Searched for: author%3A%22Koivisto%2C+A.J.%22
(1 - 9 of 9)
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Nymark, P. (author), Bakker, M. (author), Dekkers, S. (author), Franken, R. (author), Fransman, W. (author), García-Bilbao, A. (author), Greco, D. (author), Gulumian, M. (author), Hadrup, N. (author), Halappanavar, S. (author), Hongisto, V. (author), Hougaard, K. (author), Jensen, K. (author), Kohonen, P. (author), Koivisto, A.J. (author), Dal Maso, M. (author), Oosterwijk, T. (author), Poikkimäki, M. (author), Rodriguez-Llopis, I. (author), Stierum, R. (author), Sørli, J.B. (author), Grafström, R. (author)
Advanced material development, including at the nanoscale, comprises costly and complex challenges coupled to ensuring human and environmental safety. Governmental agencies regulating safety have announced interest toward acceptance of safety data generated under the collective term New Approach Methodologies (NAMs), as such technologies...
article 2020
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Kuijpers, E. (author), Pronk, A. (author), Koivisto, A.J. (author), Jensen, K.A. (author), Vermeulen, R. (author), Fransman, W. (author)
article 2020
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Pizzol, L. (author), Hristozov, D. (author), Zabeo, A. (author), Gianpietro, B. (author), Wohlleben, W. (author), Koivisto, A.J. (author), Jensen, K.A. (author), Fransman, W. (author), Stone, V. (author), Marcomini, A. (author)
The increasing use of engineered nanomaterials (ENMs) in nano-enabled products (NEPs) has raised societal concerns about their possible health and ecological implications. To ensure a high level of human and environmental protection it is essential to properly estimate the risks of these new materials and to develop adequate risk management...
article 2019
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Meyer-Plath, A. (author), Koivisto, A.J. (author), Koponen, I.K. (author), Jensen, A.C.Ø. (author), MacCalman, L. (author), Tuinman, I. (author), Fransman, W. (author), Domat, M. (author), Bivolarova, M. (author), van Tongeren, M. (author)
A particle exposure experiment inside a large climate-controlled chamber was conducted. Data on spatial and temporal distribution of nanoscale and fine aerosols in the range of mobility diameters 8-600 nm were collected with high resolution, for sodium chloride, fluorescein sodium, and silica particles. Exposure scenarios studied included...
article 2019
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Kuijpers, E. (author), Pronk, A. (author), Koivisto, A.J. (author), Jensen, K.A. (author), Vermeulen, R. (author), Fransman, W. (author)
Introduction. Knowledge on the exposure characteristics, including release of nanomaterials, is especially needed in the later stages of nano-enabled products’ life cycles to perform better occupational risk assessments. The objective of this study was to assess the concentrations during sawing and drilling in car bumpers containing multi-walled...
article 2019
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Koivisto, A.J. (author), Pizzol, L. (author), Basei, G. (author), Zabeo, A. (author), Mackevica, A. (author), Hansen, S.F. (author), Gosens, I. (author), Cassess, F.R. (author), de Jong, W. (author), Koivisto, A.J. (author), Neubauer, N. (author), Sanchaz, J.A. (author), Semenzin, E. (author), Subramanian, V. (author), Fransman, W. (author), Jensen, K.A. (author), Wohlleben, W. (author), Stone, V. (author), Marcomini, A. (author)
The use of nano-scale copper oxide (CuO) and basic copper carbonate (Cu2(OH)2CO3) in both ionic and micronized wood preservatives has raised concerns about the potential of these substances to cause adverse humans health effects. To address these concerns, we performed quantitative (probabilistic) human health risk assessment (HHRA) along the...
article 2018
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Koivisto, A.J. (author), Kling, K.I. (author), Fonseca, A.S. (author), Brostrøm Bluhme, A. (author), Moreman, M. (author), Yu, M. (author), Costa, A.L. (author), Giovanni, B. (author), Ortelli, S. (author), Fransman, W. (author), Vogel, U. (author), Jensen, K.A. (author)
Nanoscale TiO2 (nTiO2) is manufactured in high volumes and is of potential concern in occupational health. Here, we measured workers exposure levels while ceramic honeycombs were dip coated with liquid photoactive nanoparticle suspension and dried with an air blade. The measured nTiO2 concentration levels were used to assess process specific...
article 2018
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Fonseca, A.S. (author), Kuijpers, E. (author), Kling, K.I. (author), Levin, M. (author), Koivisto, A.J. (author), Nielsen, S.H. (author), Fransman, W. (author), Fedutik, Y. (author), Jensen, K.A. (author), Koponen, I.K. (author)
Fume hoods are one of the most common types of equipment applied to reduce the potential of particle exposure in laboratory environments. A number of previous studies have shown particle release during work with nanomaterials under fume hoods. Here, we assessed laboratory workers’ inhalation exposure during synthesis and handling of CuO, TiO2...
article 2018
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Koivisto, A.J. (author), Aromaa, M. (author), Koponen, I.K. (author), Fransman, W. (author), Jensen, K.A. (author), Mäkelä, J.M. (author), Hämeri, K.J. (author)
Nanoparticle (particles with diameter ≤100 nm) exposure is recognized as a potentially harmful size fraction for pulmonary particle exposure. During nanoparticle synthesis, the number concentrations in the process room may exceed 10 × 106 cm−3. During such conditions, it is essential that the occupants in the room wear highly reliable high...
article 2015
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