Development and validation of an ex vivo porcine model of functional tricuspid regurgitation

Hannah Rando, Rachael Quinn, Emily L. Larson, Zachary Darby, Ifeanyi Chinedozi, J. K. Kang, Gyeongtae Moon, James S. Gammie
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Abstract

Background and Aim: Ex vivo models of functional tricuspid regurgitation (FTR) are needed for pre-clinical testing of novel surgical and interventional repair strategies, but current options are costly or have not been formally validated. The objective of this research was to create and validate an ex vivo model to test novel repair methods for FTR. Methods: In explanted porcine hearts, the right atrium was excised to visualize the tricuspid valve. The pulmonary artery and aorta were clamped and cannulated, the coronary arteries ligated, and the right and left ventricles statically pressurized with air to 30 mmHg and 120 mmHg, respectively. FTR was induced by increasing right ventricular pressure to 80 mmHg for 3 h, which resulted in progressive tricuspid annular enlargement, right ventricular dilation, papillary muscle displacement, and central tricuspid malcoaptation. A structured light scanner was used to image the 3D topography of the tricuspid valve in both the native and FTR state, and images were exported into scan-to-computer-aided design software, which allowed for high-resolution 3D computational reconstruction. Relevant geometric measurements were sampled including annular circumference and area, major and minor axis diameter, and tenting height, angle, and area. Geometric measurements from the ex vivo model were compared to clinical transthoracic echocardiographic (TTE) measurements using two-sample t-tests. Results: A total of 12 porcine hearts were included in the study. Annular measurements of the native valve were comparable to published TTE data, except for the minor axis diameter, which was shorter in the ex vivo model (2.5 vs. 3.1 cm, P = 0.007). Induction of FTR in the ex vivo model resulted in annular enlargement (FTR vs. native: circumference 13.7 vs.11.8 cm, P = 0.012; area 14 vs. 11 cm2, P = 0.011). Ex vivo leaflet measurements in both the native and FTR model differed from published TTE data, but demonstrated comparable directional changes between the native and regurgitant states, including increased tenting height, area, and volume. Conclusion: The ex vivo pneumatically-pressurized porcine model closely recapitulates the geometry of both the native and regurgitant tricuspid valve complex in humans and holds promise for testing novel FTR repair strategies. Relevance for Patients: Currently available interventions for the tricuspid valve have a risk of permanent conduction abnormalities and are insufficient in addressing tricuspid disease for a subset of patients. This ex vivo model provides a platform for testing of novel interventions that address the deficiencies of current tricuspid therapies.
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功能性三尖瓣反流猪体外模型的开发与验证
背景和目的:需要建立功能性三尖瓣反流(FTR)的体外模型,以便对新型手术和介入修复策略进行临床前测试,但目前的方案成本高昂或尚未经过正式验证。本研究的目的是创建并验证一个体外模型,以测试新型的 FTR 修复方法:方法:切除猪右心房以观察三尖瓣。钳夹并插管肺动脉和主动脉,结扎冠状动脉,用空气分别将左右心室静态加压至 30 mmHg 和 120 mmHg。通过将右心室压力升至 80 mmHg 并持续 3 小时诱导 FTR,从而导致三尖瓣环逐渐增大、右心室扩张、乳头肌移位和中央三尖瓣适应不良。使用结构光扫描仪对三尖瓣在原生和FTR状态下的三维形貌进行成像,并将图像导出到扫描计算机辅助设计软件中,以便进行高分辨率的三维计算重建。相关的几何测量数据包括瓣环周长和面积、主轴和小轴直径以及瓣翼高度、角度和面积。使用双样本 t 检验将体内外模型的几何测量值与临床经胸超声心动图(TTE)测量值进行比较:共有 12 颗猪心被纳入研究。原生瓣膜的瓣环测量值与已发表的 TTE 数据相当,但小轴直径除外,在体外模型中,小轴直径较短(2.5 厘米对 3.1 厘米,P = 0.007)。在体外模型中诱导 FTR 会导致瓣环增大(FTR 与原生瓣:周长 13.7 与 11.8 厘米,P = 0.012;面积 14 与 11 平方厘米,P = 0.011)。原发性和 FTR 模型的活体外小叶测量结果与已发表的 TTE 数据不同,但显示了原发性和反流状态之间相似的方向性变化,包括帐篷高度、面积和体积的增加:结论:体外气压加压猪模型近似再现了人体原发性和反流性三尖瓣复合体的几何形状,有望用于测试新型 FTR 修复策略:目前可用的三尖瓣干预措施存在永久性传导异常的风险,不足以解决部分患者的三尖瓣疾病问题。这种体外模型为测试新型干预措施提供了一个平台,可解决当前三尖瓣疗法的不足之处。
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