该研究得到了美国国家科学基金会（第2039014号）和美国国家癌症研究所（R37CA269622）的资助。

1. 建立双极射频系统模型
<ol><li>设置界面的初步步骤<ol><li>启动 COMSOL Multiphysics ，然后单击 Model Wizard。</li>
		<li>选择“ 3D ”作为 空间维度。</li>
		<li>选择 AC/DC 物理模块 |电场和电流 |电流。</li>
		<li>选择 传热模块 |固体中的传热。</li>
		<li>选择 数学模块 |偏微分方程接口 |系数形式：偏微分方程。</li>
		<li>选择 学习 |与时间相关。单击 “完成”。</li>
		<li>一旦 Comsol 工作空间出现：<ol><li>选择 多物理场 |电磁加热。通过此步骤，电磁功率损失密度自动耦合为生物传热方程的热源。 注意：如果 多物理场 未自动显示，请手动指定 电磁热源 （在 COMSOL 中显示为 体积损失密度）。有关如何添加热源的更多详细信息，请参阅“物理”部分，步骤 2“热问题的设置”。</li>
			<li>从顶部功能区选择“学习” |学习步骤 |频率瞬态。</li>
		</ol></li>
	</ol></li>
	<li>定义几何图形。从顶部功能区中，选择“ 几何图形”，然后：<ol><li>使用 表 2 中列出的尺寸定义两个圆锥体。</li>
		<li>将锥体放置在 表 2 中指示的距离处（间隔 d彼此之间 ）。这两个视锥体将对用于构建双极射频系统的两根皮下注射针进行建模。</li>
		<li>复制前两个圆锥体以模拟针的绝缘性;根据 表 2 中报告的尺寸修改圆锥体的尺寸。</li>
		<li>选择一个圆柱体（高度， hm 和直径 dm）来模拟放置在 z = - 9 mm （x = 0， y = 0） 处的大部分肌肉。 表 2 中列出了每个维度的值。</li>
		<li>选择一个圆柱体（高度、 hs 和直径 ds）来模拟放置在 z = 4 mm （x = 0， y = 0） 处的薄层皮肤。 表 2 中列出了每个维度的值。</li>
		<li>选择一个球体（直径，d，t）来模拟放置在z = -0.5 mm（x = 0，y = 0）处的皮下肿瘤。肿瘤的大小列于表2中。</li>
		<li>为了便于在协议的后续步骤中选择几何形状，我们建议采取以下措施：<ol><li>从 “几何图形 ”功能区中，选择“ 虚拟操作”|”形成复合域。</li>
			<li>选择与针的导电部分相关的所有域，以创建复合几何图形。</li>
			<li>重复相同的过程，为针绝缘几何形状创建复合域。</li>
		</ol></li>
	</ol></li>
	<li>定义生物组织模型的属性。 注意：以下步骤描述了实现公式 （2）-（7） 描述的数学表达式的过程。<ol><li>在 “组件”节点中，右键单击以选择 “定义”。</li>
		<li>在 “函数”下，选择 “分析”。<ol><li>指定函数的名称（例如，k_muscle或sigma_muscle），并键入与公式 2 一致的数学表达式。</li>
			<li>指定 温度 （T） 作为 参数。</li>
			<li>指定函数的单位：在电导率的情况下为 S/m。</li>
			<li>重复前面的步骤 1 到 3 以实现方程 3，并相应地修改单位（即， W/（m·K） 表示 热导率）。</li>
			<li>指定参数的单位：K（开尔文）表示温度。在“绘图参数”中，指定函数参数的值范围（即温度）。要遵循此协议，请使用 33-100 °C （306.15-373.15 K） 的范围。</li>
			<li>重复前面的步骤 1 到 5，使用表 1 中列出的标称值（正常组织是指肌肉和皮肤）添加电导率（方程 2）和热导率（方程 3）的温度依赖性函数。</li>
		</ol></li>
		<li>在 “函数”下，选择 “分段 ”以实现公式 （4）-（7）：<ol><li>指定函数的名称。 </li>
			<li>指定 温度 （T） 作为函数的 参数 。</li>
			<li>键入与公式 （4）-（7） 一致的每个温度区间的数学表达式。</li>
			<li>重复前面的步骤，从1到3，使用 表1中列出的标称值（正常组织是指肌肉和皮肤）为每个组织模型添加血液灌注和血管压力的温度依赖性函数。</li>
		</ol></li>
	</ol></li>
	<li>为几何体组件指定材料属性。<ol><li>从组件节点中，选择“材料”。</li>
		<li>选择 空白材料 ，包括 正常组织、肿瘤组织、血液、PTFE 和 不锈钢。</li>
		<li>启用手动选择，并选择与指定材料对应的几何实体。<ol><li>正常组织与建模肌肉和皮肤的几何形状有关。</li>
			<li>肿瘤和血液组织与肿瘤的几何形状有关。</li>
			<li>PTFE材料与模拟针绝缘体的几何形状有关。</li>
			<li>不锈钢材料与模拟地面和活动针的锥体几何形状相关联。</li>
		</ol></li>
		<li>对于与温度相关的电导率和热导率23，键入所选的函数名称和出现在“定义”节点中的相关参数（即 T）。</li>
		<li>对于不依赖于温度的材料属性，请参阅表 1 中列出的基线值27。 注意：我们依靠多孔弹性理论来计算压力 16,17,26。以下步骤显示了如何将多孔材料的属性分配给特定域。</li>
		<li>从 “材料”中，选择 “更多材料 |多孔材料。</li>
		<li>右键单击“多孔材料”（Porous Material） 以选择“流体”（Fluid） 和“固体组件”（Solid components）。选择“流体”节点，然后在“流体属性”下，选择“血液”（在前面的步骤中定义）。选择“固体”节点，然后在“固体属性”下，选择“肿瘤”（在前面的步骤中定义）。在 Solid 节点中，指定定义为 θS 的体积分数（表 1）。</li>
		<li>启用手动选择，并选择与指定材料对应的几何实体。为了遵循此协议，假设只有肿瘤区域是多孔弹性域。</li>
	</ol></li>
	<li>啮合<ol><li>在 “网格节点”下，选择“ 大小 ”，然后选择预定义的 更精细 的网格。</li>
		<li>在网格节点下添加自由四面体特征。此步骤允许在关键区域获得精细的网格。 注意：对于该模型，我们将肿瘤的边缘和皮下注射针头模型的远端确定为关键区域。</li>
