新生弓弦 Goldilocks：分析新弓弦长度对乳头肌力量的生物力学影响表明，较短的新弓弦具有更高的耐受性。

Neochordal Goldilocks: Analyzing the biomechanics of neochord length on papillary muscle forces suggests higher tolerance to shorter neochordae.

机构信息

Department of Cardiothoracic Surgery, Stanford University, Stanford, Calif; Department of Mechanical Engineering, Stanford University, Stanford, Calif.

Division of Cardiac Surgery, Massachusetts General Hospital, Harvard Medical School, Boston, Mass; Cardiac Ultrasound Laboratory, Massachusetts General Hospital, Harvard Medical School, Boston, Mass; University Department of Cardiac Surgery, Leipzig Heart Center, Leipzig, Germany.

出版信息

J Thorac Cardiovasc Surg. 2024 Apr;167(4):e78-e89. doi: 10.1016/j.jtcvs.2023.04.026. Epub 2023 May 7.

DOI:10.1016/j.jtcvs.2023.04.026

PMID:37160219

Abstract

OBJECTIVE

Estimating neochord lengths during mitral valve repair is challenging, because approximation must be performed largely based on intuition and surgical experience. Little data exist on quantifying the effects of neochord length misestimation. We aimed to evaluate the impact of neochord length on papillary muscle forces and mitral valve hemodynamics, which is especially pertinent because increased forces have been linked to aberrant mitral valve biomechanics.

METHODS

Porcine mitral valves (n = 8) were mounted in an ex vivo heart simulator, and papillary muscles were fixed to high-resolution strain gauges while hemodynamic data were recorded. We used an adjustable system to modulate neochord lengths. Optimal length was qualitatively verified by a single experienced operator, and neochordae were randomly lengthened or shortened in 1-mm increments up to ±5 mm from the optimal length.

RESULTS

Optimal length neochordae resulted in the lowest peak composite papillary muscle forces (6.94 ± 0.29 N), significantly different from all lengths greater than ±1 mm. Both longer and shorter neochordae increased forces linearly according to difference from optimal length. Both peak papillary muscle forces and mitral regurgitation scaled more aggressively for longer versus shorter neochordae by factors of 1.6 and 6.9, respectively.

CONCLUSIONS

Leveraging precision ex vivo heart simulation, we found that millimeter-level neochord length differences can result in significant differences in papillary muscle forces and mitral regurgitation, thereby altering valvular biomechanics. Differences in lengthened versus shortened neochordae scaling of forces and mitral regurgitation may indicate different levels of biomechanical tolerance toward longer and shorter neochordae. Our findings highlight the need for more thorough biomechanical understanding of neochordal mitral valve repair.

摘要

目的

在二尖瓣修复过程中估计腱索长度具有挑战性，因为必须主要基于直觉和手术经验进行逼近。关于定量评估腱索长度估计错误的影响的数据很少。我们旨在评估腱索长度对乳头肌力和二尖瓣血流动力学的影响，这一点尤为重要，因为增加的力与异常的二尖瓣生物力学有关。

方法

将猪二尖瓣（n=8）安装在体外心脏模拟器中，将乳头肌固定在高分辨率应变计上，同时记录血流动力学数据。我们使用可调系统来调节腱索长度。通过单个有经验的操作人员定性地验证最佳长度，然后将腱索随机延长或缩短 1 毫米，从最佳长度增加或减少±5 毫米。

结果

最佳长度腱索产生的峰值复合乳头肌力最低（6.94±0.29 N），与所有大于±1 毫米的长度明显不同。较长和较短的腱索都根据与最佳长度的差异呈线性增加力。峰值乳头肌力和二尖瓣反流都以更长和更短的腱索为倍数，分别为 1.6 和 6.9，更为激进地缩放。

结论

利用精确的体外心脏模拟，我们发现毫米级别的腱索长度差异可导致乳头肌力和二尖瓣反流显著不同，从而改变瓣膜生物力学。延长和缩短腱索的力和二尖瓣反流的差异可能表明对更长和更短腱索的生物力学耐受性不同。我们的发现强调了需要更深入地了解腱索二尖瓣修复的生物力学。

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新生弓弦 Goldilocks：分析新弓弦长度对乳头肌力量的生物力学影响表明，较短的新弓弦具有更高的耐受性。

Neochordal Goldilocks: Analyzing the biomechanics of neochord length on papillary muscle forces suggests higher tolerance to shorter neochordae.

机构信息

出版信息

OBJECTIVE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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