10133-88-7Relevant articles and documents
A facile and green synthesis of novel imide and amidic acid derivatives of phenacetin as potential analgesic and anti-pyretic agents
Reddy, Yervala D.,Kumar, Padam P.,Devi, Bhoomireddy R.,Dubey, Pramod K.,Kumari, Yalamanchili B.
, p. 70 - 76 (2013/07/26)
Facile and green syntheses of potential analgesic and antipyretic compounds, N-(4-ethoxy-phenyl)-2-(1,3- dioxo-1,3-dihydroisoindol-2-yl)acetamide derivatives 6a-g and N-[(4-ethoxy-phenylcarbamoyl)methyl]phthalamic acid derivatives 10a-g have been developed. Two synthetic routes (A and B) have been established for the preparation of 6a-g. In the route-A, 4-ethoxyaniline 2 was reacted with chloroacetyl chloride 3 in a solution of potassium acetate and acetic acid to yield N-(4-ethoxyphenyl)-2-chloroacetamide 4. The latter was reacted with imide compounds 5a-g either in triethanolamine as a green solvent or in solid phase in the presence of TEBAC and KI to yield 6a-g. Alternatively, in the route-B, reaction of anhydrides 7a-g with glycine 8 yielded the (1, 3-dioxo-1, 3-dihydroisoindol-2-yl)acetic acid derivatives 9a-g which on reaction with 2 either in triethnolamine and DCC as a dehydrating agent or in solid phase in the presence of DCC gave 6a-g. The latter were hydrolyzed in 0.5N ethanolic KOH to afford 10a-g.
Synthesis and screening of cyclooxygenase inhibitory activity of some 1,3-dioxoisoindoline derivatives
Cizmecioglu, Murat,Pabuccuoglu, Varol,Ballar, Petek,Pabuccuoglu, Aysun,Soyer, Zeynep
experimental part, p. 186 - 190 (2011/10/10)
In this study, 15 compounds bearing N,Nphthaloylacetamide structure designed by the molecular simplification approach based on thalidomide structure were synthesized and evaluated for inhibitory potencies against cyclooxgenase (COX) isoenzymes, namely COX-1 and COX-2. The results suggested that the N,Nphthaloylacetamide structure, as a primary amide, has inhibitory activity against cyclooxygenase isoenzymes with a higher COX-1 selectivity. The conversion of the primary amide to secondary or tertiary derivatives lowered the potency but favored the COX-2 selectivity thus yielding the compounds with stronger COX-2 inhibiting activity. ECV · Editio Cantor Verlag.
Preparation and physicochemical characterization of a novel water-soluble prodrug of carbamazepine
Hemenway, Jeffrey N.,Jarho, Pekka,Henri, John T.,Nair, Sajiv K.,Vandervelde, David,Georg, Gunda I.,Stella, Valentino J.
experimental part, p. 1810 - 1825 (2011/03/21)
N-Acyl-urea derivatives of carbamazepine (CBZ) were synthesized through the reactions of iminostilbene with acyl-isocyanates to form N-glycyl-carbamazepine (N-Gly-CBZ, after a deprotection step) or N-acetyl-carbamazepine (N-acetyl-CBZ). N-Gly-CBZ was isolated as its water-soluble HCl salt and was designed to act as a prodrug and convert to CBZ and glycine in vivo by enzymatic cleavage of the acyl-urea bond. The stability pH-rate profiles for N-Gly-CBZ and N-acetyl-CBZ were determined. The stability of N-Gly-CBZ was found to range over four orders of magnitude with its greatest stability at pH 3-4 and a t 90 value of 5.9 day at pH 4 at 25°C. From the fit of the pH rate profile two pKa values were estimated to be 7.2 (terminal amine) and 10.0 (imide), which were independently verified using UV-visible spectroscopic analysis. The solubility of N-Gly-CBZ in aqueous solution was determined in the range of pH 5.5-7.5. The intrinsic solubility of the neutral form of the prodrug was found to be 4.4 mg/mL, and the solubility of the prodrug increased exponentially (log linear) as pH was decreased below its pKa1 value. N-Gly-CBZ was found to have an aqueous solubility in excess of 50 mg/mL at pH 4. The presence of N-Gly-CBZ was found to increase the aqueous solubility of CBZ, a degradation product. CBZ showed an 8.6-fold greater solubility in an aqueous solution containing 23 mg/mL of N-Gly-CBZ than in water alone. The solubilization of CBZ by N-Gly-CBZ was investigated by examining the diffusion coefficients of the predominant species in D2O and was found to be more consistent with stacking complex formation than micelle formation. The stability ofN-Gly-CBZ makes a ready-to-use parenteral formulation impractical, but a freeze-dried preparation for reconstitution appears to be feasible.