10238-28-5Relevant articles and documents
Total Synthesis of Glipizide and Glibenclamide in Continuous Flow
Sagandira, Cloudius R.,Khasipo, Agnes Z.,Watts, Paul
, p. 16028 - 16035 (2021/10/14)
Glipizide and glibenclamide remain some of the widely prescribed antidiabetic sulfonylurea drugs for the treatment of type 2 diabetes mellitus. Herein the authors report on an isocyanate-free synthetic procedure towards the preparation of these on demand drugs at multigram scale using continuous flow technology. The safety concern over the use of isocyanates in most of the existing synthetic routes was dealt with in this present work by using N-carbamates synthesised in situ from activation of amines with chloroformates as safer alternatives. An overall yield of 80–85 % was obtained for the semi-telescoped steps within 10 min total residence time.
Synthesis technology of glibenclamide
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Paragraph 0048; 0049; 0050; 0051, (2017/08/25)
The invention provides a novel synthesis technology of a glibenclamide bulk pharmaceuticals. The glibenclamide product is finally prepared by taking sulfamide as a starting raw material through the four steps of a secondary condensation reaction, a compounding reaction, a dealcoholization reaction and refining. The technology has the advantages of being high in yield, low in purity, easy and convenient to operate, suitable for industrialized production and the like.
Design and Performance Validation of a Conductively Heated Sealed-Vessel Reactor for Organic Synthesis
Obermayer, David,Znidar, Desiree,Glotz, Gabriel,Stadler, Alexander,Dallinger, Doris,Oliver Kappe
, p. 11788 - 11801 (2016/12/09)
A newly designed robust and safe laboratory scale reactor for syntheses under sealed-vessel conditions at 250 °C maximum temperature and 20 bar maximum pressure is presented. The reactor employs conductive heating of a sealed glass vessel via a stainless steel heating jacket and implements both online temperature and pressure monitoring in addition to magnetic stirring. Reactions are performed in 10 mL borosilicate vials that are sealed with a silicone cap and Teflon septum and allow syntheses to be performed on a 2-6 mL scale. This conductively heated reactor is compared to a standard single-mode sealed-vessel microwave instrument with respect to heating and cooling performance, stirring efficiency, and temperature and pressure control. Importantly, comparison of the reaction outcome for a number of different synthetic transformations performed side by side in the new device and a standard microwave reactor suggest that results obtained using microwave conditions can be readily mimicked in the operationally much simpler and smaller conventionally heated device.
