蔗糖调制射频诱导的加热速率和细胞死亡。

Convergent science physical oncology Pub Date : 2017-09-01 Epub Date: 2017-06-22 DOI:10.1088/2057-1739/aa757b
Merlyn Pulikkathara, Colette Mark, Natasha Kumar, Ana Maria Zaske, Rita E Serda
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引用次数: 2

摘要

背景:应用射频(RF)能量诱导组织热疗,促进血管灌注本研究探讨了射频辐射对腔内内皮完整性的影响,然后主要探讨了改变生物相关溶液的电导率对射频诱导的加热速率和细胞死亡的影响。细胞在高蔗糖(即高渗条件)条件下存活以实现低电导率的能力作为指导热疗的机制进行了评估。方法:使用工作频率为13.56 MHz的电容耦合射频系统产生射频辐射。使用FLIR SC 6000红外摄像机记录温度。结果:射频辐射减少了内皮细胞之间的细胞间连接,并改变了细胞形态,使其在温度下呈现更圆的外观,据报道这导致了体内血管变形。与高盐溶液相比,高糖低盐等渗溶液的电导率低,升温速度快。加热速率与细胞死亡呈正相关。向血清中添加蔗糖同样以剂量依赖的方式降低电导率并增加加热速率。细胞在添加125 mM蔗糖的培养基中生长24小时,或在添加750 mM蔗糖的培养基中生长10分钟,然后恢复24小时,细胞增殖正常。结论:已知蔗糖在流体中形成弱氢键,而不是离子,释放水分子在振荡的电磁辐射场中旋转,并有助于热感应。细胞暂时暴露于高渗(即升高的蔗糖)条件下存活的能力创造了使用蔗糖或其他糖类在暴露于射频场时选择性地提高特定组织加热的机会。
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Sucrose modulation of radiofrequency-induced heating rates and cell death.

Background: Applied radiofrequency (RF) energy induces hyperthermia in tissues, facilitating vascular perfusion This study explores the impact of RF radiation on the integrity of the luminal endothelium, and then predominately explores the impact of altering the conductivity of biologically-relevant solutions on RF-induced heating rates and cell death. The ability of cells to survive high sucrose (i.e. hyperosmotic conditions) to achieve lower conductivity as a mechanism for directing hyperthermia is evaluated.

Methods: RF radiation was generated using a capacitively-coupled radiofrequency system operating at 13.56 MHz. Temperatures were recorded using a FLIR SC 6000 infrared camera.

Results: RF radiation reduced cell-to-cell connections among endothelial cells and altered cell morphology towards a more rounded appearance at temperatures reported to cause in vivo vessel deformation. Isotonic solutions containing high sucrose and low levels of NaCl displayed low conductivity and faster heating rates compared to high salt solutions. Heating rates were positively correlated with cell death. Addition of sucrose to serum similarly reduced conductivity and increased heating rates in a dose-dependent manner. Cellular proliferation was normal for cells grown in media supplemented with 125 mM sucrose for 24 hours or for cells grown in 750 mM sucrose for 10 minutes followed by a 24 h recovery period.

Conclusions: Sucrose is known to form weak hydrogen bonds in fluids as opposed to ions, freeing water molecules to rotate in an oscillating field of electromagnetic radiation and contributing to heat induction. The ability of cells to survive temporal exposures to hyperosmotic (i.e. elevated sucrose) conditions creates an opportunity to use sucrose or other saccharides to selectively elevate heating in specific tissues upon exposure to a radiofrequency field.

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