scholarly journals Cardiac myocytes respond differentially and synergistically to matrix stiffness and topography

2019 ◽  
Author(s):  
William Wan ◽  
Kristen K. Bjorkman ◽  
Esther S. Choi ◽  
Amanda L. Panepento ◽  
Kristi S. Anseth ◽  
...  
Keyword(s):  
Cell Culture ◽  
Cardiac Myocyte ◽  
Cardiac Tissue ◽  
Cellular Level ◽  
Neonatal Rat ◽  
Substrate Stiffness ◽  
Tissue Stiffness ◽  
Topographical Cues ◽  
Cellular Alignment

AbstractDuring cardiac disease progression, myocytes undergo molecular, functional and structural changes, including increases in cell size and shape, decreased myocyte alignment and contractility. The heart often increases extracellular matrix production and stiffness, which affect myocytes. The order and hierarchy of these events remain unclear as available in vitro cell culture systems do not adequately model both physiologic and pathologic environments. Traditional cell culture substrates are 5-6 orders of magnitude stiffer than even diseased native cardiac tissue. Studies that do account for substrate stiffness often do not consider intercellular alignment and vice versa. We developed a cardiac myocyte culture platform that better recapitulates native tissue stiffness while simultaneously introducing topographical cues that promote cellular alignment. We show that stiffness and topography impact myocyte molecular and functional properties. We used a spatiotemporally-tunable, photolabile hydrogel platform to generate a range of stiffness and micron-scale topographical patterns to guide neonatal rat ventricular myocyte morphology. Importantly, these substrate patterns were of subcellular dimensions to test whether cells would spontaneously respond to topographical cues rather than an imposed geometry. Cellular contractility was highest and the gene expression profile was most physiologic on gels with healthy cardiac tissue stiffness. Surprisingly, while elongated patterns in stiff gels yielded the greatest cellular alignment, the cells actually had more pathologic functional and molecular profiles. These results highlight that morphological measurements alone are not a surrogate for overall cellular health as many studies assume. In general, substrate stiffness and micropatterning synergistically affect cardiac myocyte phenotype to recreate physiologic and pathologic microenvironments.Significance StatementHeart disease is accompanied by organ- and cellular-level remodeling, and deconvoluting their interplay is complex. Cellular-level change is best studied in vitro due to greater control and uniformity of cell types compared to animals. One common metric is degree of cellular alignment as misalignment of myocytes is a hallmark of disease. However, most studies utilize featureless culture surfaces that are orders of magnitude stiffer than, and do not mimic the scaffolding of, the heart. We developed a hydrogel platform with tunable stiffness and patterns providing topographical alignment cues. We cultured heart cells on and characterized multifactorial responses to these dynamic surfaces. Interestingly, conditions that yielded greatest alignment did not yield the healthiest functional and molecular state. Thus, morphology alone is not an indicator of overall cellular health.

scholarly journals Optogenetic currents in myofibroblasts acutely alter electrophysiology and conduction of co-cultured cardiomyocytes

2020 ◽  
Author(s):  
Geran Kostecki ◽  
Yu Shi ◽  
Christopher Chen ◽  
Daniel H. Reich ◽  
Emilia Entcheva ◽  
...  
Keyword(s):  
Cardiac Tissue ◽  
Cardiac Injury ◽  
Neonatal Rat ◽  
Culture Studies ◽  
Electrophysiological Properties ◽  
Inward Currents ◽  
Life Threatening ◽  
Cultured Cardiomyocytes ◽  
Cardiac Myofibroblasts

