Rapp Joseph H, Zhu Lei, Hollenbeck Kelsey, Sarkar Rajabrata, Velez Pauline M, Reilly Linda M, Hiramoto Jade, Pan Xian-Mang
Division of Vascular Surgery, Department of Surgery, University of California, San Francisco, USA.
J Vasc Surg. 2009 May;49(5):1181-8. doi: 10.1016/j.jvs.2008.12.028. Epub 2009 Feb 23.
Choices for embolic protection during carotid stent procedures include distal filtration (DF) and proximal occlusion with flow reversal (POFR). DF devices are widely used but have produced only modest improvements in clinical outcomes. There is less experience with POFR devices but single center reports suggest reduced emboli detected by transcranial Doppler (TCD). To determine if POFR offers a significant improvement in embolic protection, we tested five DF devices and two POFR devices with 8F and 10F sheath design in an ex vivo angioplasty system using human carotid plaques excised en bloc. Physiologic pressures and flows were used and the efficiency of plaque fragment removal by these devices compared.
Thirty-three human carotid plaques removed en bloc were secured in tailored polytetrafluoroethylene (PTFE) grafts. The distal PTFE was either 6 mm or 5 mm inner diameter (ID). Saline was delivered through the excised carotid plaque as follows: a cleaning 50 mL flush was done prior to the angioplasty procedure and discarded; further flushes of forward flow were done with five pressurized "pulsations" of 10 mL each (50 mL), peak pressure 140 mm Hg. Balloon angioplasty was done with a 4 mm and then a 6 mm balloon. DF flushes were applied after each angioplasty and "postprocedure" after the device was removed. With POFR, 50 mL were collected through the sheath after balloon angioplasty by either back-pressure of 20 mm Hg, 40 mm Hg or 60 mm Hg, or by aspiration. Postangioplasty pressurized forward flush of 50 or 100 mL was done as described. Each flush was collected, centrifuged, and examined for plaque fragments. Fragments greater than 60 microns were sized and counted on a 100 micron grid.
When DF devices were used in 6 mm lumen PTFE, the percent of fragments trapped was poor (13.7% to 27.8%). There were no statistically significant differences between the devices. The capture of fragments improved (22% vs 51.4%, P < .001) when devices appropriate for a 6 mm lumen were used in a 5 mm PTFE "ICA", functionally over-sizing the devices. POFR efficiency improved with increasing back-pressures and with repeated aspirations. Postprocedure, successive flushes of pressurized forward flow yielded additional plaque fragments and when the efficiency of POFR was assessed with forward flushing volumes similar to those used for DF, the efficiencies were similar, although larger fragments were more efficiently removed with POFR.
In our model, both protection strategies were less than ideal. For POFR, high back pressures or multiple aspirations improve the efficiency of cerebral protection but additional fragments were released by pressurized flow even after aspiration of 150 mL of saline. DF devices create a pressure gradient and fragments apparently went around the device with pressurized flow in our PTFE lumen. Over-sizing of DF devices partially corrected this problem and increased over all DF efficiency to be comparable to POFR for smaller fragments but not for larger fragments.
颈动脉支架置入术期间的栓子保护选择包括远端滤网(DF)和近端血流逆转闭塞(POFR)。DF装置被广泛使用,但在临床结果方面仅产生了适度改善。POFR装置的使用经验较少,但单中心报告显示经颅多普勒(TCD)检测到的栓子减少。为了确定POFR是否在栓子保护方面有显著改善,我们在一个体外血管成形系统中,使用整块切除的人颈动脉斑块,对5种DF装置和2种具有8F和10F鞘管设计的POFR装置进行了测试。使用了生理压力和流量,并比较了这些装置清除斑块碎片的效率。
将33块整块切除的人颈动脉斑块固定在特制的聚四氟乙烯(PTFE)移植物中。远端PTFE的内径为6毫米或5毫米。生理盐水通过切除的颈动脉斑块输送如下:在血管成形术之前进行一次50毫升的冲洗以清洁并弃去;再进行5次每次10毫升(共50毫升)的加压“搏动”正向冲洗,峰值压力为140毫米汞柱。先用4毫米然后用6毫米的球囊进行球囊血管成形术。每次血管成形术后应用DF冲洗,并在移除装置后进行“术后”冲洗。对于POFR,在球囊血管成形术后通过20毫米汞柱、40毫米汞柱或60毫米汞柱的背压或抽吸,通过鞘管收集50毫升液体。如所述进行50或100毫升的血管成形术后加压正向冲洗。每次冲洗液收集后离心,并检查有无斑块碎片。大于60微米的碎片在100微米网格上进行大小测量和计数。
当DF装置用于内径6毫米的PTFE时,捕获的碎片百分比很低(13.7%至27.8%)。各装置之间无统计学显著差异。当适合内径6毫米的装置用于内径5毫米的PTFE“颈内动脉”(ICA)时(功能上使装置尺寸过大),碎片捕获率有所提高(22%对51.4%,P<.001)。POFR效率随着背压增加和重复抽吸而提高。术后,连续的加压正向冲洗产生了额外的斑块碎片,当用与DF类似的正向冲洗量评估POFR效率时,效率相似,尽管POFR能更有效地清除较大碎片。
在我们的模型中,两种保护策略都不太理想。对于POFR,高背压或多次抽吸可提高脑保护效率,但即使在抽吸150毫升生理盐水后,加压血流仍会释放额外的碎片。DF装置会产生压力梯度,在我们的PTFE管腔中,碎片显然会随着加压血流绕过装置。DF装置尺寸过大可部分纠正这一问题,并使总体DF效率提高,对于较小碎片与POFR相当,但对于较大碎片则不然。
