Abstract

American foulbrood is a dangerous bee disease that attacks the sealed brood. It quickly leads to the death of bee colonies. Efficient diagnosis of this disease is essential. As specific odours are produced when larvae rot, it was investigated whether an electronic nose can distinguish between colonies affected by American foulbrood and healthy ones. The experiment was conducted in an apiary with 18 bee families, 9 of which showed symptoms of the disease confirmed by laboratory diagnostics. Three units of the Beesensor V.2 device based on an array of six semiconductor TGS gas sensors, manufactured by Figaro, were tested. Each copy of the device was tested in all bee colonies: sick and healthy. The measurement session per bee colony lasted 40 min and yielded results from four 10 min measurements. One 10-min measurement consisted of a 5 min regeneration phase and a 5 min object-measurement phase. For the experiments, we used both classical classification methods such as k-nearest neighbour, Naive Bayes, Support Vector Machine, discretized logistic regression, random forests, and committee of classifiers, that is, methods based on extracted representative data fragments. We also used methods based on the entire 600 s series, in this study of sequential neural networks. We considered, in this study, six options for data preparation as part of the transformation of data series into representative results. Among others, we used single stabilised sensor readings as well as average values from stable areas. For verifying the quality of the classical classifiers, we used the 25-fold train-and-test method. The effectiveness of the tested methods reached a threshold of 75 per cent, with results stable between 65 and 70 per cent. As an element to confirm the possibility of class separation using an artificial nose, we used applied visualisations of classes. It is clear from the experiments conducted that the artificial nose tested has practical potential. Our experiments show that the approach to the problem under study by sequential network learning on a sequence of data is comparable to the best classical methods based on discrete data samples. The results of the experiment showed that the Beesensor V.2 along with properly selected classification techniques can become a tool to facilitate rapid diagnosis of American foulbrood under field conditions.

Highlights

  • American foulbrood is a dangerous disease of the honeybee caused by the bacterium Paenibacillus larvae larvae

  • Considering all the analyses for the three units and all the third and fourth measurements, a good classification tool becomes the classification committee based on the three techniques of 1nn, lg, and svm_linear

  • Beesensor V.2 distinguishes between bee colonies infected with American foulbrood and healthy bee colonies at a level of 73%

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Summary

Introduction

American foulbrood is a dangerous disease of the honeybee caused by the bacterium Paenibacillus larvae larvae (white). This bacterium produces highly resistant spores [1] and can survive for decades [2]. The spores can be carried by bees with food and by the beekeeper on beekeeping equipment. In this way, the disease spreads rapidly first in the apiary from colony to colony and from apiary to apiary. Monitoring studies of honey contamination with P.l. larvae spores conducted in Poland [5] have shown that there are regions where the risk of American foulbrood symptoms is high. The results of this study translate into the current epizootic situation in the area (results of observations during field work by a co-author of the project, a veterinary surgeon specialising in bee diseases)

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