Mold spore exposure indoor have been suggested as a possible explanation for airway problems such as asthma and allergy among people living in buildings with moisture-related problems. However, this investigation could not find any associations between the spore concentrations in indoor air and signs of dampness and moldy odor reported by parents or observed by professional inspectors. Neither was there any association between the indoor spore concentration and asthma/allergy among children. With these results, there is no reason for one-time air sampling of mold colony-forming unit (CFU) in indoor air of homes to identify risk factors for asthma/allergy in children living in Scandinavian countries.
PurposeIn Norway the most critical effects of climate change are predicted to be increased rain and snow, higher temperatures, increased wind loads, and sea‐level rise. This will increase the number of floods and landslides, along with more cycles around the freezing point and increased exposure to high moisture. The main issue for protecting Norway's historical monuments from climate change is how to be aware of and how to handle the coming problems. One challenge is to define and give this information to heritage owners and local authorities. The purpose of this paper is to describe some of the practical threats related to climate change, and provide suggestions for mitigation and adaption strategies.Design/methodology/approachTheoretical information of the problem is useful at a general level, but the practical impact has to be used at a local level. Improved knowledge about the risks for deterioration at different exposure levels, thorough surveys, and practical solutions, can significantly reduce the negative effects. This knowledge must reach the people that have local and daily contact with the cultural heritage. Information to the owners and responsible authorities about the normal risk of deterioration and how to identify risks related to climate change is crucial.FindingsThe main results of the authors' work is a methodology dealing with the problem step‐by‐step production of a web‐site based on fact sheets for heritage owners and managers. The fact sheets are divided amongst different subjects and are designed to be informative and easy to use for owners and responsible authorities.Originality/valueThe results presented in this paper will increase the knowledge of how owners of cultural heritage can be prepared for climate change on a practical, hands‐on level. This can, for example, be done by a brief overall analysis of the threats of the cultural heritage in a specific municipality. The analysis can be summarised in a list of increased possible risks, with direct practical information given to those needing it, and placed online. This would enable detection of and reaction to warning signs of an unusual situation. Information, training and production of both general and specific plans for action in case of extreme situations are also important in order to prevent the negative effects of climate change.
Background Children spend considerable time in daycare centers in parts of the world and are exposed to the indoor micro- and mycobiomes of these facilities. The level of exposure to microorganisms varies within and between buildings, depending on occupancy, climate, and season. In order to evaluate indoor air quality, and the effect of usage and seasonality, we investigated the spatiotemporal variation in the indoor mycobiomes of two daycare centers. We collected dust samples from different rooms throughout a year and analyzed their mycobiomes using DNA metabarcoding. Results The fungal community composition in rooms with limited occupancy (auxiliary rooms) was similar to the outdoor samples, and clearly different from the rooms with higher occupancy (main rooms). The main rooms had higher abundance of Ascomycota, while the auxiliary rooms contained comparably more Basidiomycota. We observed a strong seasonal pattern in the mycobiome composition, mainly structured by the outdoor climate. Most markedly, basidiomycetes of the orders Agaricales and Polyporales, mainly reflecting typical outdoor fungi, were more abundant during summer and fall. In contrast, ascomycetes of the orders Saccharomycetales and Capnodiales were dominant during winter and spring. Conclusions Our findings provide clear evidences that the indoor mycobiomes in daycare centers are structured by occupancy as well as outdoor seasonality. We conclude that the temporal variability should be accounted for in indoor mycobiome studies and in the evaluation of indoor air quality of buildings.
This paper emphasises on degradation of wood in cultural heritage structures at Svalbard. Nowhere else does global heating occur faster. Negative impacts of climate change will increase the strain on wooden structures and can daily be observed at Svalbard. The severe changes affect the degradation rate of wooden constructions, including cultural heritage. Certain microclimates, also in Polar areas, are favourable to fungal growth and decay. The probable enhancing effects climate change have on fungal degradation in wooden structures are however alarming. The paper displays findings of measurements from four different case study projects at Svalbard between 2009 and 2019. The results have been analysed separately, compiled and discussed in context, and towards relevant literature. We claim that impacts of climate change may not be generalized in order to predict effects in building materials. Further, that with extended knowledge on how climate change affects natural development of fungal decay, negative impacts may be reduced. Lessons learned from high Arctic areas might add longevity and sustainability to wooden cultural heritage constructions, also in different areas and environments. The paper is part of two of the authors' PhD work at the Norwegian University of Science and Technology.
Haptics is an emerging technology that allows touch‐enabled interaction with virtual objects. Analogous to the use of computer graphics for rendering of a three‐dimensional (3D) scene to give the user a visual description of the scene, it is possible to use computer haptics to let the user touch objects in the 3D scene. This is normally accomplished by having the haptics engine sending either force vectors or positional information to a haptics device, a robotic arm, that the user manipulates. The purpose of this paper is to give an overview of this technology, describe haptic devices and haptic application programming interfaces. We will also illustrate the use of haptics technology by describing a few industrial and medical applications.
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