Department of Neurosurgery, Universitätsmedizin Charitè, Campus Virchow Klinikum, Augustenburger Platz 1, 13353 Berlin, Germany.
Eur J Cancer. 2011 May;47(8):1276-84. doi: 10.1016/j.ejca.2011.02.001. Epub 2011 Mar 9.
Various strategies using L19-mediated fibronectin targeting have become useful clinical tools in anti-tumour therapy and diagnostics. The aim of our study was to characterise the microvascular biodistribution and binding process during tumour angiogenesis and after anti-angiogenic therapy.
SF126 glioma and F9 teratocarcinoma cells were implanted into dorsal skin fold chambers (SF126: n = 4; F9: n = 6). Using fluorescence and confocal intravital microscopy the biodistribution process was assessed at t = 0 h, t = 4 h and t = 24 h after intravenous application of Cy3-L19-SIP. Sunitinib treatment was applied for six days and microscopy was performed 2 and 6 days after treatment initiation. Analysed parameters included: vascular and interstitial binding, preferential binding sites of L19-SIP, microvascular blood flow rate, microvascular permeability. Histological analysis included CD31 and DAPI.
L19-SIP showed a specific and time-dependent neovascular binding with a secondary extravasation process reaching optimal vascular/interstitial binding ratio 4 hours after iv administration (F9: L19-SIP: vascular binding: 74.6 ± 14.5; interstitial binding: 46.8 ± 12.1; control vascular: 22,2 ± 16.6). Angiogenic sprouts were preferred binding sites (F9: L19-SIP: 188 ± 15.5; RTV: 90.6 ± 13.5). Anti-angiogenic therapy increased microvascular hemodynamics (SF126: Su: 106.6 ± 13.3 μl/sec; Untreated: 19.7 ± 9.1 μl/sec) and induced increased L19-SIP accumulation (SF 126: t24; Su: 92.6 ± 2.7; Untreated: 71.9 ± 5.9) in therapy resistant tumour vessels.
L19-SIP shows a time and blood-flow dependent microvascular biodistribution process with angiogenic sprouts as preferential binding sites followed by secondary extravasation of the antibody. Microvascular biodistribution is enhanced in anti-angiogenic-therapy resistant tumour vessels.
利用 L19 介导的纤连蛋白靶向的各种策略已成为肿瘤治疗和诊断中有用的临床工具。我们的研究目的是描述肿瘤血管生成期间和抗血管生成治疗后的微血管生物分布和结合过程。
将 SF126 神经胶质瘤和 F9 畸胎瘤细胞植入背部皮肤折叠室(SF126:n = 4;F9:n = 6)。使用荧光和共聚焦活体显微镜,在静脉内应用 Cy3-L19-SIP 后 0 h、4 h 和 24 h 评估生物分布过程。应用舒尼替尼治疗 6 天,并在治疗开始后 2 天和 6 天进行显微镜检查。分析的参数包括:血管和间质结合、L19-SIP 的优先结合部位、微血管血流速度、微血管通透性。组织学分析包括 CD31 和 DAPI。
L19-SIP 表现出特异性和时间依赖性新生血管结合,二次外渗过程在静脉给药后 4 小时达到最佳血管/间质结合比(F9:L19-SIP:血管结合:74.6 ± 14.5;间质结合:46.8 ± 12.1;对照血管:22.2 ± 16.6)。血管生成芽是优先结合部位(F9:L19-SIP:188 ± 15.5;RTV:90.6 ± 13.5)。抗血管生成治疗增加了微血管血液动力学(SF126:Su:106.6 ± 13.3 μl/sec;未治疗:19.7 ± 9.1 μl/sec)并诱导 L19-SIP 在治疗抵抗肿瘤血管中积累增加(SF 126:t24;Su:92.6 ± 2.7;未治疗:71.9 ± 5.9)。
L19-SIP 表现出时间和血流依赖性微血管生物分布过程,血管生成芽作为优先结合部位,随后是抗体的继发性外渗。在抗血管生成治疗抵抗的肿瘤血管中,微血管生物分布增加。
