Research projects 98

  • Head of research Kai Savolainen
  • Language n/a

NANOSOLUTIONS seeks to identify and elaborate the characteristics of engineered nanomaterials (ENM) that determine their biological hazard potential. It will help develop a safety classification model for ENM based on an understanding of their interactions with living organisms, benefiting industry and enabling innovation.The NANOSOLUTIONS project was created to develop a safety classification for engineered nanomaterials (ENM) based on an understanding of their interactions with living organisms at molecular, cellular and organism levels. The human body uses natural nanomaterials, such as proteins and other molecules, to control the body�s many systems and processes.

Team

Dario Greco, Harri Alenius, Riitta Lahesmaa, Roland Grafström, Kai Savolainen

I4Future - Imaging for the Future: Novel Imaging and Characterization Methods in Bio, Medical and Environmental Research and Technology Innovations is a Marie Sklodowska-Curie action co-funded international, interdisciplinary and inter-sectoral doctoral programme. The programme brings together complementary and supplementary expertise of internationally accredited researchers with the aim of training young researchers in an interdisciplinary manner in highly relevant sosioeconomic research areas using state-of-the-art techniques. The programme network consists of 17 University of Oulu research groups, 10 international partner universities, 11 private companies and 4 multidisciplinary public sector organisations.

Team

Marko Huttula, Matti Alatalo, Erkki Thuneberg, Nonne Prisle

VitalSens is a joint research project with the main goal of designing a smart, cost effective and scale-able personalized biomedical remote monitoring health platform. Printable wireless electronic sensors for continuous ECG monitoring are designed. Further, the ECG recordings are stored in a cloud storage. We then proceed by developing a computational engine which processes the physiological measurements and provide automated event detection for cardiovascular diseases (CVDs). The primary focus is to create an intelligent processing system which is adaptive to the patient ECG recording.

Team

Sampo Nurmentaus, Metropolia UAS, Moncef Gabbouj, TUT, Tapio Seppänen, OU, Niku Oksala, UTA.

Biomedical Robotics and Applications (BioRA) focused on the staff exchange between the partners of EU and China, and on the development of new technologies and applications in the field of biomedical robotics on the macro, micro and nano scales for biological cell detection, manipulation, test and injection. It met the objectives and requirements of the Marie Curie Action: International Research Staff Exchange Scheme (IRSES), by setting up multiple bridges between European and Chinese institutions.

Team

Pasi Kallio, Koivikko Anastasia, Seriola Veikko

Novel materials and fabrication methods for body-centric passive wireless sensors (NOSE), is a project that is coordinated at the Tampere University of Technology, by the wireless identification and sensing systems research group (WISE). In this research project, embroidery of conductive yarns and 3D direct write dispensing of novel conductive materials; graphene, copper, and stretchable silver inks, as well as protective coatings, are used to fabricate flexible and reliable antennas and interconnections embedded into textile materials.

Team

Johanna Virkki, Leena Ukkonen, Han He, H Lam, Xiochen Chen

The international research project "Making the International Trade System for Climate Change" examines possible synergy effects between the international trade and climate regime. The focus is on how trade policy measures (WTO, free trade agreements, etc.) can support a more ambitious climate policy in the future. The project includes a first analysis of the impact of the Paris Climate Agreement on the relationship between international trade and climate policy.

Team

Harro van Asselt, Kasturi Das, Susanne Droege, Michael Mehling

The EXTREME project will be analysing and comparing the sensitivity of ecosystem functioning in desert shrubs or steppes and managed boreal forest ecosystems to the foreseen climate change, climatic variability and weather extremes, with implications for carbon sequestration and biomass production of ecosystems. The project will carry out both experimental and model-based analyses at various temporal and spatial scales. The project is expected to generate new knowledge of how carbon sequestration and biomass production of the most sensitive ecosystems response to climate change scenarios.

Team

Peltola Heli, Kellomäki Seppo, Tianshan Zha

COST Action FP1405 - ActInPak is an international project implemented mainly to identify and focus on the key technical, social, economic and legislative factors relevant for a successful deployment of renewable fibre-based functional packaging solutions. The main objective of ActInPak is to develop a knowledge-based network on sustainable, active and intelligent fibre-based packaging in order to overcome current technological, industrial, and social limitations that hinder the wide deployment of existing and newly developed solutions in market applications.

Team

Johanna Lahti, Mika Vähä-Nissi FATIMA BOUCHAMA, JULIEN BRAS, SANNE TIEKSTRA, SELCUK YILDIRIM, GREG GANCZEWSKI, DAVID RAVNJAK, TADEJA MUCK, MARCO GIACINTI, JOHANNES BERGMAIR, VICTORIA HEINRICH, DIANA GREGOR SVETEC

The objective of Finland's national bioeconomy strategy is to facilitate economic growth and to create new jobs in bioeconomy-based business. Next to technological knowhow and willingness to innovate, firms aspiring to transition to more sustainable materials and technologies need the ability to identify new business opportunities. Courage and commitment to persevere in seizing these uncertain opportunities, and tolerating the uncertainty and the possibility of failure in pursuing them, are equally important. Therefore, the decision to transition to the bioeconomy involves both rational and emotional elements.

Team

Teemu Kautonen Aalto University, Henri Hakala, University of Vaasa, Katariina Salmela-Aro, University of Jyväskylä

The goals of the SPEVINDS project were: 1)Conducting fundamental research and 2) Generating industrial applications and prototyping. Basic research was conducted around the topic of how to pack and save spectral images most effectively, involving, for example, the types of files that need to be developed. A key aspect of the project is naturally how the basic research findings can be applied in practice and how they can be used to generate business

Team

Markku Hauta-Kasari, Juha Purmonen