Szabo Imre, Kappelmayer Janos, Alekseev Stanislav I, Ziskin Marvin C
Center for Biomedical Physics, Temple University School of Medicine, Philadelphia, Pennsylvania 19140, USA.
Bioelectromagnetics. 2006 Apr;27(3):233-44. doi: 10.1002/bem.20202.
In vitro exposure of refrigerated samples (4 degrees C) of anti-coagulated blood with millimeter waves (MMWs) at incident power densities (IPDs) between 0.55 and 1.23 W/cm2 has been found to induce clot formation. We found a small but statistically significant change in clot size with increasing IPD value. MMW exposure of blood samples starting at room temperature (22 degrees C) did not induce blood coagulation; neither did conventional heating at temperatures up to 40 degrees C. Since cell-free plasma did not clot upon MMW exposure, the role of blood cells was particularly analyzed. Experiments on various mixtures of blood cells with plasma revealed an important role of red blood cells (RBC) in the coagulation process. Plasma coagulation also developed within the MMW beam above dense keratinocyte (HaCaT) monolayers suggesting it lacked cell-type specificity. We hypothesized that alteration of the membrane surface in exposed cells might be responsible for the circumscribed coagulation. The thrombogenic role of externalized phosphatidylserine (PS) molecules is well known. Therefore, we carried out experiments for immunolabeling PS molecules with fluorescein isothiocyanate (FITC)-conjugated Annexin V on exposed cells. Fluorescence microscopy of the adherent human keratinocytes (HaCaT) and murine melanoma cells (B16F10) showed that MMW exposure at an IPD of 1.23 W/cm2 is capable of inducing reversible externalization of PS molecules in cells within the beam area without detectable membrane damage. Nonadherent Jurkat cells exposed to MMW at an IPD of 34.5 mW/cm2 also showed reversible PS externalization with flow cytometry, whether the cell temperature was held constant or permitted to rise. These results suggest that certain biological effects induced by MMWs could be initiated by membrane changes in exposed cells.
已发现,在0.55至1.23W/cm²的入射功率密度(IPD)下,用毫米波(MMW)对冷藏(4℃)的抗凝血液样本进行体外照射会诱导血栓形成。我们发现,随着IPD值的增加,血栓大小有微小但具有统计学意义的变化。从室温(22℃)开始对血液样本进行MMW照射不会诱导血液凝固;在高达40℃的温度下进行传统加热也不会诱导血液凝固。由于无细胞血浆在MMW照射下不会凝固,因此特别分析了血细胞的作用。对血细胞与血浆的各种混合物进行的实验表明,红细胞(RBC)在凝血过程中起重要作用。在致密角质形成细胞(HaCaT)单层上方的MMW光束内也会发生血浆凝固,这表明它缺乏细胞类型特异性。我们推测,暴露细胞的膜表面改变可能是局限性凝血的原因。外化磷脂酰丝氨酸(PS)分子的促血栓形成作用是众所周知的。因此,我们进行了实验,用异硫氰酸荧光素(FITC)偶联的膜联蛋白V对暴露细胞上的PS分子进行免疫标记。对贴壁的人角质形成细胞(HaCaT)和鼠黑色素瘤细胞(B16F10)进行荧光显微镜检查显示,在1.23W/cm²的IPD下进行MMW照射能够诱导光束区域内细胞中PS分子的可逆外化,且未检测到膜损伤。无论细胞温度保持恒定还是允许升高,以34.5mW/cm²的IPD暴露于MMW的非贴壁Jurkat细胞通过流式细胞术也显示出可逆的PS外化。这些结果表明,MMW诱导的某些生物学效应可能是由暴露细胞的膜变化引发的。