		<li>选择 感兴趣的几何形状 并自定义 最大 （0.25 mm） 和 最小单元尺寸 ，使最小组件（例如，针尖）至少由四个网格单元（完整网格由 1,487,828 个单元组成）离散化。</li>
	</ol></li>
</ol>2. 物理
<ol><li>电气问题的设置 注意： 以下步骤提供了有关如何设置参数以计算电场分布的信息（图 2，块 1），该电场分布将提供射频热源 （Q）。<ol><li>右键单击 Electric Currents 节点。</li>
		<li>对于图3A中所示的电气边界条件，选择“端子”和“接地”作为边界。<ol><li>对于终端，手动选择两根针之一的近端（顶部）。识别出的针头将提供输入电源。</li>
			<li>在“终端”下，选择“电源”，然后根据所需的能源协议指定值。为了遵循该协议，根据初步离体实验20，选择0.5 W用于轻度热疗。</li>
			<li>选择“接地”并手动选择第二根针的近端表面。该针将充当电流返回路径的返回电极。</li>
			<li>在模型的剩余外表面应用 电气绝缘 。</li>
		</ol></li>
	</ol></li>
	<li>热问题的设置 注意：以下步骤说明如何在生物传热方程中包含温度依赖的血液灌注函数（公式 4 和 5），以模拟由血流引起的散热器。<ol><li>选择 Heat Transfer in Solids 节点 ，并指定 33 °C 作为温度的 初始值 。</li>
		<li>要对血流引起的散热器效应进行建模，请右键单击“ 固体中的传热”，添加 “热源 ”域，然后选择应考虑散热器效应的几何图形（即 肿瘤 和 正常 组织）。选择 常规来源 |用户定义 ，可以在何处键入散热器的表达式。</li>
		<li>对于 图 3B 中所示的热边界条件，右键单击 Heat Transfer，添加 Heat Flux 作为 边界条件，并指定应用热通量的外表面。选择对 流热通量 作为 通量类型。对于 传热系数，使用 h = 15 W/（m2 ·K） 模拟皮肤与空气之间自然热交换的机制28.指定 外部温度。使用 T = 20 °C 对实验室环境中的环境温度进行建模。</li>
	</ol></li>
	<li>流体动力学问题的设置 注意：以下步骤描述了如何实现 中所示的质量守恒方程 图2 （第 3 块）以及它如何与温度变化联系起来。<ol><li>选择“系数形式偏微分方程”节点，并指定“压力”作为因变量。在此阶段，将自动分配单位 Pascal （Pa）。 注意：计算出模拟结果后，可以使用所选的单位显示和/或导出结果。为了与文献保持一致，我们使用mmHg单位呈现结果（参见代表性结果部分）。</li>
		<li>将 流体电导单位 1/s 指定为 源项量。</li>
		<li>定义名称以标识变量（Pi，本研究中 的间质液压力 ）。</li>
		<li>右键单击“ 系数形式偏微分方程”节点 ，然后选择“ 系数形式 ”域。指定方程式所引用的 几何实体 （肿瘤）。重复相同的步骤，并选择将应用不同偏微分方程的剩余组织（正常组织）。</li>
		<li>对于肿瘤模型，指定以下系数和项以获得质量守恒方程（图2，块3）：肿瘤的扩散系数Ki（表1）;阻尼系数 <img alt="Equation 11" src="/files/ftp_upload/65870/65870eq11.jpg" style="vertical-align: middle;">);源术语 <img alt="Equation 12" src="/files/ftp_upload/65870/65870eq12.jpg" style="vertical-align: middle;">.对于肿瘤模型，忽略了淋巴系统的贡献。将所有其他系数设置为零。</li>
		<li>对于正常组织模型，指定以下系数和项以获得质量守恒方程（图 2 块 3）：正常组织的扩散系数 Ki （表 1）;阻尼系数 <img alt="Equation 13" src="/files/ftp_upload/65870/65870eq13.jpg" style="vertical-align: middle;">;源术语 <img alt="Equation 14" src="/files/ftp_upload/65870/65870eq14.jpg" style="vertical-align: middle;">.要将正常组织视为正常功能组织，请考虑淋巴系统的贡献。将所有其他系数设置为零。</li>
		<li>为了建立与电磁-热模拟的联系，将 血管压力 Pv 表示为 温度 的函数（通过血液灌注变量，参见公式 6 和公式 7）。</li>
		<li>右键单击“系数形式偏微分方程”，然后选择“初始值”。选择几何结构域（肿瘤），并对正常组织模型（正常组织）重复相同的步骤。根据表 1 中列出的值，为肿瘤和正常组织指定 Pi0。</li>
		<li>对于与流体动力学研究相关的 边界条件 （ 如图 3C 所示），右键单击系数 形式偏微分方程 ，然后选择 狄利克雷边界条件。选择正常组织结构域的外表面，并分配与正常组织对应的 Pi0值（表1）。</li>
	</ol></li>
</ol>3. 运行模拟并显示结果
注意：作为计算前的最后一步，请指定 时间 （模拟过程的持续时间）和 操作频率：
<ol><li>从“研究”节点中选择“频率瞬态”。<ol><li>指定 时间单位。</li>
		<li>从 输出时间中，选择 范围 （ 右侧）并指定 0 秒 作为 开始， 5 秒 作为 步长， 900 秒 作为 停止。</li>
		<li>将 频率 设置为 500e3 Hz。</li>
	</ol></li>
	<li>选择“ 计算 ”以运行模拟。</li>
	<li>要可视化结果，请在节点“结果”下选择“数据集”。<ol><li>右键单击以选择一个 切割平面 以定义用于可视化 2D 分布的平面（例如，y = 0 处的 zx 平面）。</li>
		<li>右键单击以在 3D 体积中选择一个 切割点 ，以显示参数随时间的变化。</li>
	</ol></li>
	<li>从顶部功能区上的 “结果” 中，<ol><li>选择 2D 绘图组 以可视化变量（例如 温度）在上述步骤中确定的其中一个平面上的二维分布。</li>
		<li>选择 1D 绘图组 以可视化上述步骤中确定的点或多个点的一维结果（例如，时间范围内的压力）。 注意：使用此协议中描述的设置运行模拟的时间约为2.5小时。</li>
	</ol></li>
</ol>

