Introduction: Swimmer's itch (or cercarial dermatitis) is caused by avian and mammalian blood flukes, a parasitic infection affecting people worldwide. In particular, avian blood flukes of the genus Trichobilharzia, including Trichobilharzia regenti, are known for causing swimmer's itch. While these parasites typically infect waterfowl as final hosts, incidental infections in humans by cercariae can occur. Such infections trigger immune responses leading to painful, itchy skin lesions. In experimental animals, T. regenti has however shown the ability to evade immune responses, causing neuroinflammation. Recent decades have witnessed an increase in swimmer's itch cases across Europe, turning it into an emerging zoonosis. Methods: Following a swimmer's itch case in Kampenhout (Belgium) in 2022, a malacological and parasitological survey was conducted at the transmission site, consisting of a private pond and adjacent creek. Results: Six snail species were collected, including Ampullaceana balthica, a common intermediate host for Trichobilharzia parasites. Shedding experiments and DNA barcoding identified one snail specimen infected with T. regenti, a new species record for Belgium. This finding further strengthens the link between T. regenti and cercarial dermatitis. Additionally, Echinostomatidae sp. and Notocotylus sp. were isolated from other A. balthica specimens. However, the absence of reference DNA sequences hindered genus- and species-level identification for these parasites. Conclusions: The presence of T. regenti in Belgium may have significant clinical implications, emphasizing the need for heightened diagnostic awareness among medical professionals. The lack of species-level identification for other parasite species underscores the need for comprehensive DNA databases for trematodes. These findings reveal the necessity for a Belgian framework to promptly detect and monitor zoonotic outbreaks of trematode parasites within the One Health context.
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RBINS Staff Publications 2025
One of the key challenges in the archaeology of sheep domestication is reconstructing the complex history of environmental and anthropogenic transformations undergone by sheep since the beginning of the domestication process of their wild ancestors. In recent years, GMM studies of sheep astragalus bones have contributed to our understanding of morphological differences between wild and domestic caprine species. However, the respective influences of biological and ecological factors on astragalus morphological variations in sheep remain poorly documented. This limitation hinders a comprehensive understanding of its biosystematic resolution and, consequently, its use as a proxy in archaeological contexts to investigate early selective breeding and the emergence of sheep breeds in Southwest Asia. This paper presents the results of a morphological study of 96 astragali using 3D geometric morphometrics, focusing primarily on modern Eurasian and African sheep breeds and landraces. The study is based on a well-documented comparative collection encompassing phenotypical traits (breed, sex, age, presence/absence of horns, coat and tail type, weight, body length); ecological characteristics (climate, geography, environment, elevation, topography); and breeding strategies (mobility). The results demonstrate that the 3D astragalus morphological pattern is a reliable marker for distinguishing one sheep breed from another. They suggest that astragalus morphology is only slightly influenced by phenotypic markers. The study further explores the effects of environmental and climatic factors on phenotypic variation and highlights the potential of the astragalus as an ecomorphological marker. Finally, the current limitations in interpreting the relationship between astragalus morphological variation and mobility strategies in archaeological contexts are discussed.
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RBINS Staff Publications 2026
