流体压力和流动是导致骨吸收的原因。

Fluid pressure and flow as a cause of bone resorption.

机构信息

Division of Orthopaedics, Department of Clinical and Experimental Medicine, Linköping University, Linköping, Sweden.

出版信息

Acta Orthop. 2010 Aug;81(4):508-16. doi: 10.3109/17453674.2010.504610.

DOI:10.3109/17453674.2010.504610

PMID:20718695

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2917576/

Abstract

BACKGROUND

Unstable implants in bone become surrounded by an osteolytic zone. This is seen around loose screws, for example, but may also contribute to prosthetic loosening. Previous animal studies have shown that such zones can be induced by fluctuations in fluid pressure or flow, caused by implant instability.

METHOD

To understand the roles of pressure and flow, we describe the 3-dimensional distribution of osteolytic lesions in response to fluid pressure and flow in a previously reported rat model of aseptic loosening. 50 rats had a piston inserted in the proximal tibia, designed to produce 20 local spikes in fluid pressure of a clinically relevant magnitude (700 mmHg) twice a day. The spikes lasted for about 0.3 seconds. After 2 weeks, the pressure was measured in vivo, and the osteolytic lesions induced were studied using micro-CT scans.

RESULTS

Most bone resorption occurred at pre-existing cavities within the bone in the periphery around the pressurized region, and not under the piston. This region is likely to have a higher fluid flow and less pressure than the area just beneath the piston. The velocity of fluid flow was estimated to be very high (roughly 20 mm/s).

INTERPRETATION

The localization of the resorptive lesions suggests that high-velocity fluid flow is important for bone resorption induced by instability.

摘要

背景

不稳定的植入物在骨中会被一个溶骨区域包围。例如，松动的螺钉周围就会出现这种情况，但也可能导致假体松动。以前的动物研究表明，这种区域可能是由植入物不稳定引起的流体压力或流动的波动引起的。

方法

为了了解压力和流动的作用，我们描述了在以前报道的无菌性松动大鼠模型中，针对流体压力和流动，溶骨病变的三维分布。50 只大鼠的胫骨近端插入一个活塞，设计每天产生两次临床相关幅度（700mmHg）的 20 个局部压力尖峰。尖峰持续约 0.3 秒。2 周后，在体内测量压力，并使用 micro-CT 扫描研究诱导的溶骨病变。

结果

大多数骨吸收发生在受压区域周围骨内的预先存在的腔中，而不是在活塞下。该区域的流体流动速度可能比活塞下方的区域高，压力也较低。估计流体流动速度非常高（约 20mm/s）。

解释

吸收性病变的定位表明，高速流体流动对于由不稳定性引起的骨吸收很重要。

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流体压力和流动是导致骨吸收的原因。

Fluid pressure and flow as a cause of bone resorption.

机构信息

出版信息

BACKGROUND

METHOD

RESULTS

INTERPRETATION

背景

方法

结果

解释

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