AbstractInteractions between cardiac myofibroblasts and myocytes may slow conduction after cardiac injury, increasing the chance of life-threatening arrhythmia. While co-culture studies have shown that myofibroblasts can affect cardiomyocyte electrophysiology in vitro, the mechanism(s) remain debatable. In this study, primary neonatal rat cardiac myofibroblasts were transduced with the light-activated ion channel Channelrhodopsin-2, which allowed acute and selective modulation of myofibroblast currents in co-cultures with cardiomyocytes. Optical mapping revealed that myofibroblast-specific optogenetically induced inward currents decreased conduction velocity in the co-cultures by 27±6% (baseline = 17.7±5.3 cm/s), and shortened the cardiac action potential duration by 14±7% (baseline = 161±11 ms) when 0.017 mW/mm2 light was applied. When light irradiance was increased to 0.057 mW/mm2, the myofibroblast currents led to spontaneous beating in 6/7 co-cultures. Experiments showed that optogenetic perturbation did not lead to changes in myofibroblast strain and force generation, suggesting purely electrical effects in this model. In silico modeling of optogenetically modified myofibroblast-cardiomyocyte co-cultures largely reproduced these results and enabled a comprehensive study of relevant parameters. These results clearly demonstrate that myofibroblasts are sufficiently electrically connected to cardiomyocytes to effectively alter macroscopic electrophysiological properties in this model of cardiac tissue.

scholarly journals Isolation, Characterization, and Agent-Based Modeling of Mesenchymal Stem Cells in a Bio-construct for Myocardial Regeneration Scaffold Design

Data ◽  
2019 ◽  
Vol 4 (2) ◽  
pp. 71 ◽  
Author(s):  
Diana Victoria Ramírez López ◽  
María Isabel Melo Escobar ◽  
Carlos A. Peña-Reyes ◽  
Álvaro J. Rojas Arciniegas ◽  
Paola Andrea Neuta Arciniegas
Keyword(s):  
Stem Cells ◽  
Mesenchymal Stem Cells ◽  
In Silico ◽  
Cardiac Tissue ◽  
Cellular Level ◽  
Cell Behavior ◽  
Agent Based Model ◽  
Agent Based ◽  
And Migration

Regenerative medicine involves methods to control and modify normal tissue repair processes. Polymer and cell constructs are under research to create tissue that replaces the affected area in cardiac tissue after myocardial infarction (MI). The aim of the present study is to evaluate the behavior of differentiated and undifferentiated mesenchymal stem cells (MSCs) in vitro and in silico and to compare the results that both offer when it comes to the design process of biodevices for the treatment of infarcted myocardium in biomodels. To assess in vitro behavior, MSCs are isolated from rat bone marrow and seeded undifferentiated and differentiated in multiple scaffolds of a gelled biomaterial. Subsequently, cell behavior is evaluated by trypan blue and fluorescence microscopy, which showed that the cells presented high viability and low cell migration in the biomaterial. An agent-based model intended to reproduce as closely as possible the behavior of individual MSCs by simulating cellular-level processes was developed, where the in vitro results are used to identify parameters in the agent-based model that is developed, and which simulates cellular-level processes: Apoptosis, differentiation, proliferation, and migration. Thanks to the results obtained, suggestions for good results in the design and fabrication of the proposed scaffolds and how an agent-based model can be helpful for testing hypothesis are presented in the discussion. It is concluded that assessment of cell behavior through the observation of viability, proliferation, migration, inflammation reduction, and spatial composition in vitro and in silico, represents an appropriate strategy for scaffold engineering.

scholarly journals Membranes for Modelling Cardiac Tissue Stiffness In Vitro Based on Poly(trimethylene carbonate) and Poly(ethylene glycol) Polymers

Membranes ◽  
2020 ◽  
Vol 10 (10) ◽  
pp. 274 ◽  
Author(s):  
Iris Allijn ◽  
Marcelo Ribeiro ◽  
André Poot ◽  
Robert Passier ◽  
Dimitrios Stamatialis
Keyword(s):  
Ethylene Glycol ◽  
Human Heart ◽  
Cardiac Tissue ◽  
Heart Tissue ◽  
Trimethylene Carbonate ◽  
Tissue Stiffness ◽  
Poly Ethylene Glycol ◽  
Young’S Moduli ◽  
Poly Ethylene

