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1. Spatial clusters of Varroa destructor control strategies in Europe

Author

Brodschneider, Robert, Schlagbauer, Johannes, Arakelyan, Iliyana, Ballis, Alexis, Brus, Jan, Brusbardis, Valters, Cadahía, Luis, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, da Costa, Cristina Amaro, Danneels, Ellen, Danihlík, Jiří, Dobrescu, Constantin, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gregorc, Aleš, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Mazur, Ewa, Mutinelli, Franco, Patalano, Solenn, Raudmets, Aivar, Simon Delso, Noa, Stevanovic, Jevrosima, Uzunov, Aleksandar, Vejsnæs, Flemming, Williams, Anthony, and Gray, Alison

Published
2023
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2. Honey bee colony loss rates in 37 countries using the COLOSS survey for winter 2019–2020: the combined effects of operation size, migration and queen replacement

Author

Gray, Alison, Adjlane, Noureddine, Arab, Alireza, Ballis, Alexis, Brusbardis, Valters, Bugeja Douglas, Adrian, Cadahía, Luis, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, Costa, Cristina Amaro da, Danneels, Ellen, Danihlík, Jiří, Dobrescu, Constantin, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gregorc, Aleš, Ilieva Arakelyan, Iliyana, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Mazur, Ewa, Medina-Flores, Carlos Aurelio, Mutinelli, Franco, Omar, Eslam M., Patalano, Solenn, Raudmets, Aivar, San Martin, Gilles, Soroker, Victoria, Stahlmann-Brown, Philip, Stevanović, Jevrosima, Uzunov, Aleksandar, Vejsnaes, Flemming, Williams, Anthony, Brodschneider, Robert, Gray, Alison, Adjlane, Noureddine, Arab, Alireza, Ballis, Alexis, Brusbardis, Valters, Bugeja Douglas, Adrian, Cadahía, Luis, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, Costa, Cristina Amaro da, Danneels, Ellen, Danihlík, Jiří, Dobrescu, Constantin, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gregorc, Aleš, Ilieva Arakelyan, Iliyana, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Mazur, Ewa, Medina-Flores, Carlos Aurelio, Mutinelli, Franco, Omar, Eslam M., Patalano, Solenn, Raudmets, Aivar, San Martin, Gilles, Soroker, Victoria, Stahlmann-Brown, Philip, Stevanović, Jevrosima, Uzunov, Aleksandar, Vejsnaes, Flemming, Williams, Anthony, and Brodschneider, Robert

Abstract

This article presents managed honey bee colony loss rates over winter 2019/20 resulting from using the standardised COLOSS questionnaire in 37 countries. Six countries were from outside Europe, including, for the first time in this series of articles, New Zealand. The 30,491 beekeepers outside New Zealand reported 4.5% of colonies with unsolvable queen problems, 11.1% of colonies dead after winter and 2.6% lost through natural disaster. This gave an overall colony winter loss rate of 18.1%, higher than in the previous year. The winter loss rates varied greatly between countries, from 7.4% to 36.5%. 3216 beekeepers from New Zealand managing 297,345 colonies reported 10.5% losses for their 2019 winter (six months earlier than for other, Northern Hemisphere, countries). We modelled the risk of loss as a dead/empty colony or from unresolvable queen problems, for all countries except New Zealand. Overall, larger beekeeping operations with more than 50 colonies experienced significantly lower losses (p < 0.001). Migration was also highly significant (p < 0.001), with lower loss rates for operations migrating their colonies in the previous season. A higher proportion of new queens reduced the risk of colony winter loss (p < 0.001), suggesting that more queen replacement is better. All three factors, operation size, migration and proportion of young queens, were also included in a multivariable main effects quasi-binomial GLM and all three remained highly significant (p < 0.001). Detailed results for each country and overall are given in a table, and a map shows relative risks of winter loss at the regional level.

Published
2023

3. Honey bee colony loss rates in 37 countries using the COLOSS survey for winter 2019–2020: the combined effects of operation size, migration and queen replacement

Author

Gray, Alison, primary, Adjlane, Noureddine, additional, Arab, Alireza, additional, Ballis, Alexis, additional, Brusbardis, Valters, additional, Bugeja Douglas, Adrian, additional, Cadahía, Luis, additional, Charrière, Jean-Daniel, additional, Chlebo, Robert, additional, Coffey, Mary F., additional, Cornelissen, Bram, additional, Costa, Cristina Amaro da, additional, Danneels, Ellen, additional, Danihlík, Jiří, additional, Dobrescu, Constantin, additional, Evans, Garth, additional, Fedoriak, Mariia, additional, Forsythe, Ivan, additional, Gregorc, Aleš, additional, Ilieva Arakelyan, Iliyana, additional, Johannesen, Jes, additional, Kauko, Lassi, additional, Kristiansen, Preben, additional, Martikkala, Maritta, additional, Martín-Hernández, Raquel, additional, Mazur, Ewa, additional, Medina-Flores, Carlos Aurelio, additional, Mutinelli, Franco, additional, Omar, Eslam M., additional, Patalano, Solenn, additional, Raudmets, Aivar, additional, San Martin, Gilles, additional, Soroker, Victoria, additional, Stahlmann-Brown, Philip, additional, Stevanovic, Jevrosima, additional, Uzunov, Aleksandar, additional, Vejsnaes, Flemming, additional, Williams, Anthony, additional, and Brodschneider, Robert, additional

Published
2022
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4. Spatial clusters of Varroa destructor control strategies in Europe

