A novel method for quantifying in-vivo regional left ventricular myocardial contractility in the border zone of a myocardial infarction

Lik Chuan Lee¹, Jonathan F Wenk, Doron Klepach, Zhihong Zhang, David Saloner, Arthur W Wallace, Liang Ge, Mark B Ratcliffe, Julius M Guccione

Affiliations

PMID: 22010752
PMCID: PMC3207355
DOI: 10.1115/1.4004995

A novel method for quantifying in-vivo regional left ventricular myocardial contractility in the border zone of a myocardial infarction

Lik Chuan Lee et al. J Biomech Eng. 2011 Sep.

. 2011 Sep;133(9):094506.

doi: 10.1115/1.4004995.

Authors

Lik Chuan Lee¹, Jonathan F Wenk, Doron Klepach, Zhihong Zhang, David Saloner, Arthur W Wallace, Liang Ge, Mark B Ratcliffe, Julius M Guccione

Affiliation

¹ Departments of Surgery and Bioengineering, University of California, San Francisco, CA 94143, USA. likchuan@berkeley.edu

PMID: 22010752
PMCID: PMC3207355
DOI: 10.1115/1.4004995

Abstract

Homogeneous contractility is usually assigned to the remote region, border zone (BZ), and the infarct in existing infarcted left ventricle (LV) mathematical models. Within the LV, the contractile function is therefore discontinuous. Here, we hypothesize that the BZ may in fact define a smooth linear transition in contractility between the remote region and the infarct. To test this hypothesis, we developed a mathematical model of a sheep LV having an anteroapical infarct with linearly-varying BZ contractility. Using an existing optimization method (Sun et al., 2009, "A Computationally Efficient Formal Optimization of Regional Myocardial Contractility in a Sheep With Left Ventricular Aneurysm," J. Biomech. Eng., 131(11), pp. 111001), we use that model to extract active material parameter T(max) and BZ width d(n) that "best" predict in-vivo systolic strain fields measured from tagged magnetic resonance images (MRI). We confirm our hypothesis by showing that our model, compared to one that has homogeneous contractility assigned in each region, reduces the mean square errors between the predicted and the measured strain fields. Because the peak fiber stress differs significantly (~15%) between these two models, our result suggests that future mathematical LV models, particularly those used to analyze myocardial infarction treatment, should account for a smooth linear transition in contractility within the BZ.

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Figures

**Fig. 1**
Sheep LV with anteroapical aneurysm. (a) Finite element mesh and (b) contractility T_max in BZ. Dotted line: homogeneous T_max in BZ. Solid line: linearly–varying T_max with distance d in BZ.

**Fig. 2**
Optimization results: (a) convergence with BZ width d_n as a parameter and (b) converged value of OBJ versus d_n

**Fig. 3**
Contractility in the border zone. d_n = 3 cm. T_max- _R = 186.3 kPa

**Fig. 4**
Comparison of stress in myoﬁber direction at ES. (a) Linearly–varying T_max- *_BZ* with d_n = 3 cm and T_max- _R = 186.3 kPa. (b) Homogeneous T_max- *_BZ* with T_max- _R = 190.1 kPa and T_max- BZ = 60.3 kPa. Unit of fringe levels in kPa.

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A novel method for quantifying in-vivo regional left ventricular myocardial contractility in the border zone of a myocardial infarction

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A novel method for quantifying in-vivo regional left ventricular myocardial contractility in the border zone of a myocardial infarction

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