486-35-1 Usage
Description
Daphnetin, mainly extracted from Yu Ruixiang Changbai Daphne (Daphne Korean Nakai), Daphne giraldii Nitsche bark, and root bark, is the main efficacy component of the plants D.tangutica Maxim and D.retttsa Hemsl. Changbai daphnes has the pharmacological effects of warming the spleen and stomach, relaxing the muscles and joints, and promoting circulation. In TCM, it’s commonly used as medicines for treatment of injuries. Because Changbai daphne is a pungent and warm natured herbal medicine, it was used to warm the spleen and stomach by dispelling cold.
Physical properties
Appearance: white or off-white powder, odorless, and tasteless; Solubility: slightly
soluble in methanol (equilibrium solubility of 485.4? μg/mL), slightly soluble in
ethanol (equilibrium solubility of 230.06?μg/mL), and insoluble in water (equilibrium solubility of 176.7?μg/mL) ; Melting point: 262–264?°C.
History
Changbai daphne, a Chinese traditional medicine in clinic, is mainly used for treatment of coronary heart disease, rheumatoid arthritis, thromboangiitis obliterans,
etc. Changbai daphne belongs to the first-class protective plants in Jilin province in China, and the rarity restricted the drug development. Scientists tried to find the
effective components of Changbai daphne. In 1977, scientists of phytochemistry
research group in the Traditional Chinese Medicine research laboratory from Jilin
institute of Chinese medicine first successfully isolated the crystalline monomer?–
daphnetin?– from the plant. Pharmacological results show that the pharmacological
activities of this crystal are equal to Changbai daphne, which suggested the crystal
is the main active ingredient . Through the condensation reaction experiment
using equimolecular pyrogallic acid, malic acid, and twice the amount of sulfuric
acid, under heating reaction, scientists successfully got pale yellow needle daphnetin crystals. From then on artificially synthesized daphnetin has been successfully
implemented . A large-scale industrial production can be acquired. The followup researches on the metabolism and pharmacological activity of daphnetin were
carried out. In 2009, the State Food and Drug Administration of China approved
daphnetin capsule to be used in the clinical.
Uses
Daphnetin is a natural coumarin derivative providing anti-inflammatory and protective properties to those suffering from lung injury.
Indications
This product is contained in national standards for chemical drugs, mainly used in
Buerger’s disease, occlusive vascular disease, and coronary heart disease.
General Description
This substance is a primary reference substance with assigned absolute purity (considering chromatographic purity, water, residual solvents, inorganic impurities). The exact value can be found on the certificate. Produced by PhytoLab GmbH & Co. KG
Biochem/physiol Actions
7,8-Dihydroxycoumarinan is an inhibitor of protein kinases. It is an active lactone present in plants such as Daphne Korean Nakai, and Thymelaeaceae Daphne. It serves as as analgesic, antiviral and antibacterial agent. 7,8-Dihydroxycoumarinan is found to induce tumor apoptosis via a number of signalling pathways. Thus, it is believed to exhibit antitumor effects. 7,8-Dihydroxycoumarinan might also be useful in treating lung carcinoma. It is also known to be used in treating coagulation disorders and rheumatoid arthritis. 7,8-Dihydroxycoumarinan is known to induce neurite growth and lengthen neuronal survival. It helps in clearing substances inducing necrosis, maintains water-electrolytes balance and energy metabolism. 7,8-Dihydroxycoumarinan is involved in the generation of neurotrophic factor and helps in restoring neuron function.
Pharmacology
Daphnetin pharmacological effect mainly includes: 1. Improvement of the cardiovascular system function; 2. Effects on the central nervous system.
Daphnetin also acts on the NF-k B and NFAT signal pathway and results in immune inhibition; it is also used for the treatment of malaria parasite and Pneumocystis carinii infection by chelating to Fe2 + or by acting on ribonucleotide reductase; daphnetin shows bacteriostatic effects on gold grapes, Escherichia coli, Shigella’s blessing, and Pseudomonas aeruginosa by inhibiting succinic acid oxidase in mitochondria in bacteria; daphnetin reduces the incidences of diarrhea in model mice by inhibiting mice gastrointestinal propulsive movement and has a stronger toxic effect on several important aphids .