Author

Brodschneider, Robert, primary, Schlagbauer, Johannes, additional, Arakelyan, Iliyana, additional, Ballis, Alexis, additional, Brus, Jan, additional, Brusbardis, Valters, additional, Cadahía, Luis, additional, Charrière, Jean-Daniel, additional, Chlebo, Robert, additional, Coffey, Mary F., additional, Cornelissen, Bram, additional, da Costa, Cristina Amaro, additional, Danneels, Ellen, additional, Danihlík, Jiří, additional, Dobrescu, Constantin, additional, Evans, Garth, additional, Fedoriak, Mariia, additional, Forsythe, Ivan, additional, Gregorc, Aleš, additional, Johannesen, Jes, additional, Kauko, Lassi, additional, Kristiansen, Preben, additional, Martikkala, Maritta, additional, Martín-Hernández, Raquel, additional, Mazur, Ewa, additional, Mutinelli, Franco, additional, Patalano, Solenn, additional, Raudmets, Aivar, additional, Simon Delso, Noa, additional, Stevanovic, Jevrosima, additional, Uzunov, Aleksandar, additional, Vejsnæs, Flemming, additional, Williams, Anthony, additional, and Gray, Alison, additional

Published
2022
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5. Spatial clusters of Varroa destructor control strategies in Europe

Author

Brodschneider, Robert, Schlagbauer, Johannes, Arakelyan, Iliyana, Ballis, Alexis, Brus, Jan, Brusbardis, Valters, Cadahía, Luis, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, da Costa, Cristina Amaro, Danneels, Ellen, Danihlík, Jiří, Dobrescu, Constantin, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gregorc, Aleš, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Mazur, Ewa, Mutinelli, Franco, Patalano, Solenn, Raudmets, Aivar, Simon Delso, Noa, Stevanović, Jevrosima, Uzunov, Aleksandar, Vejsnæs, Flemming, Williams, Anthony, Gray, Alison, Brodschneider, Robert, Schlagbauer, Johannes, Arakelyan, Iliyana, Ballis, Alexis, Brus, Jan, Brusbardis, Valters, Cadahía, Luis, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, da Costa, Cristina Amaro, Danneels, Ellen, Danihlík, Jiří, Dobrescu, Constantin, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gregorc, Aleš, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Mazur, Ewa, Mutinelli, Franco, Patalano, Solenn, Raudmets, Aivar, Simon Delso, Noa, Stevanović, Jevrosima, Uzunov, Aleksandar, Vejsnæs, Flemming, Williams, Anthony, and Gray, Alison

Abstract

Beekeepers have various options to control the parasitic mite Varroa destructor in honey bee colonies, but no empirical data are available on the methods they apply in practice. We surveyed 28,409 beekeepers maintaining 507,641 colonies in 30 European countries concerning Varroa control methods. The set of 19 different Varroa diagnosis and control measures was taken from the annual COLOSS questionnaire on honey bee colony losses. The most frequent activities were monitoring of Varroa infestations, drone brood removal, various oxalic acid applications and formic acid applications. Correspondence analysis and hierarchical clustering on principal components showed that six Varroa control options (not necessarily the most used ones) significantly contribute to defining three distinctive clusters of countries in terms of Varroa control in Europe. Cluster I (eight Western European countries) is characterized by use of amitraz strips. Cluster II comprises 15 countries from Scandinavia, the Baltics, and Central-Southern Europe. This cluster is characterized by long-term formic acid treatments. Cluster III is characterized by dominant usage of amitraz fumigation and formed by seven Eastern European countries. The median number of different treatments applied per beekeeper was lowest in cluster III. Based on estimation of colony numbers in included countries, we extrapolated the proportions of colonies treated with different methods in Europe. This suggests that circa 62% of colonies in Europe are treated with amitraz, followed by oxalic acid for the next largest percentage of colonies. We discuss possible factors determining the choice of Varroa control measures in the different clusters.

Published
2022

6. Supplementary information for the article: Brodschneider, R.; Schlagbauer, J.; Arakelyan, I.; Ballis, A.; Brus, J.; Brusbardis, V.; Cadahía, L.; Charrière, J.-D.; Chlebo, R.; Coffey, M. F.; Cornelissen, B.; da Costa, C. A.; Danneels, E.; Danihlík, J.; Dobrescu, C.; Evans, G.; Fedoriak, M.; Forsythe, I.; Gregorc, A.; Johannesen, J.; Kauko, L.; Kristiansen, P.; Martikkala, M.; Martín-Hernández, R.; Mazur, E.; Mutinelli, F.; Patalano, S.; Raudmets, A.; Simon Delso, N.; Stevanovic, J.; Uzunov, A.; Vejsnæs, F.; Williams, A.; Gray, A. Spatial Clusters of Varroa Destructor Control Strategies in Europe. J Pest Sci 2022. https://doi.org/10.1007/s10340-022-01523-2.

Author

Brodschneider, Robert, Schlagbauer, Johannes, Arakelyan, Iliyana, Ballis, Alexis, Brus, Jan, Brusbardis, Valters, Cadahía, Luis, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, da Costa, Cristina Amaro, Danneels, Ellen, Danihlík, Jiří, Dobrescu, Constantin, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gregorc, Aleš, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Mazur, Ewa, Mutinelli, Franco, Patalano, Solenn, Raudmets, Aivar, Simon Delso, Noa, Stevanović, Jevrosima, Uzunov, Aleksandar, Vejsnæs, Flemming, Williams, Anthony, Gray, Alison, Brodschneider, Robert, Schlagbauer, Johannes, Arakelyan, Iliyana, Ballis, Alexis, Brus, Jan, Brusbardis, Valters, Cadahía, Luis, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, da Costa, Cristina Amaro, Danneels, Ellen, Danihlík, Jiří, Dobrescu, Constantin, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gregorc, Aleš, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Mazur, Ewa, Mutinelli, Franco, Patalano, Solenn, Raudmets, Aivar, Simon Delso, Noa, Stevanović, Jevrosima, Uzunov, Aleksandar, Vejsnæs, Flemming, Williams, Anthony, and Gray, Alison

Abstract

Table S1. Utilized packages of the statistical software R version 4.0.4.