Despite the increased expenditure of the pharmaceutical industry on research and development, the number of drugs for cardiovascular diseases that reaches the market is decreasing. A major issue is the limited ability of the current in vitro and experimental animal models to accurately mimic human heart disease, which hampers testing of the efficacy of potential cardiac drugs. Moreover, many non-heart-related drugs have severe adverse cardiac effects, which is a major cause of drugs’ retraction after approval. A main hurdle of current in vitro models is their inability to mimic the stiffness of in vivo cardiac tissue. For instance, poly(styrene) petri dishes, which are often used in these models, have a Young’s modulus in the order of GPa, while the stiffness of healthy human heart tissue is <50 kPa. In pathological conditions, such as scarring and fibrosis, the stiffness of heart tissue is in the >100 kPa range. In this study, we focus on developing new membranes, with a set of properties for mimicry of cardiac tissue stiffness in vitro, based on methacrylate-functionalized macromers and triblock-copolymers of poly(trimethylene carbonate) and poly(ethylene glycol). The new membranes have Young’s moduli in the hydrated state ranging from 18 kPa (healthy tissue) to 2.5 MPa (pathological tissue), and are suitable for cell contraction studies using human pluripotent stem-cell-derived cardiomyocytes. The membranes with higher hydrophilicity have low drug adsorption and low Young’s moduli and could be suitable for drug screening applications.

Coverslip hypoxia: a novel method for studying cardiac myocyte hypoxia and ischemia in vitro

2004 ◽  
Vol 287 (4) ◽  
pp. H1801-H1812 ◽  
Author(s):  
Kelly R. Pitts ◽  
Christopher F. Toombs
Keyword(s):  
Metabolic Activity ◽  
Cardiac Myocyte ◽  
Experimental Models ◽  
Membrane Dynamics ◽  
Neonatal Rat ◽  
Simple Method ◽  
Glass Coverslip ◽  
Media Volume

In vitro experimental models designed to study the effects of hypoxia and ischemia typically employ oxygen-depleted media and/or hypoxic chambers. These approaches, however, allow for metabolites to diffuse away into a large volume and may not replicate the high local concentrations that occur in ischemic myocardium in vivo. We describe herein a novel and simple method for creating regional hypoxic and ischemic conditions in neonatal rat cardiac myocyte monolayers. This method consists of creating a localized diffusion barrier by placing a glass coverslip over a portion of the monolayer. The coverslip restricts covered myocytes to a thin film of media while leaving uncovered myocytes free to access the surrounding bulk media volume. Myocytes under the coverslip undergo marked morphology changes over time as assessed by video microscopy. Fluorescence microscopy shows that these changes are accompanied by alterations in mitochondrial membrane potential and plasma membrane dynamics and eventually result in myocyte death. We also show that the metabolic activity of myocytes drives cell necrosis under the coverslip. In addition, the intracellular pH of synchronously contracting myocytes under the coverslip drops rapidly, which further implicates metabolic activity in regulating cell death under the coverslip. In contrast with existing models of hypoxia/ischemia, this technique provides a simple and effective way to create hypoxic/ischemic conditions in vitro. Moreover, we conclude that myocyte death is hastened by the combination of hypoxia, metabolites, and acidosis and is facilitated by a reduction in media volume, which may better represent ischemic conditions in vivo.

scholarly journals In Vitro Bioactivity and Biocompatibility of Bio-Inspired Ti-6Al-4V Alloy Surfaces Modified by Combined Laser Micro/Nano Structuring

Molecules ◽  
2020 ◽  
Vol 25 (7) ◽  
pp. 1494
Author(s):  
Chen Li ◽  
Yong Yang ◽  
Lijun Yang ◽  
Zhen Shi ◽  
Pengfei Yang ◽  
...  
Keyword(s):  
Titanium Alloy ◽  
Osteoblastic Cell ◽  
Tree Frog ◽  
Direct Writing ◽  
Multi Scale ◽  
Nano Structures ◽  
Surface Microstructures ◽  
Topographical Cues ◽  
Cellular Alignment

