TexMaTer aims at producing novel cellulosic fibres and bioformulations for textiles’ finishing using under-utilised biomass resources and wastes from agricultural practices and micro- and macroalgal production (typically rich in cellulose and other bioactive compounds) and post-consumer home textiles (as an extra source of cellulose). These functional and sustainable solutions will be further used in prototypes for fashion and home textiles’ markets. The project covers all steps required to produce novel cellulosic fibres and functional textiles for the envisaged markets: from the obtention and transformation of raw materials for application in textile production processes, to fibres/yarns production and bioformulations development (at laboratory, pilot and industrial scales), ending with eco-design and prototypes manufacture. To ensure recyclability and circularity of the developed solutions, and an efficient uptake of the products by the consumer, the development of TexMaTer products will be designed considering promising End-of-Life (EoL) alternatives and also functionality, safety, environmental sustainability and social and economic benefits for consumers. Consumer behaviour studies and raising-awareness actions are also planned, thus contributing to increase consumers’ acceptance for the developed products. By incorporating bio-based resources and promoting the upcycling of post-consumer textiles, TexMaTer will increase the competitiveness of the textile & clothing industry (T&CI), significantly reducing the negative environmental impacts commonly associated to this sector: 1) the intensive use of synthetic fibres, virgin cotton and wood-based cellulose (whose production is responsible for high CO2 emissions, water consumption and contamination, and inappropriate forest management, respectively); and 2) the overutilisation of synthetic dyes and chemicals in textile finishing processes (which are typically rejected in textile wastewaters and recalcitrant).

Polyurethane (PUR) products, which include foams for building, construction, automotive and furniture and bedding, are petroleum-based and usually lack important properties. The need for sustainability in these industries leads to the development of cost-efficient processes and sustainable added-value products from low carbon footprint materials. The main objective of BIOMAT is to establish an Open Innovation Test Bed (TB) for the benefit of industries and SMEs, aiming to facilitate the cross-border partnership and accelerate innovation in nano-enabled bio-based insulation materials for these industries. Through the creation of a Single-Entry Point (SEP), SMEs and other industrial parties will have open access at a competitive price to physical facilities (pilot production lines) and services (characterisation, nanosafety, standardisation/regulation, business/marketing plans as well as technological and business-oriented mentoring) which will be focused on manufacturing and testing of nanoparticle-enabled functional PUR-based foams for the above mentioned industrial sectors. The SEP will follow all EC guidelines related to the establishment of new entities providing services through different testbeds across Europe. BIOMAT ecosystem will cover the entire Value Chain (VC) from fundamental biomaterials and functional nanoparticles to the final products and their proof of concept in an industrial environment, thus accelerating the market uptake of the new nano-enabled sustainable bio-based products. BIOMAT will, therefore, fill the existing gaps in the VC of these industrial sectors, by providing new services and support at different levels the use of such materials in these key industries.

Although previous EU funded projects have defined tools and concepts to ensure safety of nano-enabled products through design, many hurdles still hinder the implementation of these procedures in real production processes. ASINA will use the production value chains (VCs) of two representative categories of nano-enabled products (NEPs): coatings in environmental (clean) nanotechnology and nano-encapsulating systems in cosmetics, to formulate design hypothesis and make design decisions by applying a data-driven approach and methodology (the “ASINA-SMM”). Molded on industrial six sigma practices, the ASINA-SMM can be easily adopted by manufactures to deliver NEPs designed to be as safe as possible, so achieving ASINA vision to increase stakeholders (entrepreneurs, scientists, regulators, innovators, policy makers, consumers) confidence in SbD nanomanufacturing. The methodology encompasses distinct phases that ASINA will follow to deliver SbD solutions and supporting tools, at TRL6: define NEP, its intended use, production technologies and known quality, safety and cost requirements; measure performance attributes (techno-economic features, hazard and exposure potential along the entire life cycle) in relation to material (M) and process (P) design options; analyse data gathered from internal and external sources and derive/combine response functions, to identify the best compromise between possible design options; design new versions of the product/process that minimise risk, maximising performance; establish a pilot action to verify the capacity of ASINA-SMM to deliver practical, relevant, reliable and reproducible M- or P-SbD solutions. By its end, ASINA will provide a roadmap to generalise ASINA-SMM, and maximizing the positive impacts of further products, designed to improve environmental quality and human health/wellness, offering the transparency required to promote consumer acceptance and, as a consequence, the growth of reference industrial sectors.