Published
2022

8. CSI Pollen: Diversity of Honey Bee Collected Pollen Studied by Citizen Scientists

Author

Brodschneider, Robert, primary, Kalcher-Sommersguter, Elfriede, additional, Kuchling, Sabrina, additional, Dietemann, Vincent, additional, Gray, Alison, additional, Božič, Janko, additional, Briedis, Andrejs, additional, Carreck, Norman L., additional, Chlebo, Robert, additional, Crailsheim, Karl, additional, Coffey, Mary Frances, additional, Dahle, Bjørn, additional, González-Porto, Amelia Virginia, additional, Filipi, Janja, additional, de Graaf, Dirk C., additional, Hatjina, Fani, additional, Ioannidis, Pavlos, additional, Ion, Nicoleta, additional, Jørgensen, Asger Søgaard, additional, Kristiansen, Preben, additional, Lecocq, Antoine, additional, Odoux, Jean-François, additional, Özkirim, Asli, additional, Peterson, Magnus, additional, Podrižnik, Blaž, additional, Rašić, Slađan, additional, Retschnig, Gina, additional, Schiesser, Aygün, additional, Tosi, Simone, additional, Vejsnæs, Flemming, additional, Williams, Geoffrey, additional, and van der Steen, Jozef J.M., additional

Published
2021
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9. CSI Pollen: Diversity of Honey Bee Collected Pollen Studied by Citizen Scientists

Author

Brodschneider, Robert, Kalcher-Sommersguter, Elfriede, Kuchling, Sabrina, Dietemann, Vincent, Gray, Alison, Bozić, Janko, Briedis, Andrejs, Carreck, Norman L., Chlebo, Robert, Crailsheim, Karl, Coffey, Mary Frances, Dahle, Bjorn, Gonzalez-Porto, Amelia Virginia, Filipi, Janja, de Graaf, Dirk C., Hatjina, Fani, Ioannidis, Pavlos, Ion, Nicoleta, Jorgensen, Asger Sogaard, Kristiansen, Preben, Lecocq, Antoine, Odoux, Jean-Francois, Ozkirim, Asli, Peterson, Magnus, Podriznik, Blaz, Rašić, Slađan, Retschnig, Gina, Schiesser, Aygun, Tosi, Simone, Vejsnaes, Flemming, Williams, Geoffrey, van der Steen, Jozef J. M., Brodschneider, Robert, Kalcher-Sommersguter, Elfriede, Kuchling, Sabrina, Dietemann, Vincent, Gray, Alison, Bozić, Janko, Briedis, Andrejs, Carreck, Norman L., Chlebo, Robert, Crailsheim, Karl, Coffey, Mary Frances, Dahle, Bjorn, Gonzalez-Porto, Amelia Virginia, Filipi, Janja, de Graaf, Dirk C., Hatjina, Fani, Ioannidis, Pavlos, Ion, Nicoleta, Jorgensen, Asger Sogaard, Kristiansen, Preben, Lecocq, Antoine, Odoux, Jean-Francois, Ozkirim, Asli, Peterson, Magnus, Podriznik, Blaz, Rašić, Slađan, Retschnig, Gina, Schiesser, Aygun, Tosi, Simone, Vejsnaes, Flemming, Williams, Geoffrey, and van der Steen, Jozef J. M.

Abstract

Simple Summary Honey bee colonies collect pollen from plants as a source of nutrients. Diverse diets comprising pollen from many different plant species are beneficial for honey bee colony health, because they contain a greater diversity of nutrients than monofloral diets of one plant species only. Here, we present the results of the COLOSS "CSI Pollen" study on the diversity of pollen collected by honey bee colonies. In this study, beekeepers acted as citizen scientists sampling and analyzing pollen collected by their own colonies. As a simple measure of diversity, beekeepers determined the number of different colors found in pollen samples that were collected in a coordinated and standardized way. The support of 750 beekeepers allowed the collection of information about almost 18,000 pollen samples from many European countries. We found that the pollen samples consistently comprised approximately six different colors in total, of which four colors were abundant. 'Urban' habitats or 'artificial surfaces' were associated with higher pollen color diversity. This investigation highlights seasonal- and land-use-related differences in the pollen supply for honey bees, which affects beekeeping and pollinator health. Determining pollen colors is a simple, useful technique for beekeepers to estimate pollen diversity. A diverse supply of pollen is an important factor for honey bee health, but information about the pollen diversity available to colonies at the landscape scale is largely missing. In this COLOSS study, beekeeper citizen scientists sampled and analyzed the diversity of pollen collected by honey bee colonies. As a simple measure of diversity, beekeepers determined the number of colors found in pollen samples that were collected in a coordinated and standardized way. Altogether, 750 beekeepers from 28 different regions from 24 countries participated in the two-year study and collected and analyzed almost 18,000 pollen samples. Pollen samples contained approximate

