Continuous preparation for rifampicin
Tóm tắt
To reduce the cost and improve the efficiency for rifampicin preparation, a continuous flow synthesis of rifampicin starting from rifamycin S and tert-butylamine was studied in a microreactor. Two reaction steps and one purification step were coupled in a microreactor, and rifampicin was obtained with 67% overall yield. This method used 25% less 1-amino-4-methyl piperazine and got 16% higher overall yield without changing solvent and purification process between steps. This method has a good potential for further industrial application.
Tài liệu tham khảo
Maggi CRPN, Ballotta R, Senst P (1966) Rifampicin: a new orally active rifamycin. Chemotherapia 11:8
Anonymous (1973) Analytical profiles of drug substances. Academic Press, New York and London
E. A. Anacleto Gianantonio, U. S. P. Office, Ed. (United States, 1970), vol. US 3542762
Bruzzese T (Holco investment Inc USA, 1979)
Leonardo Marsili CP, U. S. P. Office, Ed. (Current: Gruppo Lepetit SpA ( original: ARCHIFAR IND CHIM TRENTINO), Italy, 1975), vol. US3925366
Leonardo Marsili CP, U. S. P. Office, Ed. (Archifar Industrie Chimiche del Trentina S.p.A., Italy, 1976), vol. 3963705
Burke WJ, Murdock KC, Ec G (1954) Condensation of hydroxyaromatic compounds with formaldehyde and primary aromatic amines. J. Am. Chem. Soc. 76:1677–1679
Burke WJ, Kolbezen MJ, Stephens CW (1952) Condensation of naphthols with formaldehyde and primary amines1. J. Am. Chem. Soc. 74:3601–3605
Burke WJ, Weatherbee C (1950) 3,4-Dihydro-1,3,2H-Benzoxazines. Reaction of polyhydroxybenzenes with N-Methylolamines1. J. Am. Chem. Soc. 72:4691–4694
Burke WJ (1949) 3,4-Dihydro-1,3,2H-Benzoxazines. Reaction of p-substituted phenols with N,N-Dimethylolamines. J. Am. Chem. Soc. 71:609–612
四川抗菌素工业研究所半合成抗菌素研究室, 甲哌力复霉素生产工艺改革, 抗菌素, 1978, 02, 7–13
上海第五制药厂, 甲哌力复霉素合成新工艺——噁嗪路线, 医药工业, 1978, 10, 20–21
Fukang Lu JY, Xiaoyuan Liao (1985) Paper presented at the 第四次全国抗生素学术会议, Guilin, China
Judit Némethné-Sóvágó MB (2014) Microreactors: a new concept for chemical synthesis and technological feasibility. Mater Sci Eng 39:89–101
Makarshin LL, Pai ZP, Parmon VN (2016) Microchannel systems for fine organic synthesis. Russ. Chem Rev 85:139–155
Wang K, Li L, Xie P, Luo G (2017) Liquid-liquid microflow reaction engineering. React Chem Eng 2:611–627
Zhang J, Wang K, Teixeira AR, Jensen KF, Luo G, in Annual review of chemical and biomolecular engineering, Vol 8, J. M. Prausnitz, Ed. (2017), vol. 8, pp. 285–305
Tanimu A, Jaenicke S, Alhooshani K (2017) Heterogeneous catalysis in continuous flow microreactors: a review of methods and applications. Chem. Eng. J. 327:792–821
Mizuno K, Nishiyama Y, Ogaki T, Terao K, Ikeda H, Kakiuchi K (2016) Utilization of microflow reactors to carry out synthetically useful organic photochemical reactions. J Photochem Photobiol C: Photochem Rev 29:107–147
Gordon CP (2018) The renascence of continuous-flow peptide synthesis - an abridged account of solid and solution-based approaches. Org Biomol Chem 16:180–196
Das S, Srivastava VC (2016) Microfluidic-based photocatalytic microreactor for environmental application: a review of fabrication substrates and techniques, and operating parameters. Photochem Photobiol Sci 15:714–730
Ma H, Bai Y, Li J, Chang Y-x (2018) Screening bioactive compounds from natural product and its preparations using capillary electrophoresis. Electrophoresis 39:260–274
Fanelli F, Parisi G, Degennaro L, Luisi R (2017) Contribution of microreactor technology and flow chemistry to the development of green and sustainable synthesis. Beilstein J Org Chem 13:520–542
Sun B, Jiang J, Shi N, Xu W (2016) Application of microfluidics technology in chemical engineering for enhanced safety. Process Saf Prog 35:365–373
Li X, Chen A, Zhou Y, Huang L, Fang Z, Gan H, Guo K (2015) Two-stage flow synthesis of coumarin via O-Acetylation of Salicylaldehyde. J Flow Chem 5:82–86
He W, Fang Z, Tian Q, Shen W, Guo K (2016) Tandem, effective continuous flow process for the epoxidation of cyclohexene. Ind Eng Chem Res 55:1373–1379
Ji D, Fang Z, He W, Zhang K, Luo Z, Wang T, Guo K (2015) Synthesis of soy-polyols using a continuous microflow system and preparation of soy-based polyurethane rigid foams. ACS Sustain Chem Eng 3:1197–1204
He W, Fang Z, Tian Q, Ji D, Zhang K, Guo K (2015) Two-stage continuous flow synthesis of epoxidized fatty acid methyl esters in a micro-flow system. Chem Eng Process 96:39–43
He W, Fang Z, Ji D, Chen K, Wan Z, Li X, Gan H, Tang S, Zhang K, Guo K (2013) Epoxidation of soybean oil by continuous micro-flow system with continuous separation. OrgProcess Res Dev 17:1137–1141
Zhu YDKCaJ (2006) Effects of the medium pH values on rifamycin oxazino cyclic reaction. Chin J Antibiot 31(10):3
Reverchon E, De Marco I, Della Porta G (2002) Rifampicin microparticles production by supercritical antisolvent precipitation. Int J Pharm 243:83–91
Gallo GG, Radaelli P (1976) Rifampin. In: Analytical Profiles of Drug Substances, vol 5. 467–513. https://doi.org/10.1016/S0099-5428(88)60328-7
Vicosa A, Letourneau J-J, Espitalier F, Re MI (2 012) An innovative antisolvent precipitation process as a promising technique to prepare ultrafine rifampicin particles. J Cryst Growth 342:80–87