Plasma protein binding of Daphetin is low. The urinary excretion is higher. The distribution volume is relatively larger. Both of metabolism and excretion are rapid. Drug elimination is mainly through the kidney with a half-life of only 15 min. The tissue distributions after intravenous injection and oral administration are equal. Daphnetin may distribute in the brain through the blood-brain barrier. The metabolites have poor stability and low oral bioavailability. People have studied the metabolic pathways and metabolic product. Daphnetin may be the substrates of MRP2 and BCRP transporters, and thus intestinal absorption is affected; in the plasma of rats, the main metabolite are 7-O and 8-O glucoside substitution products which are mediated by UT1A6 and UT1A9. The anti-inflammatory activity of the metabolites is dependent on daphnetin-7-methyl ether.
Clinical Use
It has been verified by a large number of clinical cases that oral daphnetin capsule
can significantly improve thromboangiitis obliterans; oral daphnetin has a better
curative effect than intramuscular injection of Changbai daphne in patients with
angina pectoris due to coronary heart disease. Daphnetin shows an obvious analgesic sedative effect on surgical and nonsurgical pain-relieved patients after intravenous drip or injection of daphnetin; oral daphnetin capsule shows significant
therapeutic effects on rheumatoid arthritis.There are no reports about serious adverse reactions. Two cases of whole-body
red itch were reported. It sometimes has mild gastrointestinal reaction when continuously used.
Purification Methods
Crystallise it from aqueous EtOH. It can be sublimed. [Beilstein 18/3 V 202.].
Check Digit Verification of cas no
The CAS Registry Mumber 486-35-1 includes 6 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 3 digits, 4,8 and 6 respectively; the second part has 2 digits, 3 and 5 respectively.
Calculate Digit Verification of CAS Registry Number 486-35:
(5*4)+(4*8)+(3*6)+(2*3)+(1*5)=81
81 % 10 = 1
So 486-35-1 is a valid CAS Registry Number.
InChI:InChI=1/C9H6O4/c10-6-3-1-5-2-4-7(11)13-9(5)8(6)12/h1-4,10,12H
486-35-1Relevant articles and documents
Coumarins from the bark of Daphne marginata
Zhang, Wei,Shen, Yunheng,Liu, Runhui,Zhang, Chuan,Chen, Haisheng,Fu, Peng,Shan, Lei,Zhang, Weidong
, p. 317 - 318 (2007)
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Sato,Hasegawa
, p. 2367,2372 (1971)
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Antagonistic activity of hydroxycoumarin-based antioxidants as possible singlet oxygen precursor photosensitizers
Guerrero, Tomás,Vázquez-Ortega, Fernanda,Lagunes, Irene,Ortiz-Blanco, Erik,Sosa-Ortiz, Gabriela,Tovar-Miranda, Ricardo,Medina, Manuel E.,Trigos, ángel
, (2021/05/10)
Coumarins are phenolic-type compounds with efficient antioxidant activity due to their ability to scavenge reactive oxygen species. Nevertheless, their ability to behave as photosensitizers capable of generating reactive oxygen species, such as singlet oxygen, has been less studied. In this work, the photosensitizing ability of seven hydroxycoumarins was evaluated through the photooxidation of ergosterol by quantifying the conversion of ergosterol into ergosterol peroxide. In our experimental conditions, we found that almost every tested antioxidant coumarin promotes the peroxidation of ergosterol. The results suggest that the hydroxycoumarins exhibit potential photosensitizing activity by promoting singlet oxygen generation by a Type II photochemical mechanism. Density functional theory (DFT) calculations were also performed to obtain further insight into the chemical reactivity of tested compounds; the observed tendency in the group of antioxidant coumarins to promote the reaction was their hardness due to the principle of maximum hardness. To evaluate our conclusion, we performed the reaction using a highly polarizable coumarin as a photosensitizer, which resulted in an increased photosensitizing capacity supported with DFT calculations, which reinforces our analysis. Finally, we found that hydroxycoumarins can be potentially pro-oxidants since some of them can act as photosensitizers and generate singlet oxygen in the presence of UV–Vis light, a characteristic that must be considered when these compounds are used as antioxidants.