Published
2021

10. Csi pollen:Diversity of honey bee collected pollen studied by citizen scientists

Author

Brodschneider, Robert, Kalcher-Sommersguter, Elfriede, Kuchling, Sabrina, Dietemann, Vincent, Gray, Alison, Božič, Janko, Briedis, Andrejs, Carreck, Norman L., Chlebo, Robert, Crailsheim, Karl, Coffey, Mary Frances, Dahle, Bjørn, González-Porto, Amelia Virginia, Filipi, Janja, de Graaf, Dirk C., Hatjina, Fani, Ioannidis, Pavlos, Ion, Nicoleta, Jørgensen, Asger Søgaard, Kristiansen, Preben, Lecocq, Antoine, Odoux, Jean François, Özkirim, Asli, Peterson, Magnus, Podrižnik, Blaž, Rašić, Sladan, Retschnig, Gina, Schiesser, Aygün, Tosi, Simone, Vejsnæs, Flemming, Williams, Geoffrey, van der Steen, Jozef J.M., Brodschneider, Robert, Kalcher-Sommersguter, Elfriede, Kuchling, Sabrina, Dietemann, Vincent, Gray, Alison, Božič, Janko, Briedis, Andrejs, Carreck, Norman L., Chlebo, Robert, Crailsheim, Karl, Coffey, Mary Frances, Dahle, Bjørn, González-Porto, Amelia Virginia, Filipi, Janja, de Graaf, Dirk C., Hatjina, Fani, Ioannidis, Pavlos, Ion, Nicoleta, Jørgensen, Asger Søgaard, Kristiansen, Preben, Lecocq, Antoine, Odoux, Jean François, Özkirim, Asli, Peterson, Magnus, Podrižnik, Blaž, Rašić, Sladan, Retschnig, Gina, Schiesser, Aygün, Tosi, Simone, Vejsnæs, Flemming, Williams, Geoffrey, and van der Steen, Jozef J.M.

Abstract

A diverse supply of pollen is an important factor for honey bee health, but information about the pollen diversity available to colonies at the landscape scale is largely missing. In this COLOSS study, beekeeper citizen scientists sampled and analyzed the diversity of pollen collected by honey bee colonies. As a simple measure of diversity, beekeepers determined the number of colors found in pollen samples that were collected in a coordinated and standardized way. Altogether, 750 beekeepers from 28 different regions from 24 countries participated in the two-year study and collected and analyzed almost 18,000 pollen samples. Pollen samples contained approximately six different colors in total throughout the sampling period, of which four colors were abundant. We ran generalized linear mixed models to test for possible effects of diverse factors such as collection, i.e., whether a minimum amount of pollen was collected or not, and habitat type on the number of colors found in pollen samples. To identify habitat effects on pollen diversity, beekeepers’ descriptions of the surrounding landscape and CORINE land cover classes were investigated in two different models, which both showed that both the total number and the rare number of colors in pollen samples were positively affected by ‘urban’ habitats or ‘artificial surfaces’, respectively. This citizen science study underlines the importance of the habitat for pollen diversity for bees and suggests higher diversity in urban areas.

Published
2021

11. Honey bee colony winter loss rates for 35 countries participating in the COLOSS survey for winter 2018–2019, and the effects of a new queen on the risk of colony winter loss

Author

Gray, Alison, Adjlane, Noureddine, Arab, Arab, Ballis, Alexis, Brusbardis, Valters, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, Amaro da Costa, Cristina, Dahle, Bjørn, Danihlík, Jiří, Dražić, Marica Maja, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gajda, Anna, de Graaf, Dirk C., Gregorc, Aleš, Ilieva, Iliyana, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Medina-Flores, Carlos Aurelio, Mutinelli, Franco, Patalano, Solenn, Raudmets, Aivar, Martin, Gilles San, Soroker, Victoria, Stevanović, Jevrosima, Uzunov, Aleksandar, Vejsnaes, Flemming, Williams, Anthony, Zammit-Mangion, Marion, Brodschneider, Robert, Gray, Alison, Adjlane, Noureddine, Arab, Arab, Ballis, Alexis, Brusbardis, Valters, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, Amaro da Costa, Cristina, Dahle, Bjørn, Danihlík, Jiří, Dražić, Marica Maja, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gajda, Anna, de Graaf, Dirk C., Gregorc, Aleš, Ilieva, Iliyana, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Medina-Flores, Carlos Aurelio, Mutinelli, Franco, Patalano, Solenn, Raudmets, Aivar, Martin, Gilles San, Soroker, Victoria, Stevanović, Jevrosima, Uzunov, Aleksandar, Vejsnaes, Flemming, Williams, Anthony, Zammit-Mangion, Marion, and Brodschneider, Robert

Abstract

This article presents managed honey bee colony loss rates over winter 2018/19 resulting from using the standardised COLOSS questionnaire in 35 countries (31 in Europe). In total, 28,629 beekeepers supplying valid loss data wintered 738,233 colonies, and reported 29,912 (4.1%, 95% confidence interval (CI) 4.0–4.1%) colonies with unsolvable queen problems, 79,146 (10.7%, 95% CI 10.5–10.9%) dead colonies after winter and 13,895 colonies (1.9%, 95% CI 1.8–2.0%) lost through natural disaster. This gave an overall colony winter loss rate of 16.7% (95% CI 16.4–16.9%), varying greatly between countries, from 5.8% to 32.0%. We modelled the risk of loss as a dead/empty colony or from unresolvable queen problems, and found that, overall, larger beekeeping operations with more than 150 colonies experienced significantly lower losses (p ' 0.001), consistent with earlier studies. Additionally, beekeepers included in this survey who did not migrate their colonies at least once in 2018 had significantly lower losses than those migrating (p ' 0.001). The percentage of new queens from 2018 in wintered colonies was also examined as a potential risk factor. The percentage of colonies going into winter with a new queen was estimated as 55.0% over all countries. Higher percentages of young queens corresponded to lower overall losses (excluding losses from natural disaster), but also lower losses from unresolvable queen problems, and lower losses from winter mortality (p ' 0.001). Detailed results for each country and overall are given in a table, and a map shows relative risks of winter loss at regional level.

