COCPIT´s ambition is to enhance the SAF production chain by bringing ground-breaking innovations at each thread of it. It aims also to provide investors with a human centred decision tool in a "test before invest" spirit with a high confidence level to de-risk investments. A lipid rich microalgae strain is cultivated in an intensified reactor coupled to semi-transparent photovoltaic panels transforming harmful light spectrum into electrical power. The transformation of algal biomass into SAF is studied using two alternative pathways: The most mature one, HEFA, and a very promising one HTL. The project focuses on the circularity, productivity, sustainability and economic viability of the chain. For HEFA pathway, efficient, low impact and regenerable ionic liquids are used to extract lipids and to catalyse hydrotreatment. For HTL pathway, a continuous reactor, tailored to SAF production from the chosen strain is designed and constructed to reduce clogging issues and to size with higher precision the heat exchangers. Furthermore, the mechanistic models that are developed and used in the design increase the scalability of the HTL. Biocrude upgrading is led to give a high flexibility between SAF and shipping fuel production. The system is designed in a circular way to reduce by-products, feed system with endogenous hydrogen, recirculate nutrients and reduce its water intensiveness. The whole integrated system is simulated with Unism software and all technical, economical, environmental and life cycle indicators are calculated under the COCPIT decision tool and typical scenarios are compiled. The decision tool is delivered within a marketplace that puts at investor’s service a range of required technological solutions, equipment and skills. It helps them also to choose the best technology that fits their project specificities. The ambition of this tool is to continue growing up after the end of the project to include all certified and promising SAF production pathways.

ProFuture will set the basis for market uptake of innovative, healthy and sustainable food and feed products, reformulated with protein-rich ingredients from Spirulina, Lemon/lightly/Chlorella vulgaris, Tetraselmis chuii and Nannochloropsis oceanica. Multi-factors approach and LCA/LCC will boost sustainability of the microalgal biomass production and processing, by reducing energy/water consumption and the carbon footprint. Implementation of innovative technologies will increase the efficiency and decrease the production costs of biomass, ingredients and foods/feeds. Optimized workflows will be tested at pilot plant, as part of a biorefinery process, to produce single-cell proteins and protein isolates, which will be characterized for their nutritional, safety, techno-functional and organoleptic properties as well as for economic viability & sustainability. Food and feed will be formulated with the novel ingredients at pilot plant level in collaboration with SME and large companies. Single-cell proteins will be incorporated in foods (n=6) and feeds (n=5) which will be produced at industrial scale. The food/feed microalgae value chain in EU will be analysed and improvements will be proposed to increase the economic viability and the communication between actors. Social and economic benefits of innovative food and feed products will be demonstrated by: i) supporting the authorization of novel microalgae protein ingredients for food and/or feed applications in the EU, ii) assessing consumer acceptance of and preference for microalgae protein-based products, iii) preparing a successful market implementation and exploitation of the project results and iv) devising a dissemination and communication plan for maximum outreach to all relevant stakeholders. ProFuture consortium (8 RTDs, 16 SMEs, 8 large industries and 1 association) brings together expertise with a clear market orientation to increase the competitiveness of the EU microalgae value chain.

Marine organisms are one of the most underutilized biological resources. The extreme diversity of microalgae, unicellular photosynthetic organisms that are known to produce large quantities of polysaccharides, makes them very attractive for bioprospecting and potential exploitation as commercial sources of exopolysaccharides. Exopolysaccharides from microalgae have been poorly studied compared to those from bacteria, fungi, terrestrial plants or macroalgae. Polysalgue is an interdisciplinary research project with approaches of biochemistry, physico-chemistry, process engineering and microbiology. Its main objective is to increase the level of knowledge about the potential for production of soluble polysaccharides with original structures by microalgae from marine and freshwater environments. It intends to develop the scientific background necessary for the industrial exploitation of these exopolysaccharides as hydrocolloids and/or biological active agents and to evaluate economic and environmental impacts of large scale production.