Human Cardiac Ventricular‐Like Organoid Chambers and Tissue Strips From Pluripotent Stem Cells as a Two‐Tiered Assay for Inotropic Responses

Keung, Wendy; Chan, Phyllis; Backeris, Peter; Lee, Eugene K.; Wong, Nicodemus; Wong, Andy On Tik; Wong, G.C.; Chan, Chun Man; Fermini, Bernard; Costa, Kevin D.; Tse, Gary

doi:10.1002/cpt.1385

Cited by 36 publications

(51 citation statements)

References 52 publications

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“…The dyn-EHT platform builds off of previous work from our laboratory and other investigators that have used primary, hESC and hiPSC derived cardiomyocytes to engineer functional cardiac tissues in vitro. Indeed, it is critical to acknowledge the important contributions to the field made by researchers using EHTs to model development and disease, and implementing more physiologic-like electromechanical conditioning to drive maturation (14,(16)(17)20,23,(25)(26)28,40,(61)(62)(63)(64). However, these 2D and 3D EHTs are generally isometrically constrained, which means they are unable to undergo significant fractional shortening or be stretched by preload.…”

Section: Discussionmentioning

confidence: 99%

“…Further, strategies aimed at reducing the ventricular wall stress by integrating a temporary patch over the myocardial infarct (58) or injecting materials to thicken the ventricle wall (59) have proved successful to combat the pathological remodeling observed following myocardial infarction. While there have been recent advances in engineering ventricle-like chambers using scaffolds and 3D bioprinting (22,(60)(61)(62), compared to our dyn-EHT these chambers are much more difficult to fabricate, require a relatively large number of cells to form, and must be connected to a complicated flow system with valves and pressure transducers in order to generate preload.…”

Section: Discussionmentioning

confidence: 99%

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Dynamic Loading of Human Engineered Heart Tissue Enhances Contractile Function and Drives Desmosome-linked Disease Phenotype

Bliley

Vermeer

Duffy

et al. 2020

Preprint

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The role mechanical forces play in shaping the structure and function of the heart is critical to understanding heart formation and the etiology of disease but is challenging to study in patients. Engineered heart tissues (EHTs) incorporating human induced pluripotent stem cell (hiPSC)-derived cardiomyocytes have the potential to provide insight into these adaptive and maladaptive changes in the heart. However, most EHT systems are unable to model both preload (stretch during chamber filling) and afterload (pressure the heart must work against to eject blood). Here, we have developed a new dynamic EHT (dyn-EHT) model that enables us to tune preload and have unconstrained fractional shortening of >10%.To do this, 3D EHTs are integrated with an elastic polydimethylsiloxane (PDMS) strip that provides mechanical pre-and afterload to the tissue in addition to enabling contractile force measurements based on strip bending. Our results demonstrate in wild-type EHTs that dynamic loading is beneficial based on the magnitude of the forces, leading to improved alignment, conduction velocity, and contractility. For disease modeling, we use hiPSC-derived cardiomyocytes from a patient with arrhythmogenic cardiomyopathy (ACM) due to mutations in desmoplakin. We demonstrate that manifestation of this desmosome-linked disease state requires the dyn-EHT conditioning and that it cannot be induced using 2D or standard 3D EHT approaches. Thus, dynamic loading strategy is necessary to provoke a disease phenotype (diastolic lengthening, reduction of desmosome counts, and reduced contractility), which are akin to primary endpoints of clinical disease, such as chamber thinning and reduced cardiac output.Studying the effects of mechanical loading on adaptive and maladaptive changes in heart structure and function is challenging in human patients, driving the need to develop new approaches. Animals have been used to model a wide range of human cardiovascular disease states, but there are inherent differences in physiology, gene expression and pharmacokinetics that limit the ability to replicate complex pathology (6). In vitro 2-dimensional (2D) culture of cardiomyocytes on microengineered surfaces have been used to study structure-function relationships and to create region-specific ventricular myocardium (7,8) Muscular thin films (MTFs), consisting of cells cultured on a flexible film, have enabled these 2D platforms to measure contractility (9,10), and combined with patient-specific human induced pluripotent stem cell (hiPSC)-derived cardiomyocytes can model cardiomyopathies such as Barth's syndrome (11). However, 2D cardiomyocytes are adhered to a surface (12) and thus do