Strong antimicrobial activity of collinin and isocollinin against periodontal and superinfectant pathogens in vitro
Bola?os, Gustavo,Contreras, Adolfo,Pardo-Casta?o, Camilo,Vásquez, Daniel
, (2020/02/03)
Periodontitis pathogenesis involves activation of host immune responses triggered by microbial dysbiosis. Therefore, controlling periodontal pathogens in-vivo is a main goal of periodontal therapy. New antimicrobials might help to control periodontal infection and improve treatment outcomes at “the dark times” of increasing antibiotic resistance. Here, we determined the biological activity of collinin and isocollinin against 8 bacterial strains. Antimicrobial activity of collinin and isocollinin, chlorhexidine digluconate (CHX) and sodium hypochlorite (NaClO) was evaluated against clinically relevant periodontal bacteria, like Aggregatibacter actinomycetemcomitans, Porphyromonas gingivalis, Fusobacterium nucleatum, Prevotella intermedia, Dialister pneumosintes strains and superinfectants like Escherichia coli, Staphylococcus aureus, and Pseudomonas aeruginosa strains. A broth microdilution test was carried out to determine the minimum inhibitory concentration of collinin and isocollinin against those strains, and bacterial viability was determined by resazurin assay at diverse concentration and exposure times. P. gingivalis was the most susceptible strain to collinin and isocollinin (MIC 2.1 μg/mL and 4.2 μg/mL respectively). Other periodontal pathogens showed MICs 17 μg/mL for collinin and MICs between 20 and 42 μg/mL for isocollinin, whereas CHX and NaClO showed MICs of 62 and 326 μg/mL, respectively. Collinin and isocollinin also exhibited antimicrobial activity against superinfectant bacteria (MIC 21 and 42 μg/mL, respectively). Overall, collinin and isocollinin showed a remarkable antibacterial activity against relevant periodontal and superinfective bacteria, especially against P. gingivalis (MIC 2.1 μg/mL and 4.2 μg/mL respectively) and the highly virulent P. aeruginosa (MIC 5.2 and 20.8 μg/mL, respectively).
Solubility of Collinin and Isocollinin in Pressurized Carbon Dioxide: Synthesis, Solubility Parameters, and Equilibrium Measurements
Pardo-Casta?o, Camilo,García, Andrés C.,Benavides, Paola,Bola?os, Gustavo
, p. 3799 - 3810 (2019/09/30)
Collinin is a derivative of coumarin that has shown remarkable potential against cancer, tuberculosis, periodontitis, and other prevalent diseases, and is usually extracted from plants of the Rutaceae family at a very low yield. In this work, collinin and a position-isomer herein called isocollinin were synthesized at different scales (from 1 to 50 g of precursor) by a route consisting of two parallel and two sequential chemical reactions. The isomers were characterized by 1H NMR, 13C NMR, nuclear Overhauser enhancement spectroscopy NMR, melting temperature, and melting enthalpy. For each isomer, the Hansen solubility parameters and the radius of its solubility sphere were experimentally determined by solubility tests in 15 common solvents and two solvent blends. The solubility of each isomer in pressurized CO2 was determined at 30 and 50 °C from 72.2 to 112.9 bar, by an in situ high-pressure spectrometry technique, which was validated with the anthracene-CO2 system. The solubility of both isomers in CO2 increased with pressure in the range of temperatures and pressures considered, but that of collinin exhibited an asymptotic behavior around 80.8 and 104.8 bar, at 30 and 50 °C, respectively.