SYMSITES?s main objective is to implement regional industrial urban symbiosis in four European regions different in social economic, and environment aspects, from the north Denmark, through the mid Austria to the south Spain and Greece. The four EcoSites will use the same technologies for wastewater and waste treatment and energy production and cycling, enabling a clean comparison of the EcoSite impacts. The four EcoSites will generate virtuous circles of energy, treated waste and wastewater streams between urban and industrial entities. The enabling technologies to be developed for waste and wastewater (WW) co-treatment, are: a newly developed IT Regional Management platform (ITRMP) including novel IIoTs and Social Decision support System (SDSS) to manage efficiently the I-U symbiosis; an anaerobic bioreactor(AnMBR) with advanced membrane coupled with a tertiary treatment, to be installed at the four EcoSites for a clean comparison of all impacts not directly influenced by different technologies. The aim is A) to achieve near-zero GHG emissions or CO2 negative footprint; B) use of bio-waste and non-recyclable wastes (NRW) to produce energy and reusable water as well as high-value new resources (HVNR), thus reducing the waste generation by ~50%; LCA and LCC studies and the quantity prevented from transportation (Ton-Kilometer units) and from landfilling (Ton/m3 units) will evaluate the costs and environmental impact. Dedicated tools will be developed to spread he I-US concept within Europe. These include: virtual demonstration of replication potential in other regions by setting up a network amongst waste associations ' facilitation services for implementing symbiotic processes; actions to facilitate relations and to involve the local community actors and establishment of a social innovation non profit spin-off involving tools and business models for streams exchange in a dynamic production.

In line with the current guidelines for Safe and Sustainable by Design (SSbD) chemicals and materials, INTEGRANO proposes a general assessment approach based on quantitative evidence to be applied in practice for specific Nano Materials (NMs) design cases referred to inorganic, organic and carbon NMs. The development NMs dedicated novel impact categories (ICs) for nano-toxicity and eco-nano-toxicity assessment will enable the integrated application of standardised assessment methodologies. The following four NMs Life Cycle Stages (LCS) are addressed: synthesis, incorporation, use phase and end-of-life. The application of the stage-gate SSbD process through the LCS addresses performance in the five dimensions (5D s): Safety, Environmental, Economic, Social and Functional. Generation of dedicated response functions will allow associating Key Decision Factors (KDFs, such as: concentrations, processing parameters, etc.) to Key Performance Indicators (KPIs, such as: occupational safety, CO2 emissions, job creation potential, NM cost, antibacterial functionality, etc.). SSbD NMs solutions will be obtained by Multi Objective Optimisation Design (MOOD) dedicated algorithm. A dedicated digital Decision Support Toolbox (DST) will elaborate design case specific data and run MOOD algorithm to sort the set of multi-optimal SSbD options, which are simultaneously complying with all the targeted KPIs referred to the 5Ds. The digital supported decision process will help scientists, material engineers, Nano-Enabled Products (NEPs) designers, policymakers and decision-makers to takle the SSbD challenge, allowing for dramatic reduction of Research & Development (RTD) and approval lead-time as well as minimising costs and increasing the transparency of the data, by making the industrial uptake of nanotechnologies more sustainable and viable. INTEGRANO allows the integration with other existing SSbD frameworks by transposing results into other scoring metrics and enabling data exchange.