“…Fine chemical industries and organic synthesis research laboratories are facing a digital revolution that is going to profoundly modify the way chemists think and perform chemical transformations. − Chemistry 4.0, which has been coined to define the chemistry of the fourth industrial revolution, massively takes advantage of integrated information technology systems, algorithms, and automated machines to reinvent the concepts of synthesis and production established after the Second World War. − Both research laboratories and multipurpose plants 4.0 will be miniaturized, highly modular, (semi)autonomous, and connected, increasing safety and sustainability (smaller size) and reducing cost (modularity and autonomy). − To reach the objectives of Chemistry 4.0, chemical synthesis will mainly operate in continuous-flow mode as this technology offers enhanced safety, better reaction control, on-the-fly monitoring, and easier automation compared to traditional batch reactors. ,− Moreover, from a more fundamental point of view, flow chemistry offers the possibility to access “forbidden” transformations as it allows one to explore new process windows and also strongly accelerates kinetics through improved heat and mass transfer. , Critical to the control of continuous processes is the efficient monitoring of process parameters and product quality by process analytical technology (PAT) . At the initiative of the United States Food and Drug Administration (USFDA), PAT was initially introduced in the pharmaceutical industry to enhance and control manufacturing processes with the aim of achieving quality by design (QbD).…”