Published
2020

12. Honey bee colony winter loss rates for 35 countries participating in the COLOSS survey for winter 2018–2019, and the effects of a new queen on the risk of colony winter loss

Author

Gray, Alison, primary, Adjlane, Noureddine, additional, Arab, Alireza, additional, Ballis, Alexis, additional, Brusbardis, Valters, additional, Charrière, Jean-Daniel, additional, Chlebo, Robert, additional, Coffey, Mary F., additional, Cornelissen, Bram, additional, Amaro da Costa, Cristina, additional, Dahle, Bjørn, additional, Danihlík, Jiří, additional, Dražić, Marica Maja, additional, Evans, Garth, additional, Fedoriak, Mariia, additional, Forsythe, Ivan, additional, Gajda, Anna, additional, de Graaf, Dirk C., additional, Gregorc, Aleš, additional, Ilieva, Iliyana, additional, Johannesen, Jes, additional, Kauko, Lassi, additional, Kristiansen, Preben, additional, Martikkala, Maritta, additional, Martín-Hernández, Raquel, additional, Medina-Flores, Carlos Aurelio, additional, Mutinelli, Franco, additional, Patalano, Solenn, additional, Raudmets, Aivar, additional, Martin, Gilles San, additional, Soroker, Victoria, additional, Stevanovic, Jevrosima, additional, Uzunov, Aleksandar, additional, Vejsnaes, Flemming, additional, Williams, Anthony, additional, Zammit-Mangion, Marion, additional, and Brodschneider, Robert, additional

Published
2020
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13. Loss rates of honey bee colonies during winter 2017/18 in 36 countries participating in the COLOSS survey, including effects of forage sources

Author

Gray, Alison, Brodschneider, Robert, Adjlane, Noureddine, Ballis, Alexis, Brusbardis, Valters, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, Amaro da Costa, Cristina, Csáki, Tamás, Dahle, Bjørn, Norway, Kløfta, Danihlík, Jiří, Maja Dražić, Marica, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, de Graaf, Dirk, Gregorc, Aleš, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martín-Hernández, Raquel, Medina-Flores, Carlos Aurelio, Mutinelli, Franco, Patalano, Solenn, Petrov, Plamen, Raudmets, Aivar, Ryzhikov, Vladimir A., Simon-Delso, Noa, Stevanovic, Jevrosima, Topolska, Grazyna, Uzunov, Aleksandar, Vejsnaes, Flemming, Zammit-Mangion, Marion, Soroker, Victoria, Williams, Anthony, Republic of Serbia, Slovenian Research Program, Zukunft Biene, and University of Graz

Subjects
0106 biological sciences, Beekeeping, Forage (honey bee), Honeybee -- Mortality -- Europe, beekeeping, forage sources, Biology, 01 natural sciences, Agricultural science, Biointeractions and Plant Health, 0404 agricultural biotechnology, citizen science, survey, QA, Ecological surveys, business.industry, Bee culture, Colony collapse disorder of honeybees, 04 agricultural and veterinary sciences, Honey bee, 040401 food science, mortality, 010602 entomology, monitoring, colony winter losses, Agriculture, Insect Science, Apis (Insects) -- Europe, Apis mellifera, business
Abstract

This short article presents loss rates of honey bee colonies over winter 2017/18 from 36 countries, including 33 in Europe, from data collected using the standardized COLOSS questionnaire. The 25,363 beekeepers supplying data passing consistency checks in total wintered 544,879 colonies, and reported 26,379 (4.8%, 95% CI 4.7–5.0%) colonies with unsolvable queen problems, 54,525 (10.0%, 95% CI 9.8–10.2%) dead colonies after winter and another 8,220 colonies (1.5%, 95% CI 1.4–1.6%) lost through natural disaster. This gave an overall loss rate of 16.4% (95% CI 16.1–16.6%) of honey bee colonies during winter 2017/18, but this varied greatly from 2.0 to 32.8% between countries. The included map shows relative risks of winter loss at regional level. The analysis using the total data-set confirmed findings from earlier surveys that smaller beekeeping operations with at most 50 colonies suffer significantly higher losses than larger operations (p, peer-reviewed

Published
2019

14. Multi-country loss rates of honey bee colonies during winter 2016/2017 from the COLOSS survey

Author

Brodschneider, Robert, Gray, Alison, Adjlane, Noureddine, Ballis, Alexis, Brusbardis, Valters, Charriere, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Dahle, Bjorn, de Graaf, Dirk C., Drazić, Marica Maja, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gregorc, Ales, Grzeda, Urszula, Hetzroni, Amots, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martin-Hernandez, Raquel, Aurelio Medina-Flores, Carlos, Mutinelli, Franco, Raudmets, Aivar, Ryzhikov, Vladimir A., Simon-Delso, Noa, Stevanović, Jevrosima, Uzunov, Aleksandar, Vejsnaes, Flemming, Woehl, Saskia, Zammit-Mangion, Marion, Danihlik, Jiri, Brodschneider, Robert, Gray, Alison, Adjlane, Noureddine, Ballis, Alexis, Brusbardis, Valters, Charriere, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Dahle, Bjorn, de Graaf, Dirk C., Drazić, Marica Maja, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Gregorc, Ales, Grzeda, Urszula, Hetzroni, Amots, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martin-Hernandez, Raquel, Aurelio Medina-Flores, Carlos, Mutinelli, Franco, Raudmets, Aivar, Ryzhikov, Vladimir A., Simon-Delso, Noa, Stevanović, Jevrosima, Uzunov, Aleksandar, Vejsnaes, Flemming, Woehl, Saskia, Zammit-Mangion, Marion, and Danihlik, Jiri