模拟双极射频热疗系统对肿瘤的影响

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M., et al. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Immune+modulation+by+molecularly+targeted+photothermal+ablation+in+a+mouse+model+of+advanced+hepatocellular+carcinoma+and+cirrhosis.">Immune modulation by molecularly targeted photothermal ablation in a mouse model of advanced hepatocellular carcinoma and cirrhosis.</a> Scientific Reports. 12 (1), 14449 (2022).</li><li>Bottiglieri, A., et al. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=RF-hyperthermia+to+modulate+tumor+interstitial+fluid+pressure:+an+in+vivo+pilot+study.">RF-hyperthermia to modulate tumor interstitial fluid pressure: an in vivo pilot study.</a> 38th Annual Society for Thermal Medicine Meeting. , (2023).</li><li>Baxter, L. T., Jain, R. 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Role of interstitial pressure and convection.</a> Microvascular Research. 37 (1), 77-104 (1989).</li><li>Stapleton, S., et al. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=A+mathematical+model+of+the+enhanced+permeability+and+retention+effect+for+liposome+transport+in+solid+tumors.">A mathematical model of the enhanced permeability and retention effect for liposome transport in solid tumors.</a> PLoS ONE. 8 (12), 1-10 (2013).</li><li>Rossmann, C., Haemmerich, D. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Review+of+temperature+dependence+of+thermal+properties,+dielectric+properties,+and+perfusion+of+biological+tissues+at+hyperthermic+and+ablation+temperatures.">Review of temperature dependence of thermal properties, dielectric properties, and perfusion of biological tissues at hyperthermic and ablation temperatures.</a> Critical Reviews in Biomedical Engineering. 42 (6), 467-492 (2014).</li><li>Song, C. 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A. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=A+thermoporoelastic+model+for+fluid+transport+in+tumour+tissues.">A thermoporoelastic model for fluid transport in tumour tissues.</a> Journal of The Royal Society Interface. 16 (154), 0030-0046 (2019).</li><li>Hasgall, P. A., et al. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=.">.</a> IT'IS Database for thermal and electromagnetic parameters of biological tissues. , (2022).</li><li>Cavagnaro, M., et al. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Influence+of+the+target+tissue+size+on+the+shape+of+ex+vivo+microwave+ablation+zones.">Influence of the target tissue size on the shape of ex vivo microwave ablation zones.</a> International Journal of Hyperthermia. 31 (1), 48-57 (2015).</li><li>Munson, J., Shieh, A. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Interstitial+fluid+flow+in+cancer:+implications+for+disease+progression+and+treatment.">Interstitial fluid flow in cancer: implications for disease progression and treatment.</a> Cancer Management and Research. 19 (6), 317-328 (2014).</li><li>Mu&#241;oz, N. M., et al. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Influence+of+injection+technique,+drug+formulation+and+tumor+microenvironment+on+intratumoral+immunotherapy+delivery+and+efficacy.">Influence of injection technique, drug formulation and tumor microenvironment on intratumoral immunotherapy delivery and efficacy.</a> Journal for ImmunoTherapy of Cancer. 9 (2), 0018-0027 (2021).</li><li>Swartz, M. A., Lund, A. W. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Lymphatic+and+interstitial+flow+in+the+tumour+microenvironment:+linking+mechanobiology+with+immunity.">Lymphatic and interstitial flow in the tumour microenvironment: linking mechanobiology with immunity.</a> Nature Reviews Cancer. 12 (3), 210-219 (2012).</li><li>Mehta, A., Oklu, R., Sheth, R. 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作者没有要披露的利益冲突。
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我们提出了一种计算建模协议，将瞬态电热模拟与流体动力学模拟相结合，以研究射频热疗对肿瘤中热和间质流体压力分布的影响。关键方面在于建立一个能够捕捉温度和血管压力之间关系的数值工作流程，这反过来又驱动了间质液压力的变化。
我们利用血管压力和血液灌注之间的关系来模拟质量守恒方程中温度依赖的血管压力参数（图2）。在轻度热?...

