通过电子顺磁共振氧成像（EPROI）评估肿瘤缺氧放射增敏。

IF 3 4区医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Molecular Imaging and Biology Pub Date : 2024-06-01 Epub Date: 2023-09-18 DOI:10.1007/s11307-023-01855-0

Ashlyn G Rickard, Yvonne M Mowery, Alex Bassil, Douglas C Rouse, Nerissa T Williams, Theresa Charity, Rafaela Belloni, Brian Crouch, Nimmi Ramanujam, Daniel Stevenson, Rico Castillo, Stephanie Blocker, Boris Epel, Mrignayani Kotecha, Gregory M Palmer

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引用次数: 0

摘要

目的：肿瘤缺氧会导致侵袭性表型和放疗（RT）治疗反应减弱，缺氧组织的放射敏感性是正常缺氧组织的 3 倍。实施缺氧放射增敏剂的一大挑战是缺乏直接量化组织氧的高分辨率成像模式。电子顺磁共振氧成像仪（EPROI）被用来量化两种小鼠肿瘤模型中的肿瘤氧合情况：后者能更好地再现人类恶性肿瘤的肿瘤微环境。我们假设这些模型的肿瘤缺氧情况有所不同。我们还旨在量化线粒体抑制剂罂粟碱（PPV）诱导的肿瘤缺氧的绝对变化及其对 RT 反应的影响：步骤：通过 EPROI 鉴定 E0771 和原发性 p53/MCA 肉瘤的肿瘤氧合情况，前者还通过漫反射光谱（DRS）进行间接量化。在通过 EPROI 确认 PPV 对缺氧程度的影响后，我们比较了在 20 Gy 之前使用 0 和 2 mg/kg PPV 对肿瘤生长延迟和存活率的影响：缺氧性肉瘤比正常缺氧性肉瘤更具放射抗性（P=0.0057，2-way ANOVA），基线缺氧分数高是影响存活率的重要因素（P=0.0063，Cox回归模型），与治疗方法无关。在肉瘤或E0771模型中，RT前使用PPV预处理并不能使肿瘤放射增敏。在肉瘤模型中，EPROI 成功识别了基线缺氧肿瘤。对总血红蛋白、饱和血红蛋白、线粒体电位变化和葡萄糖摄取的 DRS 定量显示，PPV 前后的 E0771 肿瘤没有显著差异：结论：EPROI 可提供三维高分辨率 pO2 定量；EPR 比 DRS 更适合描述肿瘤缺氧的特征。PPV并没有使E0771肿瘤或p53/MCA肉瘤放射增敏，这可能与每个肿瘤中复杂的血管模式有关。此外，了解肿瘤缺氧的模型依赖性将为未来使用缺氧性放射增敏剂进行治疗研究奠定急需的基础。

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Evaluating Tumor Hypoxia Radiosensitization Via Electron Paramagnetic Resonance Oxygen Imaging (EPROI).

Purpose: Tumor hypoxia contributes to aggressive phenotypes and diminished therapeutic responses to radiation therapy (RT) with hypoxic tissue being 3-fold less radiosensitive than normoxic tissue. A major challenge in implementing hypoxic radiosensitizers is the lack of a high-resolution imaging modality that directly quantifies tissue-oxygen. The electron paramagnetic resonance oxygen-imager (EPROI) was used to quantify tumor oxygenation in two murine tumor models: E0771 syngeneic transplant breast cancers and primary p53/MCA soft tissue sarcomas, with the latter autochthonous model better recapitulating the tumor microenvironment in human malignancies. We hypothesized that tumor hypoxia differs between these models. We also aimed to quantify the absolute change in tumor hypoxia induced by the mitochondrial inhibitor papaverine (PPV) and its effect on RT response.

Procedures: Tumor oxygenation was characterized in E0771 and primary p53/MCA sarcomas via EPROI, with the former model also being quantified indirectly via diffuse reflectance spectroscopy (DRS). After confirming PPV's effect on hypoxic fraction (via EPROI), we compared the effect of 0 versus 2 mg/kg PPV prior to 20 Gy on tumor growth delay and survival.

Results: Hypoxic sarcomas were more radioresistant than normoxic sarcomas (p=0.0057, 2-way ANOVA), and high baseline hypoxic fraction was a significant (p=0.0063, Cox Regression Model) hazard in survivability regardless of treatment. Pre-treatment with PPV before RT did not radiosensitize tumors in the sarcoma or E0771 model. In the sarcoma model, EPROI successfully identified baseline hypoxic tumors. DRS quantification of total hemoglobin, saturated hemoglobin, changes in mitochondrial potential and glucose uptake showed no significant difference in E0771 tumors pre- and post-PPV.

Conclusion: EPROI provides 3D high-resolution pO₂ quantification; EPR is better suited than DRS to characterize tumor hypoxia. PPV did not radiosensitize E0771 tumors nor p53/MCA sarcomas, which may be related to the complex pattern of vasculature in each tumor. Additionally, understanding model-dependent tumor hypoxia will provide a much-needed foundation for future therapeutic studies with hypoxic radiosensitizers.

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来源期刊

Molecular Imaging and Biology 医学-核医学

CiteScore

6.90

自引率

3.20%

发文量

审稿时长

3 months

期刊介绍： Molecular Imaging and Biology (MIB) invites original contributions (research articles, review articles, commentaries, etc.) on the utilization of molecular imaging (i.e., nuclear imaging, optical imaging, autoradiography and pathology, MRI, MPI, ultrasound imaging, radiomics/genomics etc.) to investigate questions related to biology and health. The objective of MIB is to provide a forum to the discovery of molecular mechanisms of disease through the use of imaging techniques. We aim to investigate the biological nature of disease in patients and establish new molecular imaging diagnostic and therapy procedures. Some areas that are covered are: Preclinical and clinical imaging of macromolecular targets (e.g., genes, receptors, enzymes) involved in significant biological processes. The design, characterization, and study of new molecular imaging probes and contrast agents for the functional interrogation of macromolecular targets. Development and evaluation of imaging systems including instrumentation, image reconstruction algorithms, image analysis, and display. Development of molecular assay approaches leading to quantification of the biological information obtained in molecular imaging. Study of in vivo animal models of disease for the development of new molecular diagnostics and therapeutics. Extension of in vitro and in vivo discoveries using disease models, into well designed clinical research investigations. Clinical molecular imaging involving clinical investigations, clinical trials and medical management or cost-effectiveness studies.