The bioactivity and biocompatibility play key roles in the success of dental and orthopaedic implants. Although most commercial implant systems use various surface microstructures, the ideal multi-scale topographies capable of controlling osteointegration have not yielded conclusive results. Inspired by both the isotropic adhesion of the skin structures in tree frog toe pads and the anisotropic adhesion of the corrugated ridges on the scales of Morpho butterfly wings, composite micro/nano-structures, including the array of micro-hexagons and oriented nano-ripples on titanium alloy implants, were respectively fabricated by microsecond laser direct writing and femtosecond laser-induced periodic surface structures, to improve cell adherence, alignment and proliferation on implants. The main differences in both the bioactivity in simulated body fluid and the biocompatibility in osteoblastic cell MC3T3 proliferation were measured and analyzed among Ti-6Al-4V samples with smooth surface, micro-hexagons and composite micro/nano-structures, respectively. Of note, bioinspired micro/nano-structures displayed the best bioactivity and biocompatibility after in vitro experiments, and meanwhile, the nano-ripples were able to induce cellular alignment within the micro-hexagons. The reasons for these differences were found in the topographical cues. An innovative functionalization strategy of controlling the osteointegration on titanium alloy implants is proposed using the composite micro/nano-structures, which is meaningful in various regenerative medicine applications and implant fields.

Abstract 1349: Overexpression And Dominant-negative Suppression Of Inwardly Rectifying Potassium Channel Protein (Kir2.1) Alters Electrophysiology And Spiral Wave Dynamics Of An In Vitro Model Of Cardiac Myocytes

Circulation ◽  
2007 ◽  
Vol 116 (suppl_16) ◽  
Author(s):  
Rajesh B Sekar ◽  
Eddy Kizana ◽  
Hee C Cho ◽  
Rachel R Smith ◽  
Brett P Eaton ◽  
...  
Keyword(s):  
Cardiac Tissue ◽  
Spiral Waves ◽  
Dominant Negative ◽  
Neonatal Rat ◽  
Resting Potential ◽  
Dominant Negative Mutant ◽  
Rapid Pacing ◽  
The Stability ◽  
Inwardly Rectifying

Introduction : An important role for the inwardly rectifying potassium current (I K1 ) has been postulated in controlling the stability and frequency of rotors responsible for ventricular tachycardia and fibrillation. We investigated the effects of Kir2.1 overexpression and Kir2.1AAA dominant-negative mutant suppression on the electrophysiology and inducibility, stability and frequency of spiral waves in an in vitro cardiac tissue model. Methods/Results : Neonatal rat ventricular myocytes (NRVMs) were transduced by lentiviral vectors encoding Kir2.1 or Kir2.1AAA. Immunostaining revealed Kir2.1 or mutant Kir2.1 protein overexpression and whole cell-clamp confirmed the predicted effects on I K1 , resting potential, and action potential duration (APD 80 ). Optical mapping was performed on confluent NRVM monolayers containing a 5 mm diameter central island of gene-modified NRVMs created by a stenciling technique. APs propagated with increased CV (25.1±2.7 cm/sec, n=7) and shortened APD 80 (73±11 msec, n=7) in islands of Kir2.1 overexpression, or decreased CV (13.1±1.1 cm/sec, n=7) and prolonged APD 80 (263±14 msec, n=7) in islands of Kir2.1AAA suppression, compared with normal CV and APD 80 of 19.2±0.4 cm/sec and 169±14 msec (n=7) in non-transduced islands. Reentry was initiated by rapid pacing. With Kir2.1 overexpression, reentrant waves anchored to the island and remained stable (89±15 minutes, n=3) with a frequency of 8±2 Hz. Superfusion with 0.5 mM BaCl 2 to block I K1 slowed reentry to 1 Hz and terminated it shortly after initiation. NRVM monolayers with islands of Kir2.1AAA suppression (n=3) displayed rapid spontaneous activity. Rapid pacing of these monolayers initiated an unstable figure-of-eight reentry (n=3) that degraded into single and multi-armed spiral waves, anchored to varying parts of the island with a maximum frequency of 2±1 Hz. Importantly, no reentry could be initiated in monolayers with non-transduced islands (n=3). Conclusion : Functional reentrant waves induced by rapid pacing are anchored to islands of localized Kir2.1 overexpression whereas they drop in frequency and meander in islands of dominant-negative suppression of Kir2.1, confirming the importance of I K1 for the stability of these waves in cardiac tissue.

scholarly journals Contractility of single cardiomyocytes differentiated from pluripotent stem cells depends on physiological shape and substrate stiffness

