Quantitative Evaluation of Cardiac Cell Interactions and Responses to Cyclic Strain

Tran, Ryan; Morris, Tessa Altair; Gonzalez, Daniela; Hetta, Ali Hatem Salaheldin Hassan Ahmed; Grosberg, Anna

doi:10.3390/cells10113199

Cited by 4 publications

(11 citation statements)

References 91 publications

(163 reference statements)

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“…These results indicate that the strain-induced alignment of CMs in co-culture with cFBs is not caused by paracrine signaling nor to Cx43 or N-cadherin mediated cell-cell communication between the CMs and cFBs. This is in line with a recent report showing a lack of Cx43 and N-cadherin-mediated cell-cell communication in the co-culture organization of neonatal rat CMs and cFBs [41]. Future experiments using targeted inhibition of Cx43 and N-cadherin in co-cultures under cyclic strain together with transcriptional analysis should be performed to validate these findings.…”

Section: Resultssupporting

confidence: 90%

Section: Strain Avoidance Of Cms In the Presence Of Cfbs Is Not Media...supporting

confidence: 93%

“…Whereas, to our knowledge, no literature exists for human tissues or models on how the amount of cFBs modulates strain avoidance of CMs, a recent study by Tran et al demonstrated a cell density dependent response to cyclic strain for co-cultures of varying ratios of neonatal rat CMs and cFBs [41]. In contrast to hPSC-derived CMs, monocultures of neonatal rat CMs oriented along the direction of cyclic strain and increasing the amount of cFBs in the co-culture resulted in orientation away from the direction of the applied cyclic strain.…”

Section: Discussionmentioning

confidence: 99%

“…In contrast to hPSC-derived CMs, monocultures of neonatal rat CMs oriented along the direction of cyclic strain and increasing the amount of cFBs in the co-culture resulted in orientation away from the direction of the applied cyclic strain. However, a higher number of cFBs was needed to induce strain avoidance in neonatal rat CMs as opposed to in co-cultures of human cFBs and CMs derived from pluripotent stem cells, possibly due to differences in maturity and contractile state between the two types of CMs [41]. Moreover, several studies have investigated the contribution of the amount of cFBs on CM alignment and maturity.…”

Section: Discussionmentioning

confidence: 99%

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Human pluripotent stem cell-derived cardiomyocytes align under cyclic strain when guided by cardiac fibroblasts

Mostert

Groenen

Klouda

et al. 2021

Preprint

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The human myocardium is a mechanically active tissue typified by the anisotropic organization of cells and extracellular matrix (ECM). Upon injury, the composition of the myocardium changes, resulting in disruption of tissue organization and loss of coordinated contraction. Understanding how anisotropic organization in the adult myocardium is shaped and disrupted by environmental cues is thus critical, not only for unravelling the processes taking place during disease progression, but also for developing regenerative strategies to recover tissue function. Here, we decoupled in vitro the two major physical cues that are inherent in the myocardium: structural ECM and mechanical strain. We show that patterned ECM proteins control the orientation of the two main cell types in the myocardium: human cardiac fibroblasts (cFBs) and cardiomyocytes (hiPSC-CMs), despite their different mechanosensing machinery. Uniaxial cyclic strain, mimicking the local anisotropic deformation of the myocardium, did not affect hiPSC-CMs orientation. It did however induce a reorientation of cFBs, perpendicular to the strain direction, albeit this strain-avoidance response was overruled in the presence of anisotropic structural cues. These findings reveal that the mechanoresponsiveness of cFBs may be a critical handle in controlling myocardial tissue structure and function. To test this, we co-cultured hiPSC-CMs and cFBs in varying cell ratios to reconstruct normal and pathological myocardium. Contrary to the hiPSC-CM monoculture, the co-cultures adopted an anisotropic organization under uniaxial cyclic strain, regardless of the cell ratio. Together, these results identify the cFBs as a therapeutic target to mechanically restore structural organization of the tissue in cardiac regenerative therapies.

