Avery Ryan, Day Kevin, Jokerst Clinton, Kazui Toshinobu, Krupinski Elizabeth, Khalpey Zain
Department of Medical Imaging, Banner - University Medical Center, 1501 N. Campbell Ave, PO Box 245067, Tucson, AZ, 85724, USA.
Department of Radiology, Mayo Clinic Hospital - Phoenix, Phoenix, AZ, USA.
J Cardiothorac Surg. 2017 Oct 10;12(1):89. doi: 10.1186/s13019-017-0652-y.
Advanced heart failure treated with a left ventricular assist device is associated with a higher risk of right heart failure. Many advanced heart failures patients are treated with an ICD, a relative contraindication to MRI, prior to assist device placement. Given this limitation, left and right ventricular function for patients with an ICD is calculated using radionuclide angiography utilizing planar multigated acquisition (MUGA) and first pass radionuclide angiography (FPRNA), respectively. Given the availability of MRI protocols that can accommodate patients with ICDs, we have correlated the findings of ventricular functional analysis using radionuclide angiography to cardiac MRI, the reference standard for ventricle function calculation, to directly correlate calculated ejection fractions between these modalities, and to also assess agreement between available echocardiographic and hemodynamic parameters of right ventricular function.
A retrospective review from January 2012 through May 2014 was performed to identify advanced heart failure patients who underwent both cardiac MRI and radionuclide angiography for ventricular functional analysis. Nine heart failure patients (8 men, 1 woman; mean age of 57.0 years) were identified. The average time between the cardiac MRI and radionuclide angiography exams was 38.9 days (range: 1 - 119 days). All patients undergoing cardiac MRI were scanned using an institutionally approved protocol for ICD with no device-related complications identified. A retrospective chart review of each patient for cardiomyopathy diagnosis, clinical follow-up, and echocardiogram and right heart catheterization performed during evaluation was also performed.
The 9 patients demonstrated a mean left ventricular ejection fraction (LVEF) using cardiac MRI of 20.7% (12 - 40%). Mean LVEF using MUGA was 22.6% (12 - 49%). The mean right ventricular ejection fraction (RVEF) utilizing cardiac MRI was 28.3% (16 - 43%), and the mean RVEF calculated by FPRNA was 32.6% (9 - 56%). The mean discrepancy for LVEF between cardiac MRI and MUGA was 4.1% (0 - 9%), and correlation of calculated LVEF using cardiac MRI and MUGA demonstrated an R of 0.9. The mean discrepancy for RVEF between cardiac MRI and FPRNA was 12.0% (range: 2 - 24%) with a moderate correlation (R = 0.5). The increased discrepancies for RV analysis were statistically significant using an unpaired t-test (t = 3.19, p = 0.0061). Echocardiogram parameters of RV function, including TAPSE and FAC, were for available for all 9 patients and agreement with cardiac MRI demonstrated a kappa statistic for TAPSE of 0.39 (95% CI of 0.06 - 0.72) and for FAC of 0.64 (95% of 0.21 - 1.00).
Heart failure patients are increasingly requiring left ventricular assist device placement; however, definitive evaluation of biventricular function is required due to the increased mortality rate associated with right heart failure after assist device placement. Our results suggest that FPRNA only has a moderate correlation with reference standard RVEFs calculated using cardiac MRI, which was similar to calculated agreements between cardiac MRI and echocardiographic parameters of right ventricular function. Given the need for identification of patients at risk for right heart failure, further studies are warranted to determine a more accurate estimate of RVEF for heart failure patients during pre-operative ventricular assist device planning.
采用左心室辅助装置治疗的晚期心力衰竭与右心衰竭风险较高相关。许多晚期心力衰竭患者在植入辅助装置之前接受了植入式心脏除颤器(ICD)治疗,而ICD是MRI检查的相对禁忌证。鉴于这一限制,对于植入ICD的患者,分别采用平面多门控采集(MUGA)放射性核素血管造影和首次通过放射性核素血管造影(FPRNA)来计算左、右心室功能。鉴于已有可用于ICD患者的MRI检查方案,我们将放射性核素血管造影的心室功能分析结果与心脏MRI(心室功能计算的参考标准)进行了关联,以直接对比这两种检查方法计算出的射血分数,并评估现有的右心室功能超声心动图参数与血流动力学参数之间的一致性。
对2012年1月至2014年5月期间进行回顾性分析,以确定同时接受心脏MRI和放射性核素血管造影进行心室功能分析的晚期心力衰竭患者。共纳入9例心力衰竭患者(8例男性,1例女性;平均年龄57.0岁)。心脏MRI检查与放射性核素血管造影检查之间的平均时间间隔为38.9天(范围:1 - 119天)。所有接受心脏MRI检查的患者均采用机构批准的ICD检查方案进行扫描,未发现与设备相关的并发症。同时对每位患者的心肌病诊断、临床随访以及评估期间进行的超声心动图和右心导管检查进行回顾性病历分析。
9例患者心脏MRI测得的平均左心室射血分数(LVEF)为20.7%(12% - 40%)。MUGA测得的平均LVEF为22.6%(12% - 49%)。心脏MRI测得的平均右心室射血分数(RVEF)为28.3%(16% - 43%),FPRNA计算得出的平均RVEF为32.6%(9% - 56%)。心脏MRI与MUGA测得的LVEF平均差异为4.1%(0% - 9%),心脏MRI与MUGA计算得出的LVEF相关性显示R值为0.9。心脏MRI与FPRNA测得的RVEF平均差异为12.0%(范围:2% - 24%),相关性中等(R = 0.5)。使用不成对t检验,右心室分析中差异增加具有统计学意义(t = 3.19,p = 0.0061)。9例患者均有右心室功能的超声心动图参数,包括三尖瓣环平面收缩期位移(TAPSE)和右心室面积变化分数(FAC),其与心脏MRI的一致性显示,TAPSE的kappa统计值为0.39(95%置信区间为0.06 - 0.72),FAC的kappa统计值为0.64(95%置信区间为0.21 - 1.00)。
心力衰竭患者越来越需要植入左心室辅助装置;然而,由于辅助装置植入后右心衰竭相关死亡率增加,需要对双心室功能进行明确评估。我们的结果表明,FPRNA与使用心脏MRI计算的参考标准RVEF仅具有中等相关性,这与心脏MRI和右心室功能超声心动图参数之间计算出的一致性相似。鉴于需要识别右心衰竭风险患者,有必要进一步开展研究,以在术前心室辅助装置规划期间更准确地评估心力衰竭患者的RVEF。
