Deep vein thrombosis (DVT) is the formation of a blood clot within the deep veins, most commonly those of the lower limbs, causing obstruction of blood flow. In 50% of people with DVT, the clot eventually breaks off and travels to the lung to cause pulmonary embolism. Clinical assessment of DVT is notoriously unreliable because up to 2/3 of DVT episodes are clinically silent and patients are symptom free even when pulmonary embolism has developed. Early diagnosis of DVT is crucial and despite the progress made in ultrasound imaging and plethysmography techniques, there is a need for new methods to enable continuous monitoring DVT diagnosis at the point of care. ThrombUS+ brings together an interdisciplinary team of industrial, technology, regulatory, social science and clinical trial experts to develop a novel wearable diagnostic device for point-of-care, operator free, continuous monitoring in patients with high DVT risk. The device will combine autonomous, AI driven DVT detection based on a novel wearable ultrasound hardware, impedance plethysmography and light reflection rheography for immediate detection of blood clot formation in the lower limb. Activity and other physiological measurements will be used to provide a continuous assessment of DVT risk and support DVT prevention via serious gaming. The aggregated data will drive an intelligence decision support unit that will provide accurate monitoring and alerts. Extended reality will be used to guide experts to design exercises and patients to use the device optimally. ThrombUS+ is intended for use by postoperative patients in the ward, during long surgical operations, cancer patients or otherwise bedridden patients at home or in care units, and women during pregnancy and postpartum. ThrombUS+ will use big data sets for AI training collected in the project via 3 large scale clinical studies and will validate the outcome in the clinical setting via 1 early feasibility study and 1 multi-center clinical trial.

Storage is becoming one of the most critical assets for modern energy systems. At the same time storage is a very diverse universe of solutions and technologies with very different characteristics. InterSTORE plans to address this complexity by developing an innovative middleware that, while virtualising the storage technology, will simplify its use from the point of view of integration platform thanks to a technology agnostic approach.The middleware will facilitate the integration of storage creating an independence from hardware solutions which are critical from customer perspectives to avoid vendor lock-in solutions. It will also facilitate its use from a monetisation perspective making sure that more investments in storage are enabled. InterSTORE middleware will be released as a full open-source product integrating a set of already available standards and protocols in a coherent and advanced architecture.The new InterSTORE solution will be tested and validated in a laboratory environment with the goal to develop testing software to be adopted in the future for interoperability certification. The middleware solution will also be integrated both in open source and commercial platforms that will be integrated in 4 real life demos to enhance the flexibility platforms and analyze the user acceptance and economic value of the new solution. Moreover, new and legacy systems will be taken into account. InterSTORE also has a strong focus towards impact. The solution will become part of existing commercial platforms ensuring that a real adoption will be deployed beyond the end of the project. The consortium will ensure that software maintenance will continue beyond the end of the project with the support of Linux Foundation Energy and that the work done will be considered by on-going standardization activities. SSH experts will perform an impact analysis to maximize the economic impact adopting innovative approaches to data monetization in the context of data spaces.

Interoperability depends on cooperation of multiple domains. While for the energy sector technical interoperability is quite well established, interoperability of functions and businesses needs more attention. Even when standards are defined and interoperability models agreed, framework setters, product developers and users need to agree on their deployment and make sure that solutions are compatible with definitions. The Interoperability Network for the Energy Transition project (IntNET) establishes an open, cross-domain community bringing together all stakeholders relevant for the European energy sector to jointly work on developing, testing and deploying interoperable energy services. The community will be formally established to exist beyond project life-time. With a comprehensive, FAIR knowledge platform and a series of attractive events it guides those who deal with the heterogeneous interoperability landscape of energy services. To support ongoing harmonization of energy services, IntNET will institutionalise an assessment methodology and maturity model (IMM). Involving legal and regulatory bodies from the beginning and constant exchange of interoperability initiatives and standardization bodies will build a deep consensus on how European governance and industry can foster interoperability at all levels. Starting from an extraordinary well balanced and connected consortium of researchers, framework setters (e.g., ministry and EU wide associations), standardisation and communication experts, IntNET’s community approach guarantees wide outreach. IntNET will establish a framework for interoperability testing in ongoing projects and harmonize test procedures in a network of closely cooperating, self-sustained testing facilities. Energy service solutions based on the novel IMM and tested according to the IntNET certification process will be awarded with a widely known quality seal for interoperable smart grid and energy products (working title: “IntNET approved").