Background: Prunella vulgaris, family Lamiaceae also known as self-heal, has been traditionally used as an expectorant, anti-inflammatory, anti-pyretic, and anti-rheumatic. Due to widespread distribution of the plant, Vulgaris is also called ‘vulgar’ in Latin adjective meaning common. Objective: The objective of this review was to describe the relevant aspects of phytochemistry and therapeutic uses of different fractions as well as isolated compounds from Prunella vulgaris. An attempt was also made to enumerate the possible leads e.g. betulinic acid, oleanolic acid, ursolic acid, umbelliferone, scopoletin, esculetin, luteolin, homoorientin, Rosmarinic acid and cinaroside for further development. Method: For peer-reviewed research literature, we undertook a structured search of bibliographic databases using a focused review question. Scientific databases such as PubMed, Scopus, Science Direct, and Google Scholar were used Results: Phytochemistry of Prunella vulgaris (PV) after a thorough literature survey revealed varied and copious metabolites, such as triterpenoids, phenolic acid, sterols, carbohydrates, coumarins, fatty acids, and volatile oils. Many of these compounds have been found to possess wide range of biological activity per se, including anti-microbial, immunosuppressive, anti-cancer, cardio-protective, anti-allergic and anti-inflammatory. Conclusion: Prunella vulgaris is a medicinal plant of immense medicinal importance having a variety of compounds such as such as triterpenoids, phenolic acid, sterols, carbohydrates, coumarins, fatty acids, and volatile oils and diversity in pharmacological spectrum. The plant could be further exploited, to isolate the various biologically active constituents responsible for its activity.
A new TEMPO-mediated electrochemical method has been developed for N-demethylation of opiates using a home-made batch cell with low-cost porous glassy carbon electrodes. Ndemethylation of opiates such as thebaine, codeine, morphine and oxycodone is a key step in the semi-synthesis of opioid medicines. The electrochemical N-demethylation using TEMPO as mediator enables the synthesis of noropiates, which is not possible with conventional Shono oxidation. Electrolysis was performed at a preparative scale in aqueous solvent at room temperature in a single step, yielding the desired products in good isolated yields (up to 83 %). Mechanistic studies suggest that the electrochemically generated oxoammonium species oxidizes the opiate to an iminium intermediate, which then hydrolyzes to the noropiate. The electrochemical reaction was also performed in a flow-cell without a supporting electrolyte and represents the first electrochemical N-demethylation of difficult opiates with an aminoxyl oxidant.
Flavoenzymes are oxidoreductases that catalyze an extensive range of different types of reactions.An advanced and powerful approach to achieving transformations that are normally outside the realm of flavoenzymes is the synergistic combination of photocatalysis and biocatalysis. Here we report the identification of a promiscuous flavin-dependent nitroreductase, BaNTR1, that is able to promote enantioselective photobiocatalytic reductions of a broad range of structurally diverse ketones to yield the corresponding alcohols with high conversion (up to >99%) and outstanding enantiopurity (up to >99:1 e.r). Noteworthy, BaNTR1 was able to promote the photoenzymatic reduction of various α,ßunsaturated ketones to give the corresponding optically pure alcohols without reducing the C=C or C≡C bond, illustrating its remarkably high chemoselectivity. Our results highlight the usefulness of photocatalysis for expanding the catalytic repertoire of nitroreductases to include highly enantio-and chemoselective reductions of non-native ketone substrates to produce optically pure alcohols. This includes difficult to prepare allyl alcohols that are not accessible via photoenzymatic conversions using ene-reductases.
The incidence of Tuberculosis (TB) is baffling in developing countries due to the increase in multidrug-resistant and extensively drug-resistant TB. Therefore, drugs acting through different mechanisms are in dire need to counter the resistant strains. Various chemical scaffolds are being investigated against tuberculosis, among them the molecules containing phenothiazine nucleus are found to be more effective against both susceptible and resistant strains of M. tuberculosis. In addition, the efficacy of first-line drugs has been found to be enhanced on supplementary treatment with phenothiazines. The present review provides an overview of the phenothiazine based molecules which were investigated during the last ten years for their anti-tubercular activity.
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