2015 ◽  
Vol 112 (41) ◽  
pp. 12705-12710 ◽  
Author(s):  
Alexandre J. S. Ribeiro ◽  
Yen-Sin Ang ◽  
Ji-Dong Fu ◽  
Renee N. Rivas ◽  
Tamer M. A. Mohamed ◽  
...  
Keyword(s):  
Stem Cells ◽  
Pluripotent Stem Cells ◽  
Contractile Activity ◽  
Cellular Level ◽  
Substrate Stiffness ◽  
Tubule Formation ◽  
Aspect Ratios ◽  
Mitochondrial Distribution ◽  
Vitro Model

Single cardiomyocytes contain myofibrils that harbor the sarcomere-based contractile machinery of the myocardium. Cardiomyocytes differentiated from human pluripotent stem cells (hPSC-CMs) have potential as an in vitro model of heart activity. However, their fetal-like misalignment of myofibrils limits their usefulness for modeling contractile activity. We analyzed the effects of cell shape and substrate stiffness on the shortening and movement of labeled sarcomeres and the translation of sarcomere activity to mechanical output (contractility) in live engineered hPSC-CMs. Single hPSC-CMs were cultured on polyacrylamide substrates of physiological stiffness (10 kPa), and Matrigel micropatterns were used to generate physiological shapes (2,000-µm2 rectangles with length:width aspect ratios of 5:1–7:1) and a mature alignment of myofibrils. Translation of sarcomere shortening to mechanical output was highest in 7:1 hPSC-CMs. Increased substrate stiffness and applied overstretch induced myofibril defects in 7:1 hPSC-CMs and decreased mechanical output. Inhibitors of nonmuscle myosin activity repressed the assembly of myofibrils, showing that subcellular tension drives the improved contractile activity in these engineered hPSC-CMs. Other factors associated with improved contractility were axially directed calcium flow, systematic mitochondrial distribution, more mature electrophysiology, and evidence of transverse-tubule formation. These findings support the potential of these engineered hPSC-CMs as powerful models for studying myocardial contractility at the cellular level.

Abstract 262: Depolarization Stimulates Neonatal Cardiomyocyte Proliferation In Vitro

2012 ◽  
Vol 111 (suppl_1) ◽  
Author(s):  
Corin Williams ◽  
Michael Levin ◽  
Lauren D Black
Keyword(s):  
Cardiac Tissue ◽  
Heart Defects ◽  
Cell Types ◽  
Cardiac Cells ◽  
Neonatal Rat ◽  
Resting Membrane Potential ◽  
Cardiomyocyte Proliferation ◽  
Potassium Gluconate ◽  
Hypertrophic Growth

Cardiac tissue engineering is a promising approach for treating children with congenital heart defects. However, as cardiomyocytes (CMs) undergo a rapid transition from hyperplastic to hypertrophic growth after birth, a major challenge to the development of engineered cardiac tissue is the limited proliferation of CMs. Mature CMs and other terminally differentiated cell types tend to have a highly negative resting membrane potential (Vmem) while stem cells and less mature cells tend to have Vmem closer to zero. Vmem has been shown to play an important role in cell differentiation and proliferation. We hypothesized that depolarization of cardiac cells would stimulate CM proliferation in vitro . To test our hypothesis, we isolated neonatal rat cardiac cells and cultured them for 24 hr under standard conditions. Cells were then subjected to depolarization treatment for 72 hr using potassium gluconate or ouabain at various concentrations. Samples were fixed and stained for cardiac α-actin (Fig 1A, red) and phospho-histone H3 (Fig 1A, green) to assess CM mitosis. We found that potassium gluconate had no significant effect while ouabain significantly increased CM mitosis, suggesting Vmem regulation via Na/K-ATPase. CM-specific proliferation was significantly higher with 10nM (p= 0.015) and 100nM (p=0.008) ouabain treatment compared to controls (n=3) (Fig 1B). Cell density was significantly higher with 100μM ouabain versus controls (2656 ± 50 vs. 2026 ± 117 cells/mm 2 ), indicating increased cardiac cell proliferation (Fig 1C). Our findings suggest that depolarization promotes CM proliferation and may be a novel approach to encourage growth of engineered cardiac tissue in vitro .

