Distinct time courses and mechanics of right ventricular hypertrophy and diastolic stiffening in a male rat model of pulmonary arterial hypertension

Kwan, Ethan Dillon; Vélez-Rendón, Daniela; Zhang, Xiaoyan; Hao, Mu; Patel, Megh; Pursell, Erica; Stowe, Jennifer; Valdez‐Jasso, Daniela

doi:10.1152/ajpheart.00046.2021

Cited by 14 publications

(31 citation statements)

References 59 publications

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“…None of these numerical permutations fundamentally altered our findings. In support of our findings, Baicu et al and Kwan et al suggested that hypertrophic thickening is primarily an early adaptive mechanism that improves systolic function, while myocardial stiffening is a late adaptive mechanism that improves the RV's resistance to excessive dilation 18,33 ; hence, concurring with our observations that myocardial stiffness is the primary mechanism driving RV stiffening.…”

Section: Myocardial Stiffening Is a Significant If Not Primary Cause ...supporting

confidence: 93%

“…The copyright holder for this preprint (which this version posted April 6, 2023. ; https://doi.org/10.1101/2023.04.03.535491 doi: bioRxiv preprint tricuspid valve leaflets underwent the same fibrotic changes in animals with RV failure 30 and are consistent with a general understanding of microstructural remodeling associated with fibrosis 31 . Importantly, our large animal model of PHT confirmed several previous findings that pulmonary hypertension induces myocardial stiffening 10,13,32,33 . Though, the current study is the first to subject maladapted RV myocardium to multi-directional shear loading scenarios.…”

Section: Myocardial Stiffening Is a Significant If Not Primary Cause ...supporting

confidence: 88%

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Untangling the mechanisms of pulmonary hypertension-induced right ventricular stiffening in a large animal model

Kakaletsis

Malinowski

Mathur

et al. 2023

Preprint

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Background: Pulmonary arterial hypertension (PHT) is a devastating disease with low survival rates. In PHT, chronic pressure overload leads to right ventricle (RV) remodeling and stiffening; thus, impeding diastolic filling and ventricular function. Multiple mechanisms contribute to RV stiffening, including wall thickening, microstructural disorganization, and myocardial stiffening. The relative importance of each mechanism is unclear. Our objective is to use a large animal model as well as experimental and computational approaches to untangle these mechanisms. Methods: We induced PHT in eight sheep via pulmonary artery banding. After eight weeks, the hearts underwent anatomic and diffusion tensor MRI to characterize wall thickening and microstructural disorganization. Additionally, myocardial samples underwent histological and gene expression analyses to quantify compositional changes and mechanical testing to quantify myocardial stiffening. All findings were compared to 12 control animals. Finally, we used computational modeling to disentangle the relative importance of each stiffening mechanism. Results: First, we found that the RVs of PHT animals thickened most at the base and the free wall. Additionally, we found that PHT induced excessive collagen synthesis and microstructural disorganization, consistent with increased expression of fibrotic genes. We also found that the myocardium itself stiffened significantly. Importantly, myocardial stiffening correlated significantly with excess collagen synthesis. Finally, our model of normalized RV pressure-volume relationships predicted that myocardial stiffness contributes to RV stiffening significantly more than other mechanisms. Conclusions: In summary, we found that PHT induces wall thickening, microstructural disorganization, and myocardial stiffening. These remodeling mechanisms were both spatially and directionally dependent. Using modeling, we show that myocardial stiffness is the primary contributor to RV stiffening. Thus, myocardial stiffening may be an important predictor for PHT progression. Given the significant correlation between myocardial stiffness and collagen synthesis, collagen-sensitive imaging modalities may be useful for non-invasively estimating myocardial stiffness and predicting PHT outcomes.

