将科尔松弛频率作为肺组织中癌症的识别参数:动物和患者体内外初步研究。

Les Bogdanowicz, Onur Fidaner, Donato Ceres, Alexander Grycuk, Martina Guidetti, David Demos
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引用次数: 0

摘要

背景:肺癌是世界上导致癌症死亡的主要原因,但诊断仍然具有挑战性。肺癌最初表现为小结节;早期准确诊断可及时对恶性结节进行手术切除,同时避免对良性结节患者进行不必要的手术:科尔弛豫频率(CRF)是一种衍生的电生物阻抗特征,可用于区分癌组织和正常组织。方法:使用 NoduleScan 对 30 名接受非小细胞肺癌切除术的志愿者新鲜切除的肺组织进行了体外人体测试。将肿瘤和远处正常肺组织相对于肿瘤的 CRF 与组织病理学标本进行比较,以建立潜在的床旁诊断算法。为了进行体内动物试验,在 20 只小鼠的右侧腹部皮下注射异种移植人类肺癌肿瘤细胞。对活体动物经皮肿瘤和安乐死后的肿瘤进行了光谱阻抗测量。这些 CRF 测量结果与健康小鼠肺组织进行了比较。对于猪肺的体外测试,猪肺是连同气管一起接收的。移除声带盒后,连接呼吸机给猪肺加压并模拟呼吸。在肺叶的不同位置切割肺表面,以形成一个可容纳从体内动物试验中获得的肿瘤的口袋。肿瘤被放置在肺表面下,电极被放置在肿瘤正上方的肺表面上,但肿瘤和电极之间有肺组织。在肺部处于放气状态、充气状态以及充气-放气过程中进行频谱阻抗测量,以模拟呼吸:结果:在对 30 名患者的 60 份标本进行评估后,NoduleScan 可以对肿瘤和远处正常组织中的 CRF 进行明确区分,灵敏度(97%)和特异度(87%)都很高。在测量的 25 个异种移植小动物模型标本中,CRF 与人体活体测量中观察到的分离情况一致。我们还成功测量了植入猪肺的肿瘤CRF,CRF测量结果与之前对加压和非加压肺的测试结果一致:结论:正如之前在乳腺组织中显示的那样,1kHz-10MHz 范围内的 CRF 能够区分非小细胞肺癌和正常组织。此外,体内小动物实验证明,灌注肿瘤具有与乳腺组织和人体体外测试相同的 CRF 特征。肺部的充气和放气对 CRF 特征没有影响。随着进一步的发展,从光谱阻抗测量中得出的 CRF 可用于指导手术切除的床旁诊断。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Cole Relaxation Frequency as a Parameter to Identify Cancer in Lung Tissue: Preliminary Animal and Ex Vivo Patient Studies.

Background: Lung cancer is the world's leading cause of cancer deaths, and diagnosis remains challenging. Lung cancer starts as small nodules; early and accurate diagnosis allows timely surgical resection of malignant nodules while avoiding unnecessary surgery in patients with benign nodules.

Objective: The Cole relaxation frequency (CRF) is a derived electrical bioimpedance signature, which may be utilized to distinguish cancerous tissues from normal tissues.

Methods: Human testing ex vivo was conducted with NoduleScan in freshly resected lung tissue from 30 volunteer patients undergoing resection for nonsmall cell lung cancer. The CRF of the tumor and the distant normal lung tissue relative to the tumor were compared to histopathology specimens to establish a potential algorithm for point-of-care diagnosis. For animal testing in vivo, 20 mice were implanted with xenograft human lung cancer tumor cells injected subcutaneously into the right flank of each mouse. Spectral impedance measurements were taken on the tumors on live animals transcutaneously and on the tumors after euthanasia. These CRF measurements were compared to healthy mouse lung tissue. For porcine lung testing ex vivo, porcine lungs were received with the trachea. After removal of the vocal box, a ventilator was attached to pressurize the lung and simulate breathing. At different locations of the lobes, the lung's surface was cut to produce a pocket that could accommodate tumors obtained from in vivo animal testing. The tumors were placed in the subsurface of the lung, and the electrode was placed on top of the lung surface directly over the tumor but with lung tissue between the tumor and the electrode. Spectral impedance measurements were taken when the lungs were in the deflated state, inflated state, and also during the inflation-deflation process to simulate breathing.

Results: Among 60 specimens evaluated in 30 patients, NoduleScan allowed ready discrimination in patients with clear separation of CRF in tumor and distant normal tissue with a high degree of sensitivity (97%) and specificity (87%). In the 25 xenograft small animal model specimens measured, the CRF aligns with the separation observed in the human in vivo measurements. The CRF was successfully measured of tumors implanted into ex vivo porcine lungs, and CRF measurements aligned with previous tests for pressurized and unpressurized lungs.

Conclusions: As previously shown in breast tissue, CRF in the range of 1kHz-10MHz was able to distinguish nonsmall cell lung cancer versus normal tissue. Further, as evidenced by in vivo small animal studies, perfused tumors have the same CRF signature as shown in breast tissue and human ex vivo testing. Inflation and deflation of the lung have no effect on the CRF signature. With additional development, CRF derived from spectral impedance measurements may permit point-of-care diagnosis guiding surgical resection.

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