Abstract

In this short note we present comparable loss rates of honey bee colonies during winter 2016/2017 from 27 European countries plus Algeria, Israel and Mexico, obtained with the COLOSS questionnaire. The 14,813 beekeepers providing valid loss data collectively wintered 425,762 colonies, and reported 21,887 (5.1%, 95% confidence interval 5.0-5.3%) colonies with unsolvable queen problems and 60,227 (14.1%, 95% CI 13.8-14.4%) dead colonies after winter. Additionally we asked for colonies lost due to natural disaster, which made up another 6,903 colonies (1.6%, 95% CI 1.5-1.7%). This results in an overall loss rate of 20.9% (95% CI 20.6-21.3%) of honey bee colonies during winter 2016/2017, with marked differences among countries. The overall analysis showed that small operations suffered higher losses than larger ones (p < 0.001). Overall migratory beekeeping had no significant effect on the risk of winter loss, though there was an effect in several countries. A table is presented giving detailed results from 30 countries. A map is also included, showing relative risk of colony winter loss at regional level.

Published
2018

15. Multi-country loss rates of honey bee colonies during winter 2016/2017 from the COLOSS survey

Author

Brodschneider, Robert, primary, Gray, Alison, additional, Adjlane, Noureddine, additional, Ballis, Alexis, additional, Brusbardis, Valters, additional, Charrière, Jean-Daniel, additional, Chlebo, Robert, additional, Coffey, Mary F, additional, Dahle, Bjørn, additional, de Graaf, Dirk C, additional, Maja Dražić, Marica, additional, Evans, Garth, additional, Fedoriak, Mariia, additional, Forsythe, Ivan, additional, Gregorc, Aleš, additional, Grzęda, Urszula, additional, Hetzroni, Amots, additional, Kauko, Lassi, additional, Kristiansen, Preben, additional, Martikkala, Maritta, additional, Martín-Hernández, Raquel, additional, Aurelio Medina-Flores, Carlos, additional, Mutinelli, Franco, additional, Raudmets, Aivar, additional, A Ryzhikov, Vladimir, additional, Simon-Delso, Noa, additional, Stevanovic, Jevrosima, additional, Uzunov, Aleksandar, additional, Vejsnæs, Flemming, additional, Wöhl, Saskia, additional, Zammit-Mangion, Marion, additional, and Danihlík, Jiří, additional

Published
2018
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16. SLU redovisar tre studier om effekter på virusnivåer

Author

Locke, Barbara, Rodrigues De Miranda, Joachim, Kristiansen, Preben, and Forsgren, Eva

Subjects
Pathobiology
Abstract

Varroakvalstret (Varroa destructor) är ett av de största hoten mot biodling världen över. Utan behandling dör angripna bisamhällen vanligtvis inom några år, men inte på grund av själva kvalsterangreppet i sig utan av de virusinfektioner som sprids med och utvecklas effektivare på grund av kvalstren. Många olika slags virus har hittats hos honungsbin, och några av dem är starkt knutna till varroakvalstret.

Published
2016

18. Preliminary analysis of loss rates of honey bee colonies during winter 2015/16 from the COLOSS survey

Author

Brodschneider, Robert, primary, Gray, Alison, additional, van der Zee, Romée, additional, Adjlane, Noureddine, additional, Brusbardis, Valters, additional, Charrière, Jean-Daniel, additional, Chlebo, Robert, additional, Coffey, Mary F, additional, Crailsheim, Karl, additional, Dahle, Bjørn, additional, Danihlík, Jiří, additional, Danneels, Ellen, additional, de Graaf, Dirk C, additional, Dražić, Marica Maja, additional, Fedoriak, Mariia, additional, Forsythe, Ivan, additional, Golubovski, Miroljub, additional, Gregorc, Ales, additional, Grzęda, Urszula, additional, Hubbuck, Ian, additional, İvgin Tunca, Rahşan, additional, Kauko, Lassi, additional, Kilpinen, Ole, additional, Kretavicius, Justinas, additional, Kristiansen, Preben, additional, Martikkala, Maritta, additional, Martín-Hernández, Raquel, additional, Mutinelli, Franco, additional, Peterson, Magnus, additional, Otten, Christoph, additional, Ozkirim, Aslı, additional, Raudmets, Aivar, additional, Simon-Delso, Noa, additional, Soroker, Victoria, additional, Topolska, Grazyna, additional, Vallon, Julien, additional, Vejsnæs, Flemming, additional, and Woehl, Saskia, additional

Published
2016
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19. Managed honey bee colony losses in Canada, China, Europe, Israel and Turkey, for the winters of 2008-9 and 1009-10