间质液压升高 （IFP） 是实体瘤的标志1。由于肿瘤内静脉受压和淋巴管缺失，液体从高渗透血管渗入间质的液体流出不平衡 1,2,3。与肿瘤微环境 （TME） 中其他异常的生物物理参数（包括固体应力和硬度）一起，IFP 升高会破坏全身和局部药物递送的功效 4,5,6。实体瘤的间质液压力范围为 5 mmHg（胶质母细胞瘤和黑色素瘤）至 30 mmHg（肾细胞癌），而正常组织为 1-3 mmHg2。高 IFP 负责增加流向肿瘤边缘的液体，并使基质细胞、浸润细胞和其他细胞外成分暴露于剪切应力 1,4。机械生物改变维持免疫抑制性 TME，例如，通过增加内皮发芽，支持血管生成、癌细胞迁移和侵袭、转化生长因子β （TGF-β） 表达和基质硬化 7,8,9。
几项研究探索了旨在降低 IFP 的基于能量的疗法，包括低强度超声、高强度聚焦超声、脉冲电场和热疗 5,10,11。加热到 40-43 °C 的温度范围，称为轻度热疗，已被证明可以增加肿瘤血液灌注，因此可能通过促进间质液的渗入和引流来帮助扩张受压静脉和降低血管压力11,12。最近的一些研究表明，热疗有可能降低 IFP，从而促进药物或造影剂在肿瘤内的分布13,14。这些研究还显示，与无治疗对照组相比，体温过高后 T 细胞浸润增加13。
体内小动物实验的有希望的结果激发了采用计算方法的进一步研究，以推进对TME内的物理参数如何受到物理干预影响的理解4,15,16,17。计算模型的结果可以补充体内实验研究，以揭示局部加热（或其他外部能源）和IFP背后的因果关系。鉴于使用基于导管和针头的压力传感器测量 IFP 的空间变化存在挑战，这尤其具有指导意义，这些压力传感器通常提供点测量值 9,16,18,19。在药物输送的背景下，了解关键的生物物理机制对于定义适当的加热方案以及药物注射的时间窗口以增强有效药物分配的可能性至关重要。就 TME 生物物理特性的变化而言的定量信息，包括但不限于 IFP，也可以为解释对外部刺激的免疫反应（例如，T 细胞浸润）提供见解。
我们提出了一种用于计算建模肿瘤 IFP 曲线热介导变化的协议。具体来说，该协议详细介绍了如何对定制的小动物设备进行建模，以提供射频电流的受控热疗，模拟加热后的瞬态温度曲线，并耦合流体动力学模拟以计算肿瘤IFP响应热疗的时空变化。该模型反映了我们在先前实验研究中在皮下肿瘤模型（McArdle RH7777，ATCC）中使用的实验设置的基本特征20。
图 1 显示了我们实施的计算模型，用于计算被正常组织包围的肿瘤中热诱导的 IFP 变化。对插入肿瘤中的一对皮下注射针进行建模，以 500 kHz 的射频电流进行加热。假设在肿瘤结构域中是一种多孔材料，由两个相组成：固相代表固体细胞外基质，液相代表间质液。在由外部刺激（例如温度升高）引起的压力变化或基质变形的情况下，固体和流体成分会重新排列。这导致间质液通过细胞外固体基质的运动16,17,21。
根据多孔弹性理论，应力张量 S （Pa）（方程[1]）是描述固体组分体积相对于初始条件变化的弹性项和描述流体组分静水压力引起的应力的多孔项的组合。
<img alt="Equation 1" src="/files/ftp_upload/65870/65870eq01.jpg" style="margin: auto;">（一）
式中，λ、μ（Pa）为Lamé参数，E为应变张量，e为体积应变张量，Pi（Pa）为间隙流体压力（I为单位矩阵）。假设固体分量在多孔弹性应力下处于稳态条件，这意味着应力张量分量是正交的。 <img alt="Equation 15" src="/files/ftp_upload/65870/65870eq15.jpg" style="margin: auto;">
图 2 显示了在所描述的多孔弹性模型中实现的数学方程组以及所提出的多物理场模型的各组成部分之间的相互作用。计算模拟的工作流程包括：
电气问题方程。电气问题方程的求解提供了时间平均射频热源Q（焦耳热）。为此，使用麦克斯韦方程的准静态近似法来计算时间平均电场 E （V/m） 的分布（图 2，块 1）。
热问题方程。Pennes生物热方程的解（图2，块2）提供了温度T（°C）的空间和时间变化，这是由于热源（Q）与吸收的电磁能有关，被动加热与组织的<img alt="Equation 16" src="/files/ftp_upload/65870/65870eq16.jpg" style="margin: auto;">热传导（）相关联，以及组织血液灌注的散热器效应（cWb（T） （T - Tb)).散热器术语近似于在微血管系统中流动的血液与吸收电磁功率的邻近组织之间的热交换。传热方程还包括平流项（），<img alt="Equation 17" src="/files/ftp_upload/65870/65870eq17.jpg" style="margin: auto;">该项描述了由间隙流体通过多孔弹性模型的细胞外基质的运动引起的温度变化。然而，与导致温度变化的其他机制相比，该术语对温度分布的影响可以忽略不计。
流体动力学问题方程。质量守恒方程（图2，块3）与达西定律（图2，块4）相结合，将间隙流体压力 Pi的空间和时间变化作为输出，该变化是由流体的源（<img alt="Equation 2" src="/files/ftp_upload/65870/65870eq02.jpg" style="vertical-align: middle;">）和汇（<img alt="Equation 03" src="/files/ftp_upload/65870/65870eq03.jpg" style="vertical-align: middle;"> ）之间的平衡产生的。质量守恒方程左侧的瞬态压力项 ， <img alt="Equation 4" src="/files/ftp_upload/65870/65870eq04.jpg" style="margin: auto;"> 描述了多孔弹性材料中流体和固体成分的重排。这是由间质液压力 Pi 的变化引起的，该变化由血管压力 Pv随温度的变化驱动。
血管压力 （Pv） 和间质液压力 （Pi） 之间的差值是流经细胞外基质的液体的来源。下沉项与淋巴管 （PL） 和间质间隙 （Pi） 之间的压力差有关。在正常组织中，淋巴管系统的压力（~ -6-0 mmHg）比组织液压力低两倍13。这种压差确保了淋巴管将多余的液体从血管壁流出到间质中的功效。对于这里提出的肿瘤模型，我们忽略了淋巴系统的贡献4,16,22。
公式 （2） 至 （5） 中的数学表达式用于描述组织和组织血液灌注的电导率和热导率的温度依赖性23,24。两种不同的数学模型用于描述血液在正常和肿瘤组织域中灌注的温度依赖性，分别为24,25。模型显示，与正常组织中的基线相比，血液灌注随温度增加多达九倍，而在肿瘤域中仅为基线值的两倍左右。对于两种模型，血液灌注的增加都限制在轻度热疗范围内（低于 45 °C）内的温度。值得一提的是，数学表达式，即方程式（4）和（5），并不能完全描述两种不同类型组织中血液灌注的温度依赖性变化的机制。然而，与正常组织相比，它们有助于代表肿瘤微环境通常表征的有限灌注。
<img alt="Equation 5" src="/files/ftp_upload/65870/65870eq05.jpg" style="margin: auto;">（二）
<img alt="Equation 6" src="/files/ftp_upload/65870/65870eq06.jpg" style="margin: auto;">（三）
<img alt="Equation 7" src="/files/ftp_upload/65870/65870eq07.jpg" style="margin: auto;"> （四）
<img alt="Equation 8" src="/files/ftp_upload/65870/65870eq08.jpg" style="margin: auto;"> （五）
<img alt="Equation 9" src="/files/ftp_upload/65870/65870eq09.jpg" style="margin: auto;">（6）
<img alt="Equation 10" src="/files/ftp_upload/65870/65870eq10.jpg" style="margin: auto;">（7）
在这项研究中，我们使用方程式 （6） 和 （7） 来模拟血管压力作为正常和肿瘤组织模型26 的血液灌注函数。根据公式（4）和（5），血流率可以表示为血液灌注与血密度之间的比率。血流与血管压力之间的关系在文献3 中已得到充分确立：血流速率和脉管系统的几何阻力（或电导率， Lp）决定了血管内的压差。血管压力可以表示为温度的函数（公式（6）和（7）），利用这种关系和血液灌注的温度依赖性模型（公式（4）和（5））。
下一节将详细介绍计算工作流程（图2）的实现以及组织模型的温度依赖性特性。 表 1 列出了所有材料属性及其描述和基线值（即在体温下）。有关安装在用于实现此计算协议的计算机上的 COMSOL Multiphysics 的详细信息，请参阅 材料表 。使用 AC/DC 模块对电气问题进行建模;使用传热物理学对生物传热进行建模;流体动力学问题使用数学接口进行建模。