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Section: Resultssupporting

confidence: 90%

Section: Strain Avoidance Of Cms In the Presence Of Cfbs Is Not Media...supporting

confidence: 93%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 2 more Smart Citations

Human pluripotent stem cell-derived cardiomyocytes align under cyclic strain when guided by cardiac fibroblasts

Mostert

Groenen

Klouda

et al. 2021

Preprint

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show abstract

“…Dynamic reorganization and remodeling of actin stress fibers in combination with a nucleo-cytoskeletal connection are believed to play an important role in the cell type-dependent response to uniaxial cyclic strain (mechanoresponse). 23–25 While cFBs are consistent in their strain avoidance behavior, 26,27 CMs show inconsistent responses, 27–31 probably related to differences in their contractile state and actin organization. 32,33 To date, CM mechanoresponse remains largely unexplored, contributing to the controversy about how CMs respond to cyclic strain.…”

Section: Introductionmentioning

confidence: 99%

Human pluripotent stem cell-derived cardiomyocytes align under cyclic strain when guided by cardiac fibroblasts

et al. 2022

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The myocardium is a mechanically active tissue typified by anisotropy of the resident cells [cardiomyocytes (CMs) and cardiac fibroblasts (cFBs)] and the extracellular matrix (ECM). Upon ischemic injury, the anisotropic tissue is replaced by disorganized scar tissue, resulting in loss of coordinated contraction. Efforts to re-establish tissue anisotropy in the injured myocardium are hampered by a lack of understanding of how CM and/or cFB structural organization is affected by the two major physical cues inherent in the myocardium: ECM organization and cyclic mechanical strain. Herein, we investigate the singular and combined effect of ECM (dis)organization and cyclic strain in a two-dimensional human in vitro co-culture model of the myocardial microenvironment. We show that (an)isotropic ECM protein patterning can guide the orientation of CMs and cFBs, both in mono- and co-culture. Subsequent application of uniaxial cyclic strain—mimicking the local anisotropic deformation of beating myocardium—causes no effect when applied parallel to the anisotropic ECM. However, when cultured on isotropic substrates, cFBs, but not CMs, orient away from the direction of cyclic uniaxial strain (strain avoidance). In contrast, CMs show strain avoidance via active remodeling of their sarcomeres only when co-cultured with at least 30% cFBs. Paracrine signaling or N-cadherin-mediated communication between CMs and cFBs was no contributing factor. Our findings suggest that the mechanoresponsive cFBs provide structural guidance for CM orientation and elongation. Our study, therefore, highlights a synergistic mechanobiological interplay between CMs and cFBs in shaping tissue organization, which is of relevance for regenerating functionally organized myocardium.

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Versatile electrical stimulator for cardiac tissue engineering—Investigation of charge-balanced monophasic and biphasic electrical stimulations

Gabetti

Sileo²,

Montrone³

et al. 2023

Front. Bioeng. Biotechnol.

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The application of biomimetic physical stimuli replicating the in vivo dynamic microenvironment is crucial for the in vitro development of functional cardiac tissues. In particular, pulsed electrical stimulation (ES) has been shown to improve the functional properties of in vitro cultured cardiomyocytes. However, commercially available electrical stimulators are expensive and cumbersome devices while customized solutions often allow limited parameter tunability, constraining the investigation of different ES protocols. The goal of this study was to develop a versatile compact electrical stimulator (ELETTRA) for biomimetic cardiac tissue engineering approaches, designed for delivering controlled parallelizable ES at a competitive cost. ELETTRA is based on an open-source micro-controller running custom software and is combinable with different cell/tissue culture set-ups, allowing simultaneously testing different ES patterns on multiple samples. In particular, customized culture chambers were appositely designed and manufactured for investigating the influence of monophasic and biphasic pulsed ES on cardiac cell monolayers. Finite element analysis was performed for characterizing the spatial distributions of the electrical field and the current density within the culture chamber. Performance tests confirmed the accuracy, compliance, and reliability of the ES parameters delivered by ELETTRA. Biological tests were performed on neonatal rat cardiac cells, electrically stimulated for 4 days, by comparing, for the first time, the monophasic waveform (electric field = 5 V/cm) to biphasic waveforms by matching either the absolute value of the electric field variation (biphasic ES at ±2.5 V/cm) or the total delivered charge (biphasic ES at ±5 V/cm). Findings suggested that monophasic ES at 5 V/cm and, particularly, charge-balanced biphasic ES at ±5 V/cm were effective in enhancing electrical functionality of stimulated cardiac cells and in promoting synchronous contraction.

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Quantitative Evaluation of Cardiac Cell Interactions and Responses to Cyclic Strain

Cited by 4 publications

References 91 publications

Human pluripotent stem cell-derived cardiomyocytes align under cyclic strain when guided by cardiac fibroblasts

Human pluripotent stem cell-derived cardiomyocytes align under cyclic strain when guided by cardiac fibroblasts

Human pluripotent stem cell-derived cardiomyocytes align under cyclic strain when guided by cardiac fibroblasts

Versatile electrical stimulator for cardiac tissue engineering—Investigation of charge-balanced monophasic and biphasic electrical stimulations

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