# Tracking Varroa Parasitism Using Handheld Infrared Cameras: Is Eusocial Fever the Key?

**Authors:** Tamás Sipos, Szilvia Orsi-Gibicsár, Tamás Schieszl, Tamás Donkó, Zsombor Zakk, Sándor Farkas, Antal Binder, Sándor Keszthelyi

PMC · DOI: 10.3390/insects15090693 · Insects · 2024-09-13

## TL;DR

Researchers used infrared cameras to detect Varroa mites in honey bee broods by identifying temperature changes caused by parasitism.

## Contribution

This study introduces infrared thermal imaging as a non-invasive method to detect Varroa mites in honey bee broods.

## Key findings

- Infrared cameras can distinguish between honey, pollen, and brood cells with stable temperature measurements.
- Mite parasitism causes a sustained temperature increase in pupae, detectable via thermal imaging.
- The study identifies a social fever response in honey bees as a potential defense against Varroa mites.

## Abstract

Varroa destructor is a significant global honey bee parasite and the primary threat to bee health. Due to its latent lifestyle, detecting the mite in a brood requires invasive techniques. Enhancing detection methods is critical for advanced research on mite population dynamics, spread, selection efforts, and control methodologies. In this study, we employed infrared thermal imaging, a less-explored technique in apicultural studies, to detect parasitism in Apis mellifera broods. Our findings indicate that handheld infrared thermal cameras can generate adequately detailed heat maps of the hive. These maps distinctly separate cells containing honey, pollen, and brood, with stable, reproducible temperature measurements observable in late autumn. Notably, mite parasitism induces a sustained temperature increase in developing honey bee pupae, consistently detected regardless of mite numbers in the cell. This study reveals an advanced thermoregulatory behavior in the honey bee colony, manifesting as a social fever phenomenon. Further research is necessary to explore the health benefits of this behavior for bees and the negative effects on the mite. Our method, combined with the development of AI-based image evaluation software, could provide beekeepers and researchers with a valuable tool for Varroa research and bee biological studies.

The Varroa destructor is the most significant bee parasite and the greatest threat to bee health all around the world. Due to its hidden lifestyle, detection within the brood cell is only possible through invasive techniques. Enhancing detection methods is essential for advancing research on population dynamics, spread, selection efforts, and control methodologies against the mite. In our study, we employed infrared imaging to measure the thermal differences in parasite and intact Apis mellifera worker broods. Experiments were conducted over two years at the MATE Kaposvár Campus in Hungary involving five beehives in 2022 and five beehives in 2023. A FLIR E5-XT WIFI handheld infrared camera was used to create a heat map of capped brood frames. Our results indicate that the resolution of these cameras is sufficient to provide detailed IR images of a bee colony, making them suitable to detect temperature differences in intact and Varroa parasitized capped brood cells. Mite parasitism causes a time-dependent and sustained temperature increase in developing bee pupae, observable regardless of mite number. Our work demonstrates two different heating patterns: hotspot heating and heating cells that are responsible for the elevated temperature of the Varroa-infested cells as a social fever response by the worker bees. Based on our results, future research combined with AI-based image evaluation software could offer beekeepers and researchers practical and valuable tools for high-throughput, non-invasive Varroa detection in the field.

## Linked entities

- **Species:** Apis mellifera (taxon 7460)

## Full-text entities

- **Diseases:** Varroa Parasitism (MESH:D010272), Eusocial Fever (MESH:D005334)
- **Species:** Apis mellifera (bee, species) [taxon 7460], Varroa destructor (honeybee ectoparasitic mite, species) [taxon 109461], Varroa (genus) [taxon 62624]

## Full text

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## Figures

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## References

47 references — full list in the complete paper: https://tomesphere.com/paper/PMC11432453/full.md

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Source: https://tomesphere.com/paper/PMC11432453