<table border="1" fo:keep-together.within-page="1" fo:keep-with-next.within-page="always">
	<tbody>
		<tr>
			<td>COMSOL Multiphysics (v. 6.0)</td>
			<td>COMSOL AB, Stockholm, Sweden</td>
			<td></td>
			<td>Software used to implement the computational workflow described in the protocol</td>
		</tr>
		<tr>
			<td>Dell 1.8.0, 11th Gen Intel(R) Core(TM) i7-11850H @ 2.50GHz, 2496 Mhz, 8 Core(s), 16 Logical Processor(s), 32 GB RAM</td>
			<td>Dell Inc.&#160;</td>
			<td></td>
			<td>Laptop used to run computational simulations</td>
		</tr>
	</tbody>
</table>

a computational modeling approach to investigate the influence of hyperthermia on the tumor microenvironment

肿瘤微环境的生物物理特性与正常组织有很大不同。一系列特征，包括血管分布减少、淋巴引流缺乏和间质压升高，减少了治疗药物对肿瘤的渗透。肿瘤内的局部热疗可以改变微环境特性，例如间质液压力，从而可能导致药物渗透率的提高。在这种情况下，多物理场计算模型可以深入了解肿瘤微环境中生物物理参数之间的相互作用，并可以指导测试局部热疗生物效应的实验的设计和解释。
本文介绍了计算模型的分步工作流程，该模型耦合了描述电流分布、生物热传递和流体动力学的偏微分方程。主要目的是研究双极射频设备提供的热疗对肿瘤内间质液压力的影响。提出了将电流分布、生物热传递和间隙流体压力联系起来的数学表达式系统，强调了热干预可能引起的间隙流体压力分布的变化。

