Garcia Emmanuel, Becker Veronika G C, McCullough Danielle J, Stabley John N, Gittemeier Elizabeth M, Opoku-Acheampong Alexander B, Sieman Dietmar W, Behnke Bradley J
Department of Kinesiology, Kansas State University, Manhattan, Kansas;
Department of Kinesiology, Kansas State University, Manhattan, Kansas; Department of Sports Science, Leipzig University, Leipzig, Germany;
J Appl Physiol (1985). 2016 Jul 1;121(1):15-24. doi: 10.1152/japplphysiol.00266.2016. Epub 2016 Apr 28.
Given the critical role of tumor O2 delivery in patient prognosis and the rise in preclinical exercise oncology studies, we investigated tumor and host tissue blood flow at rest and during exercise as well as vascular reactivity using a rat prostate cancer model grown in two transplantation sites. In male COP/CrCrl rats, blood flow (via radiolabeled microspheres) to prostate tumors [R3327-MatLyLu cells injected in the left flank (ectopic) or ventral prostate (orthotopic)] and host tissue was measured at rest and during a bout of mild-intensity exercise. α-Adrenergic vasoconstriction to norepinephrine (NE: 10(-9) to 10(-4) M) was determined in arterioles perforating the tumors and host tissue. To determine host tissue exercise hyperemia in healthy tissue, a sham-operated group was included. Blood flow was lower at rest and during exercise in ectopic tumors and host tissue (subcutaneous adipose) vs. the orthotopic tumor and host tissue (prostate). During exercise, blood flow to the ectopic tumor significantly decreased by 25 ± 5% (SE), whereas flow to the orthotopic tumor increased by 181 ± 30%. Maximal vasoconstriction to NE was not different between arterioles from either tumor location. However, there was a significantly higher peak vasoconstriction to NE in subcutaneous adipose arterioles (92 ± 7%) vs. prostate arterioles (55 ± 7%). Establishment of the tumor did not alter host tissue blood flow from either location at rest or during exercise. These data demonstrate that blood flow in tumors is dependent on host tissue hemodynamics and that the location of the tumor may critically affect how exercise impacts the tumor microenvironment and treatment outcomes.
鉴于肿瘤氧输送在患者预后中的关键作用以及临床前运动肿瘤学研究的增加,我们使用在两个移植部位生长的大鼠前列腺癌模型,研究了静息和运动期间肿瘤及宿主组织的血流以及血管反应性。在雄性COP/CrCrl大鼠中,测量了静息和轻度强度运动期间前列腺肿瘤[注射在左腹(异位)或腹侧前列腺(原位)的R3327-MatLyLu细胞]和宿主组织的血流(通过放射性微球)。测定了穿透肿瘤和宿主组织的小动脉对去甲肾上腺素(NE:10(-9)至10(-4)M)的α-肾上腺素能血管收缩作用。为了确定健康组织中的宿主组织运动性充血,纳入了假手术组。与原位肿瘤和宿主组织(前列腺)相比,异位肿瘤和宿主组织(皮下脂肪)在静息和运动期间的血流较低。运动期间,异位肿瘤的血流显著减少25±5%(标准误),而原位肿瘤的血流增加181±30%。来自任何一个肿瘤部位的小动脉对NE的最大血管收缩作用没有差异。然而,皮下脂肪小动脉对NE的峰值血管收缩作用(92±7%)显著高于前列腺小动脉(55±7%)。肿瘤的形成并未改变任何一个部位的宿主组织在静息或运动期间的血流。这些数据表明,肿瘤中的血流取决于宿主组织的血流动力学,并且肿瘤的位置可能严重影响运动对肿瘤微环境和治疗结果的影响。