Author

van der Zee, Romee, Pisa, Lennard, Andonov, Sreten, Brodschneider, Robert, Charriere, Jean-Daniel, Chlebo, Robert, Coffey, Mary F, Dahle, Bjørn, Gajda, Anna, Gray, Alison, Drazic, Marica M, Higes, Mariano, Kauko, Lassi, Kence, Aykut, Kence, Meral, Kezic, Nicola, Kiprijanovska, Hrisula, Kralj, Jasna, Kristiansen, Preben, Hernandez, Raquel Martin, Mutinelli, Franco, Nguyen, Bach Kim, Otten, Christoph, Ozkirim, Asli, Pernal, Stephen F., Peterson, Magnus, Ramsay, Gavin, Santrac, Violeta, Soroker, Victoria, Topolska, Grazyna, Uzunov, Aleksander, Vejsnaes, Flemming, Wei, Shi, and Wilkins, Selwyn

Subjects
QA273
Abstract

In 2008 the COLOSS network was formed by honey bee experts from Europe and the USA. The primary objectives set by this scientific network were to explain and to prevent large scale losses of honey bee (Apis mellifera) colonies. In June 2008 COLOSS obtained four years support from the European Union from COST and was designated as COST Action FA0803 – COLOSS (Prevention of honey bee COlony LOSSes). To enable the comparison of loss data between participating countries, a standardized COLOSS questionnaire was developed. Using this questionnaire information on honey bee losses has been collected over two years. Survey data presented in this study were gathered in 2009 from 12 countries and in 2010 from 24 countries. Mean honey bee losses in Europe varied widely, between 7-22% over the 2008-9 winter and between 7-30% over the 2009-10 winter. An important finding is that for all countries which participated in 2008-9, winter losses in 2009-10 were found to be substantially higher. In 2009-10, winter losses in South East Europe were at such a low level that the factors causing the losses in other parts of Europe were absent, or at a level which did not affect colony survival. The five provinces of China, which were included in 2009-10, showed very low mean (4%) A. mellifera winter losses. In six Canadian provinces, mean winter losses in 2010 varied between 16-25%, losses in Nova Scotia (40%) being exceptionally high. In most countries and in both monitoring years, hobbyist beekeepers (1-50 colonies) experienced higher losses than practitioners with intermediate beekeeping operations (51-500 colonies). This relationship between scale of beekeeping and extent of losses effect was also observed in 2009-10, but was less pronounced. In Belgium, Italy, the Netherlands and Poland, 2008-9 mean winter losses for beekeepers who reported ‘disappeared’ colonies were significantly higher compared to mean winter losses of beekeepers who did not report ‘disappeared’ colonies. Mean 2008-9 winter losses for those beekeepers in the Netherlands who reported symptoms similar to “Colony Collapse Disorder” (CCD), namely: 1. no dead bees in or surrounding the hive while; 2. capped brood was present, were significantly higher than mean winter losses for those beekeepers who reported ‘disappeared’ colonies without the presence of capped brood in the empty hives. In the winter of 2009-10 in the majority of participating countries, beekeepers who reported ‘disappeared’ colonies experienced higher winter losses compared with beekeepers, who experienced winter losses but did not report ‘disappeared’ colonies.

Published
2012

20. Results of international standardised beekeeper surveys of colony losses for winter 2012–2013: analysis of winter loss rates and mixed effects modelling of risk factors for winter loss

Author

Zee, Romée van der, primary, Brodschneider, Robert, additional, Brusbardis, Valters, additional, Charrière, Jean-Daniel, additional, Chlebo, Róbert, additional, Coffey, Mary F, additional, Dahle, Bjørn, additional, Drazic, Marica M, additional, Kauko, Lassi, additional, Kretavicius, Justinas, additional, Kristiansen, Preben, additional, Mutinelli, Franco, additional, Otten, Christoph, additional, Peterson, Magnus, additional, Raudmets, Aivar, additional, Santrac, Violeta, additional, Seppälä, Ari, additional, Soroker, Victoria, additional, Topolska, Grażyna, additional, Vejsnæs, Flemming, additional, and Gray, Alison, additional

Published
2014
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21. Standard survey methods for estimating colony losses and explanatory risk factors inApis mellifera

Author

van der Zee, Romée, primary, Gray, Alison, additional, Holzmann, Céline, additional, Pisa, Lennard, additional, Brodschneider, Robert, additional, Chlebo, Róbert, additional, Coffey, Mary F, additional, Kence, Aykut, additional, Kristiansen, Preben, additional, Mutinelli, Franco, additional, Nguyen, Bach Kim, additional, Noureddine, Adjlane, additional, Peterson, Magnus, additional, Soroker, Victoria, additional, Topolska, Grażyna, additional, Vejsnæs, Flemming, additional, and Wilkins, Selwyn, additional

Published
2013
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22. Managed honey bee colony losses in Canada, China, Europe, Israel and Turkey, for the winters of 2008–9 and 2009–10

Author

van der Zee, Romée, primary, Pisa, Lennard, additional, Andonov, Sreten, additional, Brodschneider, Robert, additional, Charrière, Jean-Daniel, additional, Chlebo, Róbert, additional, Coffey, Mary F, additional, Crailsheim, Karl, additional, Dahle, Bjørn, additional, Gajda, Anna, additional, Gray, Alison, additional, Drazic, Marica M, additional, Higes, Mariano, additional, Kauko, Lassi, additional, Kence, Aykut, additional, Kence, Meral, additional, Kezic, Nicola, additional, Kiprijanovska, Hrisula, additional, Kralj, Jasna, additional, Kristiansen, Preben, additional, Hernandez, Raquel Martin, additional, Mutinelli, Franco, additional, Nguyen, Bach Kim, additional, Otten, Christoph, additional, Özkırım, Asli, additional, Pernal, Stephen F, additional, Peterson, Magnus, additional, Ramsay, Gavin, additional, Santrac, Violeta, additional, Soroker, Victoria, additional, Topolska, Grażyna, additional, Uzunov, Aleksandar, additional, Vejsnæs, Flemming, additional, Wei, Shi, additional, and Wilkins, Selwyn, additional

