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肿瘤微血管和微环境:临床前模型活体成像的新见解。

Tumor microvasculature and microenvironment: novel insights through intravital imaging in pre-clinical models.

机构信息

Edwin L. Steele Laboratory for Tumor Biology, Department of Radiation Oncology, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts 02114, USA.

出版信息

Microcirculation. 2010 Apr;17(3):206-25. doi: 10.1111/j.1549-8719.2010.00029.x.

Abstract

Intravital imaging techniques have provided unprecedented insight into tumor microcirculation and microenvironment. For example, these techniques allowed quantitative evaluations of tumor blood vasculature to uncover its abnormal organization, structure and function (e.g., hyper-permeability, heterogeneous and compromised blood flow). Similarly, imaging of functional lymphatics has documented their absence inside tumors. These abnormalities result in elevated interstitial fluid pressure and hinder the delivery of therapeutic agents to tumors. In addition, they induce a hostile microenvironment characterized by hypoxia and acidosis, as documented by intravital imaging. The abnormal microenvironment further lowers the effectiveness of anti-tumor treatments such as radiation therapy and chemotherapy. In addition to these mechanistic insights, intravital imaging may also offer new opportunities to improve therapy. For example, tumor angiogenesis results in immature, dysfunctional vessels--primarily caused by an imbalance in production of pro- and anti-angiogenic factors by the tumors. Restoring the balance of pro- and anti-angiogenic signaling in tumors can "normalize" tumor vasculature and thus, improve its function, as demonstrated by intravital imaging studies in preclinical models and in cancer patients. Administration of cytotoxic therapy during periods of vascular normalization has the potential to enhance treatment efficacy.

摘要

活体成像技术为肿瘤微循环和微环境提供了前所未有的深入了解。例如,这些技术允许对肿瘤血管系统进行定量评估,以揭示其异常的组织、结构和功能(例如,高通透性、异质性和受损的血流)。同样,功能性淋巴管的成像记录了肿瘤内部缺乏这些淋巴管。这些异常导致间质液压力升高,并阻碍治疗剂输送到肿瘤。此外,活体成像记录了缺氧和酸中毒等特征的肿瘤内微环境恶化。异常的微环境进一步降低了放射治疗和化学疗法等抗肿瘤治疗的效果。除了这些机制上的见解外,活体成像还可能为改善治疗提供新的机会。例如,肿瘤血管生成导致不成熟、功能失调的血管——主要是由肿瘤产生的促血管生成和抗血管生成因子失衡引起的。通过活体成像研究在临床前模型和癌症患者中的研究表明,恢复肿瘤中促血管生成和抗血管生成信号的平衡可以“正常化”肿瘤血管,从而改善其功能。在血管正常化期间给予细胞毒性治疗有可能增强治疗效果。

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