Abstract
Continuous processing in microreactors represents a novel way for the safe and expedient conduct of high energetic reactions and potentially hazardous chemistry. Apart from handling benefits (such as minimised problems in the scale-up process), reactions in microreactors proceed under precisely controlled conditions providing improved yields and product quality compared to the batch procedure. In this paper, the potential of this technology is exemplarily determined in the crucial nitration of the pharmaceutically relevant intermediate 1-methyl-3-propyl-1H -pyrazole-5-carboxylic acid (1 ). Further fundamental nitration examples demonstrate the unproblematic handling of hazardous H2 SO4 /HNO3 mixtures for the nitration of 2-methylindole (4 ) and pyridine-N -oxide (6 ) or even the explosive acetyl nitrate Ac2 O/HNO3 (nitration of toluene, 8 ) in the continuous reaction mode.
Key words
continuous chemistry - pyrazoles - nitration reactions - microreaction technology - heterocycles
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