Pharmaceuticals have undoubtably made our world a better place, ensuring longer and healthier lives. However, pharmaceuticals and their active metabolites are rapidly emerging environmental toxicants. It is thus critical that we fully understand, and mitigate where nec-essary, the environmental impact resulting from their production, use and disposal. In this direction, ENVIROMED addresses two aspects of the environmental impact of pharmaceuticals, a) impact of the processes in manufacturing the compound, and b) impact of the compound itself, during its lifecycle. The project narrows the knowledge gap when it comes to the effect of pharmaceutical compounds, and their derivatives, in the environment as it enables the better understanding the environmental impact of such compounds, throughout their lifecycle. It aims to offer (via extensive monitoring campaigns & scientific studies) information regarding occurrence of pharmaceuticals in the environment, their persistence, environmental fate, and toxicity (via in-vitro & in-vivo models) as well as application of in-silico methods to provide information about the basic risk management and fate prediction in the environment. Brief ideas about toxicity endpoints, available ecotoxicity databases, and expert systems employed for rapid toxicity predictions of ecotoxicity of pharmaceuticals will also be taken into account, in order to have a comprehensive approach to pharmaceuticals' Lifecycle Assessment (LCA). Moreover, the project aims at developing a set of technologies that enable greener and overall, more efficient pharmaceuticals production, which include: a) Green-by-design in-silico drug development; b) Novel sensing to allow reduction of rinsing chemicals and cycles; c) a robust Continuous Biomanufacturing line (CBM), which makes use of AI-enabled process optimisation and prediction, using data assimilation based on chemical sensing and energy disaggregation/monitoring. Training activities and a robust exploitation

Chemistry is a key underpinning science for solving many global problems. The ability to make any molecule or material, in any quantity needed in a prescribed timescale, and in a sustainable way, is important for the discovery and supply of new medicines to cure diseases, agrochemicals for better crop yields/protection, as well as new electronic and smart materials to improve our daily lives. Traditionally, synthetic chemistry is performed manually in conventional glassware. This approach is becoming increasingly inadequate to keep pace with the demand for greater accuracy and reproducibility of reactions, needed to support further discovery and development, including scaling up processes for manufacturing. The future of synthetic chemistry will require the wider adoption of automated (or autonomous) reaction platforms to perform reactions, with full capture of reaction conditions and outcomes. The data generated will be valuable for the development of better reactions and better predictive tools that will facilitate faster translation to industrial applications. The chemical and pharmaceutical industry is a significant provider of jobs and creator of wealth for the UK. Data from the Chemical Industries Association (CIA) shows that the chemical industry has a total turnover of £40B, adding £14.4B of value to the UK economy every year, employs 140,000 people directly, and supports a further 0.5M jobs. The sector is highly innovation-intensive: much of its annual spend of £4B on investment in capital and R&D is based on synthetic chemistry with many SME's and CRO's establishing novel markets in Science Parks across the UK regions, particularly in the South East and North West. The demand for graduate recruits by the Chemicals and Pharmaceutical industries for the period 2015-2025 is projected to be between 50,000-77,000, driven by an aging workforce creating significant volumes of replacement jobs, augmented by the need to address skills shortages in key enabling technologies, particularly automation and data skills. This CDT will provide a new generation of molecular scientists that are conversant with the practical skills, associated data science and digital technology to acquire, analyse and utilise large data sets in their daily work. This will be achieved by incorporating cross-disciplinary skills from engineering, as well as computing, statistics, and informatics into chemistry graduate programs, which are largely lacking from existing doctoral training in synthetic chemistry. Capitalising upon significant strategic infrastructural and capital investment on cutting edge technology at Imperial College London made in recent years, this CDT also attracts very significant inputs from industrial partners, as well as Centres of Excellence in the US and Europe, to deliver a unique multi-faceted training programme to improve the skills, employability and productivity of the graduates for future academic and industrial roles.