<p>Diabetes-associated cognitive dysfunction represents a global health challenge, yet the mechanisms by which anesthetics modulate cognitive function in diabetic states remain poorly understood. We systematically compared the effects of 2-hour brief exposure to sevoflurane (SEV) and propofol (PRO) on cognitive function and neuropathology in streptozotocin (STZ) -induced diabetic mice. Morris water maze and Y-maze tests revealed that SEV significantly exacerbated spatial memory and learning deficits in mice, while PRO showed no significant effects. Additionally, diabetic mice exhibited reduced NeuN<sup>+</sup> neurons, increased β-amyloid deposition, and decreased SYN expression in the hippocampal CA1 region as examined by Immuno-fluorescence staining. Neither short-term SEV nor PRO exposure aggravated neuronal structural damage. Further transcriptomics revealed both anesthetics affected hippocampal neuron differentiation, but SEV uniquely perturbed fatty acid metabolism pathways. Metabolomics identified SEV-induced disruptions in lipid metabolism, marked by elevated hippocampal free fatty acids, phospholipids, as well as reduced lysophospholipids and acylcarnitine. Integrated multi-omics analysis demonstrated that SEV impaired cognition by suppressing fatty acid oxidation and dysregulating glycerophospholipid metabolism. These findings highlight the critical impact of anesthetic selection in diabetic populations.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Multi-omics analysis reveals sevoflurane exacerbates cognitive impairment in diabetic mice by disrupting lipid metabolism

  • Xinyue Liu,
  • Fang Wang,
  • Chang Liu,
  • Kai Yu,
  • Yuqin Wang,
  • Guoqing Zhao

摘要

Diabetes-associated cognitive dysfunction represents a global health challenge, yet the mechanisms by which anesthetics modulate cognitive function in diabetic states remain poorly understood. We systematically compared the effects of 2-hour brief exposure to sevoflurane (SEV) and propofol (PRO) on cognitive function and neuropathology in streptozotocin (STZ) -induced diabetic mice. Morris water maze and Y-maze tests revealed that SEV significantly exacerbated spatial memory and learning deficits in mice, while PRO showed no significant effects. Additionally, diabetic mice exhibited reduced NeuN+ neurons, increased β-amyloid deposition, and decreased SYN expression in the hippocampal CA1 region as examined by Immuno-fluorescence staining. Neither short-term SEV nor PRO exposure aggravated neuronal structural damage. Further transcriptomics revealed both anesthetics affected hippocampal neuron differentiation, but SEV uniquely perturbed fatty acid metabolism pathways. Metabolomics identified SEV-induced disruptions in lipid metabolism, marked by elevated hippocampal free fatty acids, phospholipids, as well as reduced lysophospholipids and acylcarnitine. Integrated multi-omics analysis demonstrated that SEV impaired cognition by suppressing fatty acid oxidation and dysregulating glycerophospholipid metabolism. These findings highlight the critical impact of anesthetic selection in diabetic populations.