The spinal consequences of HT-2 toxin and selenium deficiency during bone maturation in mice.

In our investigation, we probed the ramifications of low selenium diets and HT-2 mycotoxin exposure on spinal development and structural fidelity in murine models. A cohort of 48 male mice was segregated into six groups: a control set, a singular low selenium diet group, two cohorts exposed to distinct concentrations of HT-2 toxin (1.6 and 3.2 mg/kg·bw·d), and two assemblies subjected to a confluence of low selenium intake and each designated HT-2 dosage. Across an 8-week investigative period, parameters such as body mass, markers of bone metabolism, and cellular vigor were assiduously monitored. Analytical techniques encompassed biomechanical assessments, X-ray scrutiny, and micro-computed tomography (micro-CT) evaluations. Our results unveiled a dose-dependent diminution in the body mass of mice exclusively exposed to HT-2 toxin, whereas concurrent exposure to both low selenium and HT-2 toxins elicited a synergistic effect. Pertinent shifts were observed in calcium, phosphorus, and vitamin D concentrations, as well as in the operational dynamics of osteoblasts and osteoclasts, aligning with toxin dosage and combined exposure. Variations in biomechanical attributes were also discerned, mirroring the levels of toxin exposure. Micro-CT and X-ray examinations further corroborated the extensive detrimental impact on the cortical and trabecular architecture of the mice's spinal columns. This inquiry elucidates the complex synergistic interactions between low selenium and HT-2 mycotoxin on murine spinal development and integrity under co-exposure conditions. These findings accentuate the exigency of comprehensively understanding the solitary and joint effects of these toxins on osseous health, providing pivotal insights for future toxicological research and public health strategies.