Trunk muscle control of human lumbar spine stability

躯干肌肉控制人体腰椎稳定性

• 批准号: 217379-2006
• 负责人: Potvin, James
• 金额: $ 1.22万
• 依托单位: McMaster University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2008
• 资助国家: 加拿大
• 起止时间: 2008-01-01 至 2009-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=393239
• 关键词: Trunk; muscle; control; human; lumbar

The spine is a very complex biological and mechanical structure. The lumbar spine, or low back, is particularly susceptible to injury and pain and has been the focus of a great deal of research attempting to understand how it operates and how work and everyday activities can lead to tissue damage. When loads are handled, the body must find a way to use the many muscles and ligaments of the spine to perform the task with a number of objectives that must be considered. First, we want to keep the metabolic cost low. Next, we need to select from a large number of combinations of muscle forces that will successfully complete the task. Finally, we must recruit muscles that will maintain some level of stability in the lumbar spine so that it does not buckle. Often, these three objects conflict with each other. The purpose of this research is to further our understanding of how the body resolves these three different objectives and, in particular, what role mechanical spine stability plays under a variety of loading conditions. In particular, sudden trunk loading and prolonged, fatiguing tasks have been found to be particularly good perturbations for studying spine stability. We plan to use a variety of these types of perturbations to challenge the spine and further our knowledge of how we maintain stability in an effort to avoid injury. First, we will have to further refine a complex computer model of the spine, including its muscles, vertebrae and ligaments. This model will allow for stability to be calculated about the lowest six joints of the spine and about each of the three anatomical axes (flexion/extension, lateral bend, axial twist). Next, we will use this model and muscle electromyography to predict individual muscle forces and stability contributions for a wide variety of trunk perturbations. Subjects will be exposed to sudden and prolonged loading through force rapidly applied to a chest harness, to hand held loads and through movement of a robotic platform on which they will sit. The long term objective of the proposed research is to reduce low back injuries through a further understanding of trunk muscle contributions to lumbar spine mechanics.

脊柱是一个非常复杂的生物和机械结构。腰椎或下背部特别容易受伤和疼痛，并且一直是大量研究的重点，试图了解它是如何运作的，以及工作和日常活动如何导致组织损伤。当负荷处理，身体必须找到一种方法来使用脊柱的许多肌肉和韧带来执行任务，必须考虑一些目标。首先，我们希望保持低代谢成本。接下来，我们需要从大量的肌肉力量组合中进行选择，以成功完成任务。最后，我们必须招募肌肉，以保持腰椎的稳定性，使其不会弯曲。通常，这三个对象相互冲突。本研究的目的是进一步了解身体如何解决这三个不同的目标，特别是在各种负荷条件下，脊柱机械稳定性起着什么作用。特别是，突然的躯干负荷和长时间的疲劳任务已被发现是研究脊柱稳定性的特别好的扰动。我们计划使用各种类型的扰动来挑战脊柱，并进一步了解我们如何保持稳定性以避免受伤。首先，我们必须进一步完善脊柱的复杂计算机模型，包括其肌肉，椎骨和韧带。该模型将允许计算脊柱最低六个关节和三个解剖轴（屈曲/伸展、侧向弯曲、轴向扭转）的稳定性。接下来，我们将使用这个模型和肌肉肌电图来预测各种躯干扰动的个体肌肉力量和稳定性贡献。受试者将通过快速施加到胸带上的力、手持负载以及通过他们将坐在其上的机器人平台的移动而暴露于突然和长时间的负载。这项研究的长期目标是通过进一步了解躯干肌肉对腰椎力学的贡献来减少腰部损伤。