Role of Musculo-Dynamics in Bone Fluid Flow, Circulation and Adaptation

肌肉动力学在骨液流动、循环和适应中的作用

• 批准号: 7478697
• 负责人: Yi-Xian Qin
• 金额: $ 32.41万
• 依托单位: STATE UNIVERSITY NEW YORK STONY BROOK
• 依托单位国家: 美国
• 财政年份: 2005
• 资助国家: 美国
• 起止时间: 2005-08-01 至 2010-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7478697
• 关键词: Animals; Area; Arteries; Atrophic; Bed rest; Blood Circulation; Blood capillaries; Blood flow; Bone Formation Inhibition; Bone Surface; Bone remodeling; Cell Count; Cell Line; Cell Nucleus; Cells; Condition; Contralateral; Daily; Devices; Exercise; Femur; Filtration; Fracture Healing; Frequencies; Goals; Growth Factor; Histology; Immobilization; Infiltration; Injury; Intercellular Fluid; Intervention; Ischemia; Isometric Exercise; Leg; Limb structure; Liquid substance; Marrow; Measurement; Measures; Mechanics; Mediating; Mediator of activation protein; Microcirculation; Microgravity; Microspheres; Mitochondria; Modeling; Molecular; Monitor; Muscle; Muscle Contraction; Muscular Atrophy; Musculoskeletal; Nuclear; Nutrient; Optics; Osteogenesis; Osteoporosis; Oxygen; Pattern; Perfusion; Physiological; Porosity; Prosthesis; Protocols documentation; Pump; Rate; Rattus; Research Personnel; Rest; Role; Series; Shapes; Signal Transduction; Skeletal Muscle; Skeletal bone; Skeletal system; Stimulus; Surface; Suspension substance; Suspensions; Testing; Tissues; Transmission Electron Microscopy; Treatment Protocols; Vascular blood supply; Venous; Week; Work; base; bone; bone loss; bone turnover; capillary; cell growth; day; density; design; fluid flow; improved; in vivo Model; muscle strength; pressure; prevent; research study; response; restoration; shear stress; voltage; wasting

DESCRIPTION (provided by applicant): Musculoskeletal microvascular circulations supply nutrients, oxygen and physiological flow to and move waste from muscle and bone. Musculoskeletal complications, induced by reduced microcirculation in the condition during injury and functional disuse (e.g., bedrest and microgravity), have significant physiological effects in muscle atrophy and osteopenia. Exercise such as muscle contraction appears to increase blood flow to the skeletal tissues, i.e., bone and muscle. Musculo-dynamics induced bone fluid flow is proposed as a critical mediator in initiating and regulating osteonal adaptation. Using oscillatory pressurized marrow fluid flow stimuli, the physiological fluid stimulus was found to initiate new bone formation and reduce intracortical bone porosities caused by disuse, even in the absence of direct tissue strain. While bone remodeling was demonstrated to be sensitive to high rate of dynamic physiological stimulation, the role of fluid flow in both bone and muscle perhaps explains, at least in part, the cellular response mechanism to anabolic stimuli. In the work proposed, we will examine the general hypothesis that skeletal musculocirculation, mediated at dynamic functional stimulation, serves as a dynamic muscle pump and a critical mediator for bone fluid flow, which controls and promotes osteogenic and muscular adaptation. Indeed, improving our understanding the roles of muscular dynamics (e.g., frequency and magnitude of muscle contraction), circulations, and fluid flow through bone may help to devise a biomechanically based intervention for treating osteoporosis, muscle atrophy, and accelerating fracture healing or promoting bony ingrowth into prostheses. In this application, the goal will be achieved by a series of sub-hypotheses and specific aims: (1) Dynamic interstitial fluid flow can be initiated and enhanced by functional contraction of skeletal muscle. Functional muscle contraction serves as a dynamic pump to generate intramedullary pressure and regulates venous return, which initiate fluid flow in bone. (2) Bone fluid flow induced by musculo-dynamic stimulation can initiate surface adaptive response and inhibit intracortical bone loss in a disuse bone. The adaptive response will be sensitive to the rate of loading patterns. (3) Osteogenic response to anabolic fluid flow stimuli induced by muscle-pump is dependent on generated fluid pressure magnitude and loading duration. (4) The potentials of dynamic patterns of muscle stimuli can initiate muscular adaptation, in which loads induced at the physiological level will increase capillary density and substantially increase blood flow in muscle, while overloading will cause partial musculovascular atrophy following bone bloodflow ischemia. (5) Fluid infiltration in muscle and bone can be optimized by insertion of rest preiod during dynamic loading, which reduce the fluid saturation and improve perfusion. (6) The osteogenic potentials response to fluid flow stimuli is initiated by osteoblastic activation of bone lining cells, following a daily but short duration (e.g., <10 days) of loading. Ultrastructural osteoblastic features of cell and nuclei will be examined via histomorphometric analysis of cell area, nuclear area, cell number, cell and nuclei shapes, in which associated fluid components will be identified.

描述（由申请人提供）：肌肉骨骼微血管循环提供营养，氧气和生理流动，并从肌肉和骨骼中移动废物。损伤和功能废用（如卧床和微重力）时微循环减少引起的肌肉骨骼并发症对肌肉萎缩和骨质减少有显著的生理影响。肌肉收缩等运动似乎可以增加骨骼组织（即骨骼和肌肉）的血流量。肌肉动力学诱导的骨液流动被认为是启动和调节骨适应的关键介质。使用振荡加压骨髓液流刺激，即使在没有直接组织应变的情况下，生理液体刺激也能启动新骨形成并减少因废弃而引起的皮质内骨孔隙。虽然骨重塑被证明对高速率的动态生理刺激敏感，但骨骼和肌肉中流体流动的作用可能至少部分地解释了细胞对合成代谢刺激的反应机制。在提出的工作中，我们将检验在动态功能刺激下介导的骨骼肌循环作为动态肌肉泵和骨液流动的关键介质的一般假设，骨液流动控制并促进成骨和肌肉适应。事实上，提高我们对肌肉动力学（例如，肌肉收缩的频率和幅度）、循环和骨内液体流动的作用的理解可能有助于设计基于生物力学的干预措施来治疗骨质疏松症、肌肉萎缩、加速骨折愈合或促进骨长入假体。