Radiolysis, Photolysis and Sonolysis of Cells and their

细胞的辐射分解、光解和声分解及其作用

• 批准号: 6947124
• 负责人: PETER RIESZ
• 金额: --
• 依托单位: DIVISION OF CLINICAL SCIENCES - NCI
• 依托单位国家: 美国
• 资助国家: 美国
• 起止时间: 至
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/6947124
• 关键词: chemical models; chemosensitizing agent; combination cancer therapy; cytolysis; drug interactions; electron spin resonance spectroscopy; free radical oxygen; free radical scavengers; neoplasm /cancer thermotherapy; physical chemical interaction; porphyrins; surfactant; temperature; tissue /cell culture; ultrasound biological effect; ultrasound therapy

Sonodynamic therapy is a promising new modality for cancer treatment based on the synergistic effects of cell killing by a combination of sonosensitzer and ultrasound. Ultrasound can penetrate deeply into tissue and can be focused in a small region of tumor to activate non-toxic molecules (e.g. porphyrins ) thus minimizing undesirable side effects. The experimental evidence suggests that sonosensitization is due to the chemical activation of sonosensitizers inside or in close vicinity of hot collapsing cavitation bubbles to form sensitizer-derived radicals either by direct pyrolysis of the sensitizer at the water-gas interface or due to the reactions of hydrogen atoms and hydroxyl radicals formed by the pyrolysis of water. The free radicals derived from the sonosensitizer (mostly carbon-centered) react with oxygen to form peroxyl and alkoxyl radicals. Unlike OH radicals and H atoms which are formed by pyrolysis inside cavitation bubbles, the reactivity of alkoxyl and peroxyl radicals with organic compounds in biological media is much lower and hence they have a higher probability of reaching critical cellular sites. The synergistic effect of ultrasound (47 kHz) and analogues of gallium-porphyrin derivatives (ATX-70) on cytolysis of human leukemia cells (HL-525 and HL-60) suspended in a cell culture medium were studied. Organic surfactants preferentially accumulate and subsequently decompose at the gas/solution interface of cavitation bubble, producing secondary radicals that can diffuse to the bulk solution. The gallium porphyrin analogues used in the current study possessed two n-alkyl side chains (ATX-Cx, where x = number of carbon atoms, ranging from x = 2 to x = 12). By varying the n-alkyl chain length, thereby modifying the surfactant properties of the ATX-Cx derivatives, cell killing in relation to the accumulation of the ATX-Cx derivatives at the gas/solution interface of cavitation bubbles was determined. Following sonolysis in the presence of the ATX-Cx, a strong correlation for the yield of carbon centered radicals and cell killing was observed. These results support the hypothesis that a sonochemical mechanism is responsible for the synergistic effect of ultrasound and ATX-Cx on HL-525 and HL-60 cells.

基于超声与声敏器联合杀伤细胞的协同效应，声动力治疗是一种很有前景的癌症治疗新方式。超声波可以深入组织，并可以聚焦在肿瘤的一个小区域，以激活无毒分子（如卟啉），从而最大限度地减少不良的副作用。实验证据表明，声敏化是由于在热坍缩空化泡内部或附近的声敏化剂被化学激活，通过在水气界面直接热解敏化剂或通过水的热解形成氢原子和羟基自由基的反应而形成敏化剂衍生自由基。来自声敏剂的自由基（主要以碳为中心）与氧反应形成过氧基和烷氧基自由基。与在空化泡内通过热解形成的OH自由基和H原子不同，烷氧基和过氧基自由基在生物介质中与有机化合物的反应活性要低得多，因此它们到达细胞关键部位的可能性更高。