Masuoka Kazunori, Michalek Arthur J, MacLean Jeffrey J, Stokes Ian A F, Iatridis James C
University of Vermont, Burlington, VT 05405, USA.
Spine (Phila Pa 1976). 2007 Aug 15;32(18):1974-9. doi: 10.1097/BRS.0b013e318133d591.
In vitro biomechanical study on rat caudal motion segments to evaluate association between compressive loading and water content under static and cyclic conditions.
To test hypotheses: 1) there is no difference in height loss and fluid (volume) loss of discs loaded in compression under cyclic (0.15-1.0 MPa) and static conditions with the same root-mean-square (RMS) magnitudes (0.575 MPa); and 2) after initial disc bulge, tissue water loss is directly proportional to height loss under static loading.
Disc degeneration affects water content, elastic and viscoelastic behaviors. There is limited understanding of the association between transient water loss and viscoelastic creep in a controlled in vitro environment where inferences may be made regarding mechanisms of viscoelasticity.
A total of 126 caudal motion segments from 21 Wistar rats were tested in compression using 1 of 6 protocols: Static loading at 1.0 MPa for 9, 90, and 900 minutes, Cyclic loading at 0.15 to 1.0 MPa/1 Hz for 90 minutes, Mid-Static loading at 0.575 MPa for 90 minutes, and control. Water content was then measured in anulus and nucleus regions.
Percent water loss was significantly greater in nucleus than anulus regions, suggesting some water redistribution, with average values under 1 MPa static loading of 23.0% and 14.9% after 90 minutes and 26.9% and 17.6% after 900 minutes, respectively. Cyclic loading resulted in significantly greater height loss (0.506 +/- 0.108 mm) than static loading with the same RMS value (0.402 +/- 0.096 mm), but not significantly less than static loading at peak value (0.539 +/- 0.122 mm). Significant and strong correlations were found between percent water loss and disc height loss, suggesting water was lost through volume decrease.
Peak magnitude of cyclic compression and not RMS value was most important in determining height change and water loss, likely due to differences between disc creep and recovery rates. Water redistribution from nucleus to anulus occurred under loading consistent with an initial elastic compression (and associated disc bulge) followed by a reduction in disc volume over time.
对大鼠尾椎运动节段进行体外生物力学研究,以评估静态和循环条件下压缩负荷与含水量之间的关系。
检验以下假设:1)在循环(0.15 - 1.0兆帕)和静态条件下,以相同均方根(RMS)大小(0.575兆帕)加载压缩的椎间盘,其高度损失和液体(体积)损失没有差异;2)在初始椎间盘膨出后,静态加载下组织水分损失与高度损失成正比。
椎间盘退变会影响含水量、弹性和粘弹性行为。在可控的体外环境中,对于瞬态水分损失与粘弹性蠕变之间的关系了解有限,在此环境中可以对粘弹性机制进行推断。
使用6种方案中的1种,对来自21只Wistar大鼠的总共126个尾椎运动节段进行压缩测试:1.0兆帕静态加载9、90和900分钟,0.15至1.0兆帕/1赫兹循环加载90分钟,0.575兆帕中期静态加载90分钟,以及对照组。然后测量纤维环和髓核区域的含水量。
髓核区域的水分损失百分比显著高于纤维环区域,表明存在一些水分重新分布,在1兆帕静态加载下,90分钟后的平均值分别为23.0%和14.9%,900分钟后分别为26.9%和17.6%。与相同RMS值的静态加载(0.402 +/- 0.096毫米)相比,循环加载导致的高度损失显著更大(0.