Laser Pulse Duration Optimization for Photothermal Therapy with Gold Nanostars

International Journal of Medical Physics, Clinical Engineering and Radiation Oncology Pub Date : 2018-06-04 DOI:10.4236/IJMPCERO.2018.73032

Juntao Cao

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引用次数: 1

Abstract

Photothermal therapy (PTT), which utilizes light radiation to create localized heating effect in the targeted areas, is a promising solution for highly specific yet minimally invasive cancer therapy. PTT uses photothermal agents, which are usually nanoparticles that absorb strongly in the near-infrared optical window where minimal tissue absorption occurs. Photothermal agents are also highly functionalized to target at specific tumor sites. Gold nanostar is an ideal candidate for photothermal agents, because it not only has a Surface Plasmon Resonance in the near-infrared, but also can be easily produced and purified, and is extremely versatile in the drug delivery process. In order to achieve maximum amount of localized heating, pulse lasers are usually used in laser ablation processes like photothermal therapy. However, intensive laser radiation can cause damage to regular tissues as well the nanostructures themselves. Therefore, identifying the optimal pulse duration to effectively generate localized heating in the tumorous tissues while keeping the normal tissues and the nanostructures intact is important to achieving optimal photo-therapeutic results. This manuscript provides a numerical calculation method with Comsol Multiphysics to optimize the pulse condition of the gold nanostars under photothermal therapy settings. Based on results, gold nanostar displays significant temperature heterogeneity under femtosecond and picosecond laser radiation, while nanosecond laser only induces rather uniform heating effects across the entire gold nanostar particle. This finding indicates that femtosecond laser, which is the most common type of laser used for ablation, is likely to melt the tip of the gold nanostar before the nanostar body reaches a reasonably high temperature. Picosecond and nanosecond lasers are much less likely to induce such dramatic morphology change. This study offers important insight into finding the optimal condition for photothermal therapy with maximal efficacy and minimal damage.

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纳米金光热治疗激光脉冲持续时间优化

光热疗法(PTT)利用光辐射在目标区域产生局部热效应，是一种很有前途的高特异性微创癌症治疗方案。PTT使用光热剂，通常是纳米颗粒，在近红外光学窗口中吸收强烈，组织吸收最小。光热剂也被高度功能化以靶向特定的肿瘤部位。金纳米星是光热剂的理想候选者，因为它不仅具有近红外表面等离子体共振，而且易于生产和纯化，并且在给药过程中用途广泛。为了实现最大限度的局部加热，脉冲激光器通常用于光热治疗等激光消融过程。然而，强烈的激光辐射会对常规组织以及纳米结构本身造成损害。因此，确定最佳脉冲持续时间，在保持正常组织和纳米结构完整的情况下，有效地在肿瘤组织中产生局部加热，对于获得最佳光疗效果非常重要。本文利用Comsol Multiphysics软件，采用数值计算的方法对光热环境下金纳米晶体的脉冲条件进行了优化。结果表明，在飞秒和皮秒激光照射下，金纳米颗粒的温度呈现出明显的非均匀性，而纳秒激光仅在整个金纳米颗粒中产生较为均匀的加热效应。这一发现表明，飞秒激光是最常用的烧蚀激光，很可能在纳米星体达到合理的高温之前熔化金纳米星的尖端。皮秒和纳秒激光不太可能引起这种剧烈的形态变化。这项研究为寻找光热治疗的最佳条件提供了重要的见解，以获得最大的疗效和最小的损伤。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Medical Physics, Clinical Engineering and Radiation Oncology

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