Kristin Erkman

To sustain life and its quality on Earth, the EU has established several initiatives for the implementation of the Green Deal: Zero Pollution Action Plan, Farm to Fork and Green Deal Industrial Plan, among many others. All of these require significant innovation, based on new knowledge and skills – research, training and education – coupled with industry adaptation, civil society engagement and smart regulation, which is a challenge globally. More importantly, we need significantly more people who can carry out this innovation. The main objective of “Innovative Chemistry and Biotechnology for a Sustainable Future” (INNOCHEMBIO) is to train future experts of sustainable chemistry and biotechnology, helping Europe to take the next steps in the green transition. The solutions and trained experts can reduce the environmental impact of the chemical and agricultural industries, offer eco-friendly analytical techniques, and assess the safety of new materials. This will be achieved through interdisciplinary research projects in an international research environment, collaboration with the industry, the public sector and the civil society, via a comprehensive quadruple-helix based training programme. As a result, our graduates will not only become experts in their respective fields, but leaders and spokespersons. Eventually, through dedicated career planning, we provide skilled workforce to all 4 sectors of the helix. INNOCHEMBIO is an international consortium led by TalTech, with over 100 years of experience in chemistry and biotechnology research and training. INNOCHEMBIO will achieve its objectives by recruiting 15 PhD candidates in up to two calls offering fellowships for 48 months. During this period, the candidates will receive discipline specific training both in Estonia and abroad by working on their research project; broader training through courses offered at TalTech and by our partners; and experience working in the private sector.

The environmental impact of the pharmaceutical industry is a huge problem. The production and use of pharmaceuticals cause high CO2 emissions, contamination of soils, biota, and water, and even dangers to human health through carcinogenic impurities. Especially the use of solvents is a major problem. The European Green Deal has led to strict regulations on environmental pollution by the pharma industry, causing manufacturers to move outside of the EU due to the high costs associated with green pharma. This results in supply chain fragility and low crisis preparedness in Europe. New methods to produce pharmaceuticals in a green, efficient, and economically friendly way are required. The IMPACTIVE project brings together the expertise and knowledge from two COST Actions and will develop novel green methods to produce active pharmaceutical ingredients (APIs) using mechanochemistry as a disruptive technology (as acknowledged by IUPAC). Mechanochemistry uses mechanical processes, such as ball milling, twin-screw extrusion, resonant acoustic mixing, and spray drying, to induce chemical reactions. The advantages of mechanochemistry include: no solvent use, high efficiency, low costs, and reduced energy use and CO2 emission. Upon completion of the project, we will provide proof-of-concept at a small pilot scale of the use of mechanochemistry to produce 6 APIs from 3 different families of compounds. Based on a recent study, switching to mechanochemistry can reduce terrestrial ecotoxicity and CO2 emissions by more than 85%, while production costs were reduced with 12%. The results of the IMPACTIVE project will thus enable pharmaceutical manufacturers to move back to Europe while minimizing environmental pollution.Through our strong dissemination and communication strategy we will ensure that the project´s results are shared with scientists, the pharmaceutical industry, and stakeholders from regulatory and public authorities to achieve maximum impact.

The project deals with the development of sustainable methods of asymmetric catalysis and their application in the synthesis of biologically relevant compounds. Various methods of catalysis (organo-, metal- and enzymatic catalysis) will be used separately or in cooperative manner. Special attention will be turned to the increase of efficiency of reactions by using selective catalysts, cascade or one-pot reactions. As a new method, a halogen bond donor catalyzed asymmetric reactions will be studied. New reactions will be applied on the synthesis of biologically active compounds and their derivatives. As a result, new asymmetric catalytic sustainable methods for the creating molecular complexity will be developed. Principles of green chemistry will take root in science, in the mode of thinking of PhD students and by PhD graduates in Estonian chemistry enterprises.