Randeberg Lise Lyngsnes, Winnem Andreas M, Langlois Neil E, Larsen Eivind L P, Haaverstad Rune, Skallerud Bjørn, Haugen Olav A, Svaasand Lars O
Department of Electronics and Telecommunications, Norwegian University of Science and Technology, N-7491 Trondheim, Norway.
Lasers Surg Med. 2007 Jun;39(5):403-13. doi: 10.1002/lsm.20494.
Bruises are currently evaluated by visual inspection, and little is known about the first phase after injury. The temporal development of fresh injuries must be accurately described to be able to age bruises in a reliable manner. Color changes in a bruise caused by hemoglobin breakdown products will depend on the severity of the trauma, and thus on the local immune response in the skin. It is therefore important to relate the nature of the impact to the temporal tissue responses.
Controlled injuries were inflicted on anesthetized domestic pigs. Trauma was induced either by a pendulum device, or by paintballs released using pressurized air. The speed of the projectiles was recorded using a high speed camera. Biopsies and reflection spectra (400-850 nm) were collected from normal and bruised skin. The experiments were approved by the national animal research authority.
The temporal development of the injury was found to depend strongly on the weight and speed of the object. Low speed, blunt objects did not cause persistent skin changes. However, deep muscular bleeding could be found in most cases. High speed, light weight objects caused a rapidly developing bruise. These bruises were fully developed within 15-20 minutes. No deep muscular hemorrhages were observed in those cases. White blood cells (neutrophilic granulocytes) could be found in biopsies from high speed injuries. The amount of white blood cells depended on the time between injury and collection of the biopsies.
Further investigations utilizing a larger range of object weight and velocities are required to be able to fully classify minor traumatic injuries. Preliminary results indicate that this can be achieved by controlled experiments using a porcine model. Reflectance spectroscopy was found to be a useful tool to study immediate skin reactions to the trauma.
目前瘀伤是通过目视检查进行评估的,而对于损伤后的第一阶段了解甚少。必须准确描述新鲜损伤的时间发展过程,以便能够可靠地判断瘀伤的形成时间。由血红蛋白分解产物引起的瘀伤颜色变化将取决于创伤的严重程度,进而取决于皮肤中的局部免疫反应。因此,将撞击的性质与组织的时间反应联系起来很重要。
对麻醉后的家猪造成可控损伤。通过摆锤装置或使用压缩空气发射彩弹来诱导创伤。使用高速摄像机记录弹丸的速度。从正常皮肤和瘀伤皮肤采集活检样本和反射光谱(400 - 850纳米)。这些实验得到了国家动物研究管理部门的批准。
发现损伤的时间发展在很大程度上取决于物体的重量和速度。低速、钝性物体不会导致皮肤出现持续性变化。然而,在大多数情况下可发现深部肌肉出血。高速、轻质物体导致瘀伤迅速形成。这些瘀伤在15 - 20分钟内完全形成。在这些情况下未观察到深部肌肉出血。在高速损伤的活检样本中可发现白细胞(中性粒细胞)。白细胞的数量取决于损伤与采集活检样本之间的时间。
需要进一步开展利用更大范围物体重量和速度的研究,以便能够对轻度创伤性损伤进行全面分类。初步结果表明,这可以通过使用猪模型进行对照实验来实现。发现反射光谱是研究皮肤对创伤即时反应的有用工具。