Elevated interstitial fluid pressure (IFP) is a hallmark of solid tumors1. The leakage of fluid into the interstitium from hyperpermeable blood vessels is imbalanced by the egress of fluid due to compressed intratumoral veins and absent lymphatics1,2,3. In concert with other biophysical parameters that are abnormal within the tumor microenvironment (TME), including solid stress and stiffness, elevated IFP undermines the efficacy of both systemic and local drug delivery4,5,6. Interstitial fluid pressure in solid tumors ranges from 5 mmHg (glioblastoma and melanoma) to 30 mmHg (renal cell carcinoma) compared to 1-3 mmHg in normal tissue2. High IFP is responsible for increasing the fluid flow toward the margin of the tumor and exposes stromal cells, infiltrated cells, and other extracellular components to shear stress1,4. Mechano-biological alterations sustain an immunosuppressive TME, for example, by increasing endothelial sprouting, which supports angiogenesis, cancer cell migration and invasion, transforming growth factor-&#946; (TGF-&#946;) expression, and stromal stiffening7,8,9.
Several studies have explored energy-based therapies with the intent of decreasing IFP, including low-intensity ultrasound, high-intensity focused ultrasound, pulsed electric fields, and thermal therapies5,10,11. Heating to temperatures in the range of 40-43 &#176;C, referred to as mild hyperthermia, has been shown to increase tumor blood perfusion and may thus contribute to expanding compressed veins and reducing vascular pressure by facilitating intravasation and drainage of interstitial fluid11,12. Some recent studies have shown the potential of hyperthermia to reduce IFP and consequently, to facilitate the distribution of drug or contrast agents within a tumor13,14. These studies also show increased T-cell infiltration following hyperthermia compared to no treatment control groups13.
The promising results from in vivo small animal experiments motivate further studies employing computational approaches to advance the understanding of how physical parameters within the TME are affected by physical interventions4,15,16,17. Results from computational models can complement in vivo experimental studies to uncover the cause-effect relationship underlying the local heating (or other external energy sources) and the IFP. This can be particularly instructive given the challenges with measuring spatial variations in IFP with catheter- and needle-based pressure transducers, which typically provide point measurements9,16,18,19. In the context of drug delivery, an understanding of the key biophysical mechanisms is essential to define the appropriate heating protocol as well as the time window for drug injection to enhance the likelihood of effective drug distribution. Quantitative information in terms of changes in biophysical characteristics of the TME, including but not limited to the IFP, could also give insights into the interpretation of the immunological response (e.g., T-cell infiltration) to external stimuli.
We present a protocol for computational modeling of thermally mediated changes to tumor IFP profiles. Specifically, the protocol details how to model a custom small-animal apparatus for delivering controlled thermal therapy with radiofrequency current, simulate transient temperature profiles following heating, and couple fluid dynamic simulations to compute the spatio-temporal variation of tumor IFP in response to thermal therapy. This model mirrors the essential features of the experimental setup we used in a subcutaneous tumor model (McArdle RH7777, ATCC) in a prior experimental study20.
Figure 1 shows the computational model we implemented to calculate thermally induced changes in IFP in a tumor surrounded by normal tissue. A pair of hypodermic needles inserted in the tumor is modeled to deliver heating with&#160;radiofrequency current at 500 kHz. A porous material is assumed in the tumor domain, composed of two phases: the solid phase represents the solid extracellular matrix, and the fluid phase represents the interstitial fluid. In the case of a pressure change or a matrix deformation resulting from an external stimulus, for example increase of temperature, the solid and fluid components rearrange. This causes the movement of the interstitial fluid through the extracellular solid matrix16,17,21.
From the poroelasticity theory, the stress tensor S (Pa) (equation [1]) is the combination of the elastic term describing the change in volume of the solid component relative to the initial conditions, and a porous term describing the stress induced by the hydrostatic pressure of the fluid component.
<img alt="Equation 1" src="/files/ftp_upload/65870/65870eq01.jpg" style="margin: auto;" />&#160; &#160; &#160;(1)
Where, &#955;, &#956; (Pa) are the Lam&#233; parameters, E is the strain tensor, e is the volumetric strain tensor, Pi (Pa) is the interstitial fluid pressure (I is the identity matrix). Steady-state conditions are assumed for the solid component under poroelastic stress, which means that the stress tensor components are orthogonal, <img alt="Equation 15" src="/files/ftp_upload/65870/65870eq15.jpg" style="margin: auto;" />.
Figure 2 shows the system of mathematical equations implemented in the described poroelastic model and the interplay between the components of the presented multi-physics model. The workflow of the computational simulations includes:
Electrical problem equations. The solution of the electrical problem equations provides the time-averaged RF heat source Q (Joule heating). To this end, a quasi-static approximation to Maxwell&#39;s equations is used to calculate the distribution of the time-averaged electric field E (V/m) (Figure 2, block 1).
