15362-40-0Relevant articles and documents
Vilsmeier reagent, NaHSe and diclofenac acid chloride: One-pot synthesis of a novel selenoindolinone with potent anticancer activity
Aydillo, Carlos,Plano, Daniel,Ruberte, Ana Carolina,Sanmartín, Carmen,Sharma, Arun K.
, p. 38404 - 38408 (2020)
An effective and straightforward synthesis of 3-seleno functionalized indolinone (5) involving Vilsmeier reagent is presented. Likewise, a procedure to achieve lactamization of diclofenac with excellent yields by using hydrides is also ascertained. Compou
Stability of diclofenac sodium in the inclusion complex with β-cyclodextrin in the solid state
Cwiertnia, Barbara,Hladon, Teresa,Stobiecki, Maciej
, p. 1213 - 1218 (1999)
The aim of this study was to characterize the thermal stability of diclofenac sodium both alone and in the inclusion complex with β-cyclodextrin in the solid state, by determination of the number of the products of its decomposition, which were identified by GC-MS. The molar ratio of diclofenac sodium in the inclusion complex with β-cyclodextrin was 1:1. The decomposition of diclofenac sodium both alone and in inclusion complex with β-cyclodextrin occurred according to the first-order reaction. The HPLC of the samples thermostated at 80°C gave five products of decomposition, which were identified by GC-MS. Diclofenac sodium in the inclusion complex with β-cyclodextrin was more thermally stable. Thermal decomposition of diclofenac sodium leads to formation of five products, of which 4-chloro-10H-9-acridinone had not been reported previously in the literature.
Synthesis method of diclofenac sodium
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, (2021/09/21)
The invention discloses a synthesis method of diclofenac sodium, which comprises the following steps: (1) toluene. An oil layer is obtained by adding 2, 6 -dichlorophenol and sodium carbonate, keeping warm and refluxing, extracting the oil layer with water, and adding an alkali heat-preserving reaction in the oil layer to obtain 2, 6 -dichloroaniline. (2) 1, 2 Dichlorodimethylaniline prepared in step (6 -) is heated and melted, chloroacetyl chloride is added dropwise, and the heat is subjected to heat preservation reaction after being heated to crystallize to obtain N - (2, 6 - dichlorophenyl) - phenyl - chloroacetamide. (3) 2 (N - 2 Dichlorophenyl) 6 - phenyl - chloroacetamide prepared in step (-) is reacted with the aluminum trichloride to give a solid 1 - (2, 6 -dichlorophenyl) -2 -indolinone. (4) 3 (1 - 2-dichlorophenyl) 6 -indolinone prepared in step (-2 -) is added to alkali liquor, stirred and heated to reflux to obtain diclofenac sodium. The synthesis method is stable, easy to operate, low in cost, high in yield and suitable for industrial production.
Degradation kinetics and mechanism of diclofenac by UV/peracetic acid
Fu, Yongsheng,Liu, Yiqing,Zhang, Li
, p. 9907 - 9916 (2020/03/23)
In this work, the degradation kinetics and mechanism of diclofenac (DCF) by UV/peracetic acid (PAA) was investigated. The effects of pH, PAA dose and common water components such as inorganic ions and dissolved organic matter (DOM) on DCF degradation by UV/PAA were also evaluated. It was observed that the addition of PAA promoted the photodegradation of DCF due to the generation of reactive radicals in the photolysis of PAA, which was also confirmed by the radical scavenging experiment. The best degradation efficiency of DCF was obtained at pH 8.5. The removal of DCF was enhanced gradually with increasing PAA dose. Since NO3- is a photosensitive substance which can generate HO under UV irradiation, its existence promoted the degradation of DCF. The presence of CO32- could slightly improve DCF degradation, which might be due to the role of generated carbonate radicals. Cl-, SO42- and Fe3+ had little effect on DCF removal, while Cu2+ could enhance DCF degradation because of its catalytic ability for PAA decomposition. An inhibition effect on DCF removal was observed in the presence of DOM, and it was more obvious in higher concentration of DOM. The elimination of total organic carbon (TOC) was low. According to the twelve reaction products detected in the UV/PAA system, the probable transformation mechanism of DCF was proposed exhibiting eight reaction pathways, i.e., hydroxylation, decarboxylation, formylation, dehydrogenation, dechlorination-hydrogenation, dechlorination-cyclization, dechlorination-hydroxylation and amidation. This study indicates that UV/PAA is a promising method for DCF removal from contaminated water.