Baldwin S A, Broderick R, Osbourne D, Waeg G, Blades D A, Scheff S W
Sanders-Brown Center on Aging and Department of Neurosurgery, University of Kentucky, Lexington 40536, USA.
J Neurosurg. 1998 May;88(5):874-83. doi: 10.3171/jns.1998.88.5.0874.
The authors tested the hypothesis that breach of the blood-spinal cord barrier (BSCB) will produce evidence of oxidative stress and that a similar staining pattern will be seen between 4-hydroxynonenal (HNE)/protein complexes and extravasated immunoglobulin G (IgG).
Adult female Fischer 344 rats, each weighing 200 to 225 g, were subjected to a spinal cord contusion at T-10 by means of a weight-drop device. Spinal cord tissue was assessed for oxidative stress by localizing extravasated plasma contents with a monoclonal antibody for rat IgG and protein conjugation with HNE, which is an aldehyde byproduct of lipid peroxidation. The animals were killed at 1 and 6 hours, and 1, 2, and 7 days after surgery. Maximum HNE/protein staining was observed at 2 days postinjury, and HNE/protein and IgG manifested similar staining patterns. Analysis revealed a graduated but asymmetrical rostral-caudal response relative to the T-10 injury site. Both HNE/protein complex and IgG staining revealed that the caudal levels T-11 and T-12 stained significantly more intensely than the rostral levels T-9 and T-8, respectively. A higher percentage of neurons positive for HNE/protein immunostaining was observed in spinal cord levels caudal to the injury site compared with equidistant rostral regions. Protein dot-blot assays also revealed a similar asymmetrical rostral-caudal HNE/protein content. To analyze the timing of the BSCB breach, another group of animals received identical contusions, and horseradish peroxidase (HRP) was injected 10 minutes before or at various times after injury (1, 3, and 6 hours, and 1, 2, and 7 days). Maximum HRP permeability was seen immediately after injury, with a significant decrease occurring by 1 hour and a return to control levels by 2 days posttrauma.
Data from this study indicate possible compromise of neuronal, axonal, glial, and synaptic function after trauma, which may be a factor in motor deficits seen in animals after spinal cord contusion. The colocalization of the IgG stain with the HNE/protein stain is consistent with the hypothesis of a mutual cause-effect relationship between BSCB and oxidative stress in central nervous system trauma.
作者检验了以下假设,即血脊髓屏障(BSCB)的破坏会产生氧化应激的证据,并且在4-羟基壬烯醛(HNE)/蛋白质复合物与外渗的免疫球蛋白G(IgG)之间会观察到相似的染色模式。
成年雌性Fischer 344大鼠,体重200至225克,通过重物坠落装置在T-10水平造成脊髓挫伤。通过用大鼠IgG单克隆抗体定位外渗的血浆成分以及与HNE(脂质过氧化的醛副产物)进行蛋白质结合,评估脊髓组织的氧化应激。在术后1小时、6小时以及1天、2天和7天处死动物。损伤后2天观察到最大的HNE/蛋白质染色,并且HNE/蛋白质和IgG表现出相似的染色模式。分析显示相对于T-10损伤部位存在渐进但不对称的头端-尾端反应。HNE/蛋白质复合物和IgG染色均显示,尾端的T-11和T-12水平染色分别明显比头端的T-9和T-8水平更强烈。与等距离的头端区域相比,在损伤部位尾端的脊髓水平观察到更高百分比的神经元对HNE/蛋白质免疫染色呈阳性。蛋白质斑点印迹分析也显示了类似的不对称头端-尾端HNE/蛋白质含量。为了分析BSCB破坏的时间,另一组动物接受相同的挫伤,并在损伤前10分钟或损伤后不同时间(1小时、3小时和6小时以及1天、2天和7天)注射辣根过氧化物酶(HRP)。损伤后立即观察到最大的HRP通透性,1小时时显著降低,创伤后2天恢复到对照水平。
本研究数据表明创伤后神经元、轴突、神经胶质和突触功能可能受损,这可能是脊髓挫伤后动物出现运动功能障碍的一个因素。IgG染色与HNE/蛋白质染色的共定位与中枢神经系统创伤中BSCB与氧化应激之间存在相互因果关系的假设一致。