Steffen Loft

Steffen Loft


Member of:

    From March 2015 to February 2021 Head of Department of Public Health, University of Copenhagen 
    Member of the steering committee for the University of Copenhagen's Center for Sustainability Science
    Until 2015
    Head of Section of Environmental Health, Department of Public Health, University of Copenhagen
    Until 2015
    Member of the Academic Council of the Faculty of Health Sciences, University of Copenhagen
    Until 2014
    Vice Chairman of the Board of the National Research Centre for the Working

    Primary fields of research

    Steffen Loft is worldly recognised for research in the fields of health effects of particles, molecular epidemiology and oxidative DNA damage and repair. 

    The particle research comprises exposure and effects of outdoor and indoor air pollution as well as engineered, including medical, nanoparticles. The work spans the entire hierarchy of techniques from experimental models; from synthetic membranes, organotypic cell cultures and transgenic animals, the use of biomarkers and functional measures populations with controlled exposure and interventions, to register-based epidemiology at the aggregate level. There is particular attention on mechanisms associated with oxidative stress-related genotoxic and vascular effects and risk groups of genetically susceptible, foetuses, children and elderly people with and without diabetes and / or obesity and regulation of defence mechanisms such as DNA repair.

    The molecular epidemiology development include measures of internal dose of environmental factors, effects in the form of oxidative and chemical stress, the cellular response in the form of gene expression patterns, resulting DNA damage and related repair capacity, genetic susceptibility and cardiovascular function. Biomarkers of exposure and effects are applied in vulnerable populations and validated by the predictive value in relation to disease development in large cohorts.

    Major recent research achievements include demonstration of effects of nanoparticles on oxidative damage to DNA and vascular functions both in susceptible transgenic animal models and in humans, and that a number of biomarkers of exposure can predict risk of cancer in prospective settings.

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