Cardiotrophin-1 displays early expression in the murine heart tube and promotes cardiac myocyte survival

Development ◽  
1996 ◽  
Vol 122 (2) ◽  
pp. 419-428 ◽  
Author(s):  
Z. Sheng ◽  
D. Pennica ◽  
W.I. Wood ◽  
K.R. Chien
Keyword(s):  
Cardiac Myocyte ◽  
Embryonic Stem ◽  
Neuronal Cell ◽  
Fold Increase ◽  
Cell System ◽  
Neonatal Rat ◽  
Heart Tube ◽  
Related Family ◽  
Early Expression

We have recently isolated a novel cytokine, cardiotrophin-1 (CT-1), from an in vitro embryonic stem cell system of cardiogenesis that can activate embryonic markers in neonatal rat cardiac myocytes. CT-1 is a new member of the interleukin 6 (IL-6)/leukemia inhibitory factor (LIF) cytokines, which activate downstream signals via gp130-dependent pathways. To define the developmental pattern of expression of CT-1 during murine embryogenesis, we have developed antibodies directed against a CT-1 fusion protein. As assessed by immunolocalization, CT-1 is predominantly expressed in the early mouse embryonic heart tube (E8.5-10.5). In the heart, CT-1 is primarily expressed in myocardial cells, and not in endocardial cushion or outflow tract tissues. After E12.5, CT-1 expression is found in other tissues, including skeletal, liver and dorsal root ganglia. Given the effects of a related family member (ciliary neurotrophic factor, CNTF) on neuronal cell survival, we studied the ability of CT-1 to promote cardiac myocyte survival and proliferation in vitro. Both CT-1 and LIF, which share the same receptors, dramatically promote neonatal cardiac myocyte survival, while IL-6 and CNTF are without effect. A cell proliferation assay documents that CT-1 provokes an approximate 2-fold increase in embryonic cardiac myocyte proliferation. Thus, CT-1 may play an autocrine role during cardiac chamber growth and morphogenesis by promoting the survival and proliferation of immature myocytes, most likely via gp130-dependent signaling pathways.

scholarly journals Pre-Conditioning with CDP-Choline Attenuates Oxidative Stress-Induced Cardiac Myocyte Death in a Hypoxia/Reperfusion Model

2014 ◽  
Vol 2014 ◽  
pp. 1-8 ◽  
Author(s):  
Héctor González-Pacheco ◽  
Aurelio Méndez-Domínguez ◽  
Salomón Hernández ◽  
Rebeca López-Marure ◽  
Maria J. Vazquez-Mellado ◽  
...  
Keyword(s):  
Oxidative Stress ◽  
Reperfusion Injury ◽  
Cardiac Myocytes ◽  
Cardiac Myocyte ◽  
Cell Signalling ◽  
Annexin V ◽  
Neonatal Rat ◽  
Ischaemia Reperfusion Injury ◽  
Ischaemia Reperfusion

Background. CDP-choline is a key intermediate in the biosynthesis of phosphatidylcholine, which is an essential component of cellular membranes, and a cell signalling mediator. CDP-choline has been used for the treatment of cerebral ischaemia, showing beneficial effects. However, its potential benefit for the treatment of myocardial ischaemia has not been explored yet.Aim. In the present work, we aimed to evaluate the potential use of CDP-choline as a cardioprotector in anin vitromodel of ischaemia/reperfusion injury.Methods. Neonatal rat cardiac myocytes were isolated and subjected to hypoxia/reperfusion using the coverslip hypoxia model. To evaluate the effect of CDP-choline on oxidative stress-induced reperfusion injury, the cells were incubated with H2O2during reperfusion. The effect of CDP-choline pre- and postconditioning was evaluated using the cell viability MTT assay, and the proportion of apoptotic and necrotic cells was analyzed using the Annexin V determination by flow cytometry.Results. Pre- and postconditioning with 50 mg/mL of CDP-choline induced a significant reduction of cells undergoing apoptosis after hypoxia/reperfusion. Preconditioning with CDP-choline attenuated postreperfusion cell death induced by oxidative stress.Conclusion. CDP-choline administration reduces cell apoptosis induced by oxidative stress after hypoxia/reperfusion of cardiac myocytes. Thus, it has a potential as cardioprotector in ischaemia/reperfusion-injured cardiomyocytes.

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