Thermal problem equations. The solution of the Pennes bioheat equation (Figure 2, block 2) provides the spatial and temporal variation of the temperature T (&#176;C) as a result of the heat source (Q) linked&#160;to the absorbed electromagnetic energy, the passive heating linked to the thermal conduction of the tissues (<img alt="Equation 16" src="/files/ftp_upload/65870/65870eq16.jpg" style="margin: auto;" />), and the heat sink effect of the tissue blood perfusion (cWb(T) (T - Tb)). The heat sink term approximates the heat exchange between the blood flowing in the microvasculature and adjacent tissue where electromagnetic power is absorbed. The heat transfer equation also includes the advection term (<img alt="Equation 17" src="/files/ftp_upload/65870/65870eq17.jpg" style="margin: auto;" />), which describes the change in the temperature caused by the movement of interstitial fluid through the extracellular matrix of the poroelastic model. However, this term has a negligible impact on the temperature profile compared to the other mechanisms responsible for the temperature change.
Fluid-dynamic problem equations. The conservation of mass equation (Figure 2, block 3) combined with Darcy&#39;s law (Figure 2, block 4) gives as an output the spatial and temporal variation of the interstitial fluid pressure Pi resulting from the balance between the source (<img alt="Equation 2" src="/files/ftp_upload/65870/65870eq02.jpg" style="vertical-align: middle;" />) and the sink (<img alt="Equation 03" src="/files/ftp_upload/65870/65870eq03.jpg" style="vertical-align: middle;" /> ) of the fluid. The transient pressure term on the left side of the mass conservation equation, <img alt="Equation 4" src="/files/ftp_upload/65870/65870eq04.jpg" style="margin: auto;" /> , describes the rearrangement of the fluid and solid components in the poroelastic material. This is caused by the variation of the interstitial fluid pressure, Pi, driven by the variation of the vascular pressure Pv as a function of the temperature.
The difference between the vascular pressure (Pv) and the interstitial fluid pressure (Pi) is the source of the fluid that flows through the extracellular matrix. The sink term is linked to the pressure difference between the lymphatic vessels (PL) and the interstitial space (Pi). In normal tissue, the pressure in the lymphatic vasculature (~ -6-0 mmHg) is up to two-fold lower than the interstitial fluid pressure13. This pressure difference ensures the efficacy of the lymphatic vessels to drain the excess of the fluid extravasating from the wall of&#160;blood vessels into the interstitium. For the tumor model presented here, we neglected the contribution of the lymphatic system4,16,22.
Mathematical expressions from Equations (2) to (5) are used to describe the temperature dependence of the electrical and thermal conductivity of tissue and tissue blood perfusion23,24. Two different mathematical models are used to describe the temperature dependence of blood perfusion in the normal and tumor tissue domains, respectively24,25. The models show that the blood perfusion increases with the temperature up to nine times compared to the baseline in the normal tissue and only approximately two times of the baseline value in the tumor domain. For both models, the increase in the blood perfusion is limited to the temperatures within the mild hyperthermia range (below 45 &#176;C). It is worth mentioning that the mathematical expressions, Equations (4) and (5), do not fully describe the mechanisms underlying the temperature-dependent changes in the blood perfusion in the two different types of tissue. However, they help represent the limited perfusion that typically characterizes the tumor microenvironment compared to normal tissues.
<img alt="Equation 5" src="/files/ftp_upload/65870/65870eq05.jpg" style="margin: auto;" />&#160; &#160;&#160; (2)
<img alt="Equation 6" src="/files/ftp_upload/65870/65870eq06.jpg" style="margin: auto;" />&#160; &#160; &#160;(3)
<img alt="Equation 7" src="/files/ftp_upload/65870/65870eq07.jpg" style="margin: auto;" /> (4)
<img alt="Equation 8" src="/files/ftp_upload/65870/65870eq08.jpg" style="margin: auto;" /> (5)
<img alt="Equation 9" src="/files/ftp_upload/65870/65870eq09.jpg" style="margin: auto;" />&#160; &#160; &#160;(6)
<img alt="Equation 10" src="/files/ftp_upload/65870/65870eq10.jpg" style="margin: auto;" />&#160; &#160; &#160;(7)
In this study, we used Equations (6) and (7) to model the vascular pressure as a function of the blood perfusion both for normal and tumor tissue models26. From Equations (4) and (5), the blood flow rate can be expressed as the ratio between the blood perfusion and the blood density. The relationship between blood flow and vascular pressure is well established in the literature3: the blood flow rate and the geometrical resistance (or conductivity, Lp) of the vasculature determine the pressure difference within the blood vessel. The vascular pressure can be expressed as a function of the temperature (Equations (6) and (7)), leveraging on this relationship and the temperature-dependent model of the blood perfusion (Equations (4) and (5)).
The implementation of the computational workflow (Figure 2) and the temperature-dependent properties of the tissue models are described in detail in the following section. All material properties and their descriptions and baseline values (i.e., at body temperature) are listed in Table 1. See the Table of Materials for details about COMSOL Multiphysics installed on a computer used to implement this computational protocol. The electrical problem was modeled using the AC/DC module; bioheat transfer was modeled using heat transfer physics; and the fluid-dynamics problem was modeled using the Mathematics interface.

