CT 血管造影-透视融合成像在经心尖入路中的应用。

CT angiography-fluoroscopy fusion imaging for percutaneous transapical access.

机构信息

Department of Cardiovascular Medicine, Division of Structural and Congenital Heart Disease, Lenox Hill Heart and Vascular Institute-North Shore/Long Island Jewish Health System, New York, New York.

Department of Medicine, Temple University School of Medicine, Philadelphia, Pennsylvania.

出版信息

JACC Cardiovasc Imaging. 2014 Feb;7(2):169-77. doi: 10.1016/j.jcmg.2013.10.009. Epub 2014 Jan 8.

DOI:10.1016/j.jcmg.2013.10.009

PMID:24412189

Abstract

OBJECTIVES

The aim of this proof-of-principle study is to validate the accuracy of fusion imaging for percutaneous transapical access (TA).

BACKGROUND

Structural heart disease interventions, including TA, are commonly obtained under fluoroscopic guidance, which lacks important spatial information. Computed tomographic angiography (CTA)-fluoroscopy fusion imaging can provide the 3-dimensional information necessary for improved accuracy in planning and guidance of these interventions.

METHODS

Twenty consecutive patients scheduled for percutaneous left ventricular puncture and device closure using CTA-fluoroscopy fusion guidance were prospectively recruited. The HeartNavigator software (Philips Healthcare, Best, the Netherlands) was used to landmark the left ventricular epicardium for TA (planned puncture site [PPS]). The PPS landmark was compared with the position of the TA closure device on post-procedure CTA (actual puncture site). The distance between the PPS and actual puncture site was calculated from 2 fixed reference points (left main ostium and mitral prosthesis center) in 3 planes (x, y, and z). The distance from the left anterior descending artery at the same z-plane was also assessed. TA-related complications associated with fusion imaging were recorded.

RESULTS

The median (interquartile range [IQR]) TA distance difference between the PPS and actual puncture site from the referenced left main ostium and mitral prosthesis center was 5.00 mm (IQR: 1.98 to 12.64 mm) and 3.27 mm (IQR: 1.88 to 11.24 mm) in the x-plane, 4.48 mm (IQR: 1.98 to 13.08 mm) and 4.00 mm (IQR: 1.62 to 11.86 mm) in the y-plane, and 5.57 mm (IQR: 3.89 to 13.62 mm) and 4.96 mm (IQR: 1.92 to 11.76 mm) in the z-plane. The mean TA distance to the left anterior descending artery was 15.5 ± 7.8 mm and 22.7 ± 13.7 mm in the x- and y-planes. No TA-related complications were identified, including evidence of coronary artery laceration.

CONCLUSIONS

With the use of CTA-fluoroscopy fusion imaging to guide TA, the actual puncture site can be approximated near the PPS. Moreover, fusion imaging can help maintain an adequate access distance from the left anterior descending artery, thereby, potentially reducing TA-related complications.

摘要

目的

本原理验证研究旨在验证经心尖入路（TA）经融合成像引导进行经皮穿刺的准确性。

背景

结构性心脏病介入治疗，包括 TA，通常在透视引导下进行，缺乏重要的空间信息。计算机断层血管造影（CTA）-透视融合成像可提供必要的 3 维信息，以提高这些介入治疗的规划和指导的准确性。

方法

前瞻性招募了 20 例连续接受 CTA-透视融合引导下经皮左心室穿刺和器械闭合治疗的患者。使用 HeartNavigator 软件（荷兰飞利浦医疗保健公司）对左心室心外膜进行 TA（计划穿刺部位[PPS]）定位。将 PPS 标记与术后 CTA 中的 TA 闭合装置位置（实际穿刺部位）进行比较。从 2 个固定参考点（左主干开口和二尖瓣假体中心）在 3 个平面（x、y 和 z）上计算 PPS 和实际穿刺部位之间的距离。还评估了同一 z 平面左前降支的距离。记录了与融合成像相关的 TA 相关并发症。

结果

从左主干开口和二尖瓣假体中心参考点来看，PPS 和实际穿刺部位之间的 TA 距离差异在 x 平面为 5.00mm（IQR：1.98 至 12.64mm）和 3.27mm（IQR：1.88 至 11.24mm），y 平面为 4.48mm（IQR：1.98 至 13.08mm）和 4.00mm（IQR：1.62 至 11.86mm），z 平面为 5.57mm（IQR：3.89 至 13.62mm）和 4.96mm（IQR：1.92 至 11.76mm）。左前降支的 TA 距离平均值为 x 平面 15.5 ± 7.8mm 和 y 平面 22.7 ± 13.7mm。在 x 平面和 y 平面上均未发现 TA 相关并发症，包括冠状动脉撕裂的证据。

结论

使用 CTA-透视融合成像引导 TA 时，实际穿刺部位可接近 PPS。此外，融合成像可帮助保持与左前降支足够的进入距离，从而降低 TA 相关并发症的风险。

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CT 血管造影-透视融合成像在经心尖入路中的应用。

CT angiography-fluoroscopy fusion imaging for percutaneous transapical access.

机构信息

出版信息

OBJECTIVES

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

目的

背景

方法

结果

结论

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