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Section: Myocardial Stiffening Is a Significant If Not Primary Cause ...supporting

confidence: 93%

Section: Myocardial Stiffening Is a Significant If Not Primary Cause ...supporting

confidence: 88%

Untangling the mechanisms of pulmonary hypertension-induced right ventricular stiffening in a large animal model

Kakaletsis

Malinowski

Mathur

et al. 2023

Preprint

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“…Finally, at week 5, an increase in RV wall stiffness assessed by biomechanical testing was noted. 10 Could the differential response to Sugen/ hypoxia between Sprague Dawley and CDF rats Mendiola et al report be due to different temporal response? Supporting a differential time course between Sprague Dawley and CDF rats is the observation that Sprague Dawley rats had a lower RVSP and higher TAPSE/RVSP than CDF rats.…”

Section: See Article By Mendiola Et Almentioning

confidence: 99%

Knowing All the Angles (on Right Ventricular Myocardial Remodeling)

Simon

Cormack

Kia

2023

Circ: Heart Failure

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“…It is worth noting that Laplace-type models can be used to study RV mechanics during PAH, beyond just the wall stress state. More recently, Vélez-Rendón et al (2018) and Kwan et al (2021) employed such a model to discriminate the contributions of morphological and intrinsic mechanisms (i.e., altered contractility and chamber stiffness) towards compensated RV function during the early stages of PAH. Their model of the RV comprised the RV cavity (assumed to be a fraction of a sphere), the RVFW and septum.…”

Section: Multiscale Models Of Rv Mechanics and Remodelingmentioning

confidence: 99%

“…Myocardial structure and mechanics are altered in response to pressure overload as shown in animal experimental models of PAH ( Bogaard et al, 2009b ; Rain et al, 2013 ; Vélez-Rendón et al, 2019 ; Kwan et al, 2021 ). The alteration in structure is mainly in the form of myocardial fibrosis, which leads to increased RV diastolic stiffness, supplemented by altered RV contractile force ( Rain et al, 2016 ; Wang et al, 2018 ).…”

Section: Scientific Insightsmentioning

confidence: 99%

Computational models of ventricular mechanics and adaptation in response to right-ventricular pressure overload

et al. 2022

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Pulmonary arterial hypertension (PAH) is associated with substantial remodeling of the right ventricle (RV), which may at first be compensatory but at a later stage becomes detrimental to RV function and patient survival. Unlike the left ventricle (LV), the RV remains understudied, and with its thin-walled crescent shape, it is often modeled simply as an appendage of the LV. Furthermore, PAH diagnosis is challenging because it often leaves the LV and systemic circulation largely unaffected. Several treatment strategies such as atrial septostomy, right ventricular assist devices (RVADs) or RV resynchronization therapy have been shown to improve RV function and the quality of life in patients with PAH. However, evidence of their long-term efficacy is limited and lung transplantation is still the most effective and curative treatment option. As such, the clinical need for improved diagnosis and treatment of PAH drives a strong need for increased understanding of drivers and mechanisms of RV growth and remodeling (G&R), and more generally for targeted research into RV mechanics pathology. Computational models stand out as a valuable supplement to experimental research, offering detailed analysis of the drivers and consequences of G&R, as well as a virtual test bench for exploring and refining hypotheses of growth mechanisms. In this review we summarize the current efforts towards understanding RV G&R processes using computational approaches such as reduced-order models, three dimensional (3D) finite element (FE) models, and G&R models. In addition to an overview of the relevant literature of RV computational models, we discuss how the models have contributed to increased scientific understanding and to potential clinical treatment of PAH patients.

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Distinct time courses and mechanics of right ventricular hypertrophy and diastolic stiffening in a male rat model of pulmonary arterial hypertension

Cited by 14 publications

References 59 publications

Untangling the mechanisms of pulmonary hypertension-induced right ventricular stiffening in a large animal model

Untangling the mechanisms of pulmonary hypertension-induced right ventricular stiffening in a large animal model

Knowing All the Angles (on Right Ventricular Myocardial Remodeling)

Computational models of ventricular mechanics and adaptation in response to right-ventricular pressure overload

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