Cardiac neuromodulation with acute intermittent hypoxia in rats with spinal cord injury

IF 4.7 2区医学 Q1 NEUROSCIENCES

Journal of Physiology-London Pub Date : 2025-03-22 DOI:10.1113/JP287676

Mehdi Ahmadian, Erin Erskine, Christopher R. West

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引用次数: 0

Abstract

It is well recognized that the interruption in bulbospinal sympathetic projections is the main cause of cardiovascular instability in individuals and experimental animals with spinal cord injury (SCI). Whether interrupted bulbospinal sympathetic projections contribute to cardiac dysfunction directly (i.e. input to the heart) or indirectly (i.e. vascular influences that alter loading conditions on the heart) post-SCI remains unknown, as does the potential effect of SCI-induced alterations in parasympathetic control on heart function. We employed a sequential pharmacological blockade approach to bridge this knowledge gap and additionally examined whether acute intermittent hypoxia (AIH) is capable of neuromodulating the heart post-SCI. In two experiments, rats were given T3 contusion SCI and survived for 2 weeks. At 2 weeks post-SCI, rats were instrumented with left ventricular and arterial catheters to assess cardiovascular function in response to either a sequential pharmacological blockade targeting different sites of the autonomic neuraxis (experiment 1) or AIH (experiment 2). The findings from experiment 1 revealed that impaired direct sympathetic transmission to the heart underlies the majority of the SCI-induced reduction in heart function post-SCI. The findings from experiment 2 revealed that a single-session of AIH increased left ventricular pressure generation and arterial blood pressure immediately and up to 90 min post-AIH. Together, our findings demonstrate that disrupted bulbospinal sympathetic pathways contribute directly to the SCI-induced impairment in left ventricular function. We also show that a single session of AIH is capable of neuromodulating the heart post-SCI.

Key points

The loss of sympathetic transmission to the heart is the main cause of reduced cardiac function in a rodent model of spinal cord injury (SCI).
Parasympathetic control remains unaltered post-SCI and does not contribute to reduced cardiac function post-SCI.
Acute intermittent hypoxia neuromodulates the heart and increases left ventricular pressure generating capacity.

Abstract Image

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众所周知，球神经交感神经投射的中断是脊髓损伤（SCI）患者和实验动物心血管不稳定的主要原因。脊髓损伤后球神经交感神经投射的中断是直接（即对心脏的输入）还是间接（即改变心脏负荷条件的血管影响）导致心脏功能障碍，以及脊髓损伤引起的副交感神经控制改变对心脏功能的潜在影响，目前仍是未知数。我们采用了一种连续的药理阻断方法来弥补这一知识空白，并进一步研究了急性间歇性缺氧（AIH）是否能够对 SCI 后的心脏进行神经调节。在两项实验中，大鼠接受了 T3 挫伤性 SCI，并存活了 2 周。在SCI后2周，大鼠被植入左心室和动脉导管，以评估心血管功能对针对自律神经轴不同部位的连续药物阻断（实验1）或AIH（实验2）的反应。实验 1 的结果显示，交感神经对心脏的直接传导受损是 SCI 引起的 SCI 后心脏功能下降的主要原因。实验 2 的结果表明，单次 AIH 会立即增加左心室压力的产生，并在 AIH 后 90 分钟内增加动脉血压。总之，我们的研究结果表明，球神经交感通路的破坏直接导致了 SCI 引起的左心室功能损害。我们还表明，单次 AIH 能够对 SCI 后的心脏进行神经调节。要点：在脊髓损伤（SCI）的啮齿动物模型中，心脏交感神经传导的丧失是导致心脏功能减退的主要原因。副交感神经控制在脊髓损伤后保持不变，不会导致脊髓损伤后心脏功能减退。急性间歇性缺氧会对心脏进行神经调节并增加左心室的压力生成能力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Physiology-London 医学-神经科学

CiteScore

9.70

自引率

7.30%

发文量

817

审稿时长

2 months

期刊介绍： The Journal of Physiology publishes full-length original Research Papers and Techniques for Physiology, which are short papers aimed at disseminating new techniques for physiological research. Articles solicited by the Editorial Board include Perspectives, Symposium Reports and Topical Reviews, which highlight areas of special physiological interest. CrossTalk articles are short editorial-style invited articles framing a debate between experts in the field on controversial topics. Letters to the Editor and Journal Club articles are also published. All categories of papers are subjected to peer reivew. The Journal of Physiology welcomes submitted research papers in all areas of physiology. Authors should present original work that illustrates new physiological principles or mechanisms. Papers on work at the molecular level, at the level of the cell membrane, single cells, tissues or organs and on systems physiology are all acceptable. Theoretical papers and papers that use computational models to further our understanding of physiological processes will be considered if based on experimentally derived data and if the hypothesis advanced is directly amenable to experimental testing. While emphasis is on human and mammalian physiology, work on lower vertebrate or invertebrate preparations may be suitable if it furthers the understanding of the functioning of other organisms including mammals.