Editorial: Animal Biomechanics: Application of Biomedical Engineering to Veterinary Sciences for Animal Healthcare – Volume II

Mauro Malvè^1*Rocío Fernández-Parra²

• ¹Public University of Navarre, Pamplona, Spain
• ²Universidad Catolica de Valencia San Vicente Martir Facultad de Veterinaria y Ciencias Experimentales, Valencia, Spain

Within the field of experimental and clinical biomechanics, Shin et al. present a finite element analysis to evaluate the biomechanical performance of different plate placements in canine elbow arthrodesis. Specifically, caudal, medial, and lateral plate configurations are compared in terms of stress distribution and create stability. Their results indicate that plate position has a substantial influence on load transfer and mechanical behaviour of the arthrodesis construct, highlighting the relevance of computational modelling for optimizing surgical planning and implant positioning in veterinary orthopaedics. Casas-Alvarado et al. investigate the surface thermal response of peripheral nerve blocks in dogs undergoing trauma or orthopaedic surgery, shedding light on analgesic monitoring under clinical conditions. Underberg et al. use time-of-flight magnetic resonance imaging to achieve non-contrast enhanced visualization of equine foot vasculature in a cadaver model, demonstrating a promising imaging approach. Day et al. compare polyethylene cable versus stainless steel cerclage wire in a canine fracture model, providing biomechanical insight relevant to orthopaedic repair. Wang et al. contribute two complementary studies on large avian species, reporting on head and neck movement characteristics and on morphological parameters of vertebrae in domestic geese and ducks, respectively, with implications for comparative anatomy, motion analysis, and veterinary ergonomics. Guevar et al. present a comparative biomechanical analysis of monocortical and bicortical polyaxial screw-rod fixation strategies in canine lumbar stabilization, and Kim et al. describe a modified laparoscopic-assisted percutaneous gastropexy technique in dogs, exemplifying surgical innovation and minimally invasive approaches. This volume also presents advancements in personalized veterinary devices and computational approaches. Sutter et al. present a cadaveric study of patient-specific 3D-printed nasopharyngeal stents in dogs, highlighting the potential of additive manufacturing for customized veterinary implants. Yu et al. apply deep learning to ultrasonographic data to classify canine chronic kidney disease, illustrating the promise of artificial intelligence in diagnostic workflows. Huart et al. employ statistical shape modelling to characterize the geometric morphology of the canine femur, tibia, and patella, offering quantitative reference data that may support clinical decision-making, implant design, and surgical planning. These studies collectively demonstrate how computational modelling, machine learning, and additive manufacturing converge to enable more precise, individualized, and effective interventions in veterinary practice. Taken together, the articles in Volume II illustrate the range and depth of how biomedical engineering is being applied across veterinary disciplines. From imaging and implant design to computational diagnostics, motion analysis, and educational technologies, this collection demonstrates both technological diversity and translational relevance. At the same time, the volume underscores that many questions remain open -particularly those that lie at the intersection of quantitative model validation, clinical implementation, and species-specific biomechanics. The findings presented here also highlight the need for interdisciplinary collaboration, integrating veterinary clinicians, biomedical engineers, computer scientists, and data analysts to address complex health challenges.We thank all the authors for their contributions to this Research Topic. We hope that this collection not only enriches the field of veterinary biomechanics but also promotes further collaboration between veterinary clinicians and engineers. By promoting such interdisciplinary partnerships, this research strongly aligns with the OneHealth framework, which recognizes the interconnection of human, animal, and environmental health. Knowledge and methodologies developed in human biomechanics can, in turn, be applied to animals, improving veterinary care and outcomes. The insights gained from these studies can inform better clinical interventions, enhance animal welfare, and generate findings that may translate back to human health.