机械力在肿瘤生长和治疗中的作用。
The role of mechanical forces in tumor growth and therapy.
作者信息
Jain Rakesh K, Martin John D, Stylianopoulos Triantafyllos
机构信息
Edwin L. Steele Laboratory, Department of Radiation Oncology, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts 02114; email:
出版信息
Annu Rev Biomed Eng. 2014 Jul 11;16:321-46. doi: 10.1146/annurev-bioeng-071813-105259.
Abstract
Tumors generate physical forces during growth and progression. These physical forces are able to compress blood and lymphatic vessels, reducing perfusion rates and creating hypoxia. When exerted directly on cancer cells, they can increase cells' invasive and metastatic potential. Tumor vessels-while nourishing the tumor-are usually leaky and tortuous, which further decreases perfusion. Hypoperfusion and hypoxia contribute to immune evasion, promote malignant progression and metastasis, and reduce the efficacy of a number of therapies, including radiation. In parallel, vessel leakiness together with vessel compression causes a uniformly elevated interstitial fluid pressure that hinders delivery of blood-borne therapeutic agents, lowering the efficacy of chemo- and nanotherapies. In addition, shear stresses exerted by flowing blood and interstitial fluid modulate the behavior of cancer and a variety of host cells. Taming these physical forces can improve therapeutic outcomes in many cancers.
摘要
肿瘤在生长和进展过程中会产生物理力。这些物理力能够压迫血管和淋巴管,降低灌注率并导致缺氧。当直接作用于癌细胞时,它们会增加细胞的侵袭和转移潜能。肿瘤血管在滋养肿瘤的同时通常是渗漏且迂曲的,这进一步降低了灌注。低灌注和缺氧有助于免疫逃逸,促进恶性进展和转移,并降低包括放疗在内的多种治疗方法的疗效。与此同时,血管渗漏和血管受压共同导致间质液压力普遍升高,阻碍血源性治疗药物的递送,降低化疗和纳米治疗的疗效。此外,流动的血液和间质液施加的剪切应力会调节癌细胞和多种宿主细胞的行为。控制这些物理力可以改善许多癌症的治疗效果。
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