Published
2012
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23. Standard survey methods for estimating colony losses and explanatory risk factors in Apis mellifera

Author

van der Zee, Romée, Gray, Alison, Holzmann, Céline, Pisa, Lennard, Brodschneider, Robert, Chlebo, Róbert, Coffey, Mary F, Kence, Aykut, Kristiansen, Preben, Mutinelli, Franco, Nguyen, Bach Kim, Noureddine, Adjlane, Peterson, Magnus, Soroker, Victoria, Topolska, Grażyna, Vejsnæs, Flemming, and Wilkins, Selwyn

Abstract

SummaryThis chapter addresses survey methodology and questionnaire design for the collection of data pertaining to estimation of honey bee colony loss rates and identification of risk factors for colony loss. Sources of error in surveys are described. Advantages and disadvantages of different random and non-random sampling strategies and different modes of data collection are presented to enable the researcher to make an informed choice. We discuss survey and questionnaire methodology in some detail, for the purpose of raising awareness of issues to be considered during the survey design stage in order to minimise error and bias in the results. Aspects of survey design are illustrated using surveys in Scotland. Part of a standardized questionnaire is given as a further example, developed by the COLOSS working group for Monitoring and Diagnosis. Approaches to data analysis are described, focussing on estimation of loss rates. Dutch monitoring data from 2012 were used for an example of a statistical analysis with the public domain R software. We demonstrate the estimation of the overall proportion of losses and corresponding confidence interval using a quasi-binomial model to account for extra-binomial variation. We also illustrate generalized linear model fitting when incorporating a single risk factor, and derivation of relevant confidence intervals.

Published
2013
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24. Loss rates of honey bee colonies during winter 2017/18 in 36 countries participating in the COLOSS survey, including effects of forage sources

Author

Republic of Serbia, Slovenian Research Program, Zukunft Biene, University of Graz, Gray, Alison, Brodschneider, Robert, Adjlane, Noureddine, Ballis, Alexis, Brusbardis, Valters, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, Costa, Cristina Amaro da, Csaki, Tamas, Dahle, Bjørn, Danihlík, Jiří, Dražić, Marica Maja, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Graaf, Dirk de, Gregorc, Ales, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martın-Hern andez, Raquel, Medina-Flores, Carlos Aurelio, Mutinelli, Franco, Patalano, Solenn, Petrov, Plamen, Raudmets,Aivar, Ryzhikov, Vladimir A., Simon-Delso, Noa, Stevanovic Jevrosima, Topolska Grazyna, Uzunov Aleksandar, Marion Vejsnaes Flemming, Anthony, Williams, Zammit-Mangion Marion, Soroker Victoria, Republic of Serbia, Slovenian Research Program, Zukunft Biene, University of Graz, Gray, Alison, Brodschneider, Robert, Adjlane, Noureddine, Ballis, Alexis, Brusbardis, Valters, Charrière, Jean-Daniel, Chlebo, Robert, Coffey, Mary F., Cornelissen, Bram, Costa, Cristina Amaro da, Csaki, Tamas, Dahle, Bjørn, Danihlík, Jiří, Dražić, Marica Maja, Evans, Garth, Fedoriak, Mariia, Forsythe, Ivan, Graaf, Dirk de, Gregorc, Ales, Johannesen, Jes, Kauko, Lassi, Kristiansen, Preben, Martikkala, Maritta, Martın-Hern andez, Raquel, Medina-Flores, Carlos Aurelio, Mutinelli, Franco, Patalano, Solenn, Petrov, Plamen, Raudmets,Aivar, Ryzhikov, Vladimir A., Simon-Delso, Noa, Stevanovic Jevrosima, Topolska Grazyna, Uzunov Aleksandar, Marion Vejsnaes Flemming, Anthony, Williams, Zammit-Mangion Marion, and Soroker Victoria

Abstract

peer-reviewed, This short article presents loss rates of honey bee colonies over winter 2017/18 from 36 countries, including 33 in Europe, from data collected using the standardized COLOSS questionnaire. The 25,363 beekeepers supplying data passing consistency checks in total wintered 544,879 colonies, and reported 26,379 (4.8%, 95% CI 4.7–5.0%) colonies with unsolvable queen problems, 54,525 (10.0%, 95% CI 9.8–10.2%) dead colonies after winter and another 8,220 colonies (1.5%, 95% CI 1.4–1.6%) lost through natural disaster. This gave an overall loss rate of 16.4% (95% CI 16.1–16.6%) of honey bee colonies during winter 2017/18, but this varied greatly from 2.0 to 32.8% between countries. The included map shows relative risks of winter loss at regional level. The analysis using the total data-set confirmed findings from earlier surveys that smaller beekeeping operations with at most 50 colonies suffer significantly higher losses than larger operations (p<.001). Beekeepers migrating their colonies had significantly lower losses than those not migrating (p<.001), a different finding from previous research. Evaluation of six different forage sources as potential risk factors for colony loss indicated that intensive foraging on any of five of these plant sources (Orchards, Oilseed Rape, Maize, Heather and Autumn Forage Crops) was associated with significantly higher winter losses. This finding requires further study and explanation. A table is included giving detailed results of loss rates and the impact of the tested forage sources for each country and overall.

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