing, as well as in the production of carbon fibers and biofuels. Lignin hydrogels are distinguished by a high sorption capacity with respect to heavy metals such as lead, iron and copper, which, depending on the content of acidic groups in lignin and the molar mass of sorbate, is ~ 25-50% of the mass of lignin, and therefore they can be used for the purification of waste waters of chemical enterprises. Lignin has high biological activity against various pathogens, including viruses, which makes research in this area very relevant, especially against the backdrop of the COVID-19 pandemic. The use of lignin in some composites for 3D printing can increase the mechanical strength of finished products. The industrial implementation of the technology for the production of carbon fibers from lignin will ensure a twofold reduction in the mass of vehicles. The second direction of lignin valorization - hydrogenolysis and selective oxidation - allows one to obtain monomeric compounds with a yield close to the theoretical one. The economic aspects of valorization are also considered. In addition, based on a comparison of the results of valorization of coniferous and deciduous lignins, a hypothesis on the structure of native lignin was proposed. © 2022 Altai State University. All rights reserved.
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Respiratory viral infections are a major public health concern because of their global occurrence, ease of spread and considerable morbidity and mortality. Medical treatments for viral respiratory diseases primarily involve providing relief from symptoms like pain and discomfort rather than treating the infection. Very few antiviral medications have been approved with restrictive usage, high cost, unwanted side effects and limited availability. Plants with their unique metabolite composition and high remedial values offer unique preventive and therapeutic efficacy in treatment of viral infections. The present review is focused on the types and mode of action of plant secondary metabolites that have been used successfully ί in the treatment of infections caused by respiratory viruses like Influenza, SARS, MERS, RSV etc. Plant metabolites such as phenolics, alkaloids, terpenoids and oligosaccharides inhibit attachment and entry of the virus. Others such as flavonoids, viz quercetin and baicalein, alkaloids viz sanguinarine, berberine and emetine, specific lipids and fatty acids prevent viral replication and protein synthesis. These metabolites have the potential to be used as lead molecules that can be optimized to develop potent drugs for effectively combating pandemics caused by respiratory viruses.
ABSTRACT
Lignin has recently attracted the attention of the scientific community, as a suitable raw material for biomedical applications. In this work, acetylated lignin was used to encapsulate five different porphyrins, aiming to preserve their photophysical properties, and for further use as antibacterial treatment. The obtained nanoparticles were physically characterized, through dynamic light scattering size measurement, polydispersity index and zeta potential values. Additionally, the photophysical properties of the nanoparticles, namely UV-vis absorption, fluorescence emission, singlet oxygen production and photobleaching, were compared with those of the free porphyrins. It was found that all the porphyrins were susceptible to encapsulation, with an observed decrease in their fluorescence quantum yield and singlet oxygen production. These nanoparticles were able to exert an effective photodynamic bactericide effect (blue-LED light, 450-460 nm, 15 J/cm2) on Staphylococcus aureus and Escherichia coli. Furthermore, it was achieved a photodynamic bactericidal activity on an encapsulated lipophillic porphyrin, where the free porphyrin failed to diminish the bacterial survival. In this work it was demonstrated that acetylated lignin encapsulation works as a universal, cheap and green material for the delivery of porphyrins, while preserving their photophysical properties.