作者聚焦：计算局部射频热疗干预对肿瘤生物力学的影响

一种计算建模方法研究热疗对肿瘤微环境的影响

Goal of this research is to use computational modeling to study the effect of local radiofrequency thermal intervention on the biomechanics of the tumor. We would be focusing particular on high intratumoral pressure driven by abnormal blood flow within the tumor, which is one of the main barriers to the effective distribution of therapeutic agents. Interventions such as radiofrequency hyperthermia have been recently explored as a potential tool to perturb a tumor microenvironment, for example, increasing blood flow and thereby decreasing intratumoral pressure.This may lead to more favorable conditions to the distribution of therapeutic agents and potentially improve the patient's response to therapeutic treatments. Currently available to measure intratumoral pressure rely on invasive techniques that provide information, quantitative information, in only a few locations within the tumors. Computational model may provide the means to assess the special profile of biophysical variables across the entire tumor.Protocol is the description of a computational workflow that captures the relationship between tissue temperature and blood perfusion driving changes in intratumoral pressure. The protocol describes a model geometry that in principle mirrors in-vivo experimental settings designed to approximate clinical thermal intervention. Perspective on how computational models can be employed to advance our understanding of how biophysical parameters of the tumor microenvironment, such as intratumoral pressure, can be affected by local thermal interventions.

肿瘤内高间质液压的均匀分布和外周处降至正常值 （0-3 mmHg） 是 TME 的标志。 图 4 和 图 5 显示了温度 （A）、间隙流体压力 （B） 和流体速度 （C） 的初始条件 （t = 0 min）。在开始加热之前，当初始温度为 33 °C 时，肿瘤内的间质液压力值约为 9 mmHg，并且在外周降至 3 mmHg。这些值是在 体内 实验期间测量的（中心温度降至 37 °C 以下通常是麻醉...

Watch this Scientific Journal Video about Author Spotlight: Computing the Effects of a Local Radiofrequency Hyperthermia Intervention on Tumor Biomechanics at JoVE.com

本文描述了一种协议，用于模拟瞬态温度曲线和偶极射频热疗系统加热后间隙流体压力的耦合时空变化。该方案可用于评估表征肿瘤微环境的生物物理参数对介入热疗技术的反应。

The biophysical properties of the tumor microenvironment differ substantially from normal tissues. A constellation of features, including decreased ...

本研究的目的是使用计算建模来研究局部射频热干预对肿瘤生物力学的影响。我们将特别关注由肿瘤内异常血流驱动的高瘤内压力，这是有效分布治疗剂的主要障碍之一。最近，人们已经探索了射频热疗等干预措施，将其作为扰乱肿瘤微环境的潜在工具，例如，增加血流量，从而降低肿瘤内压。这可能为治疗剂的分布带来更有利的条件，并可能改善患者对治疗的反应。目前可用于测量肿瘤内压力的依赖于侵入性技术，这些技术仅在肿瘤内的几个位置提供信息，定量信息。计算模型可以提供评估整个肿瘤中生物物理变量的特殊特征的方法。协议是对计算工作流程的描述，该工作流程捕获组织温度和血液灌注之间的关系，从而驱动肿瘤内压力的变化。该协议描述了一个模型几何形状，该几何形状原则上反映了旨在近似临床热干预的体内实验设置。关于如何利用计算模型来推进我们对肿瘤微环境的生物物理参数（如肿瘤内压力）如何受到局部热干预影响的理解。

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Research

JoVE Journal

Bioengineering

A Computational Modeling Approach to Investigate the Influence of Hyperthermia on the Tumor Microenvironment

200 次观看.  Kansas State University. 本研究的目的是使用计算建模来研究局部射频热干预对肿瘤生物力学的影响。我们将特别关注由肿瘤内异常血流驱动的高瘤内压力，这是有效分布治疗剂的主要障碍之一。最近，人们已经探索了射频热疗等干预措施，将其作为扰乱肿瘤微环境的潜在工具，例如，增加血流量，从而降低肿瘤内压。这可能为治疗剂的分布带来更有利的条件，并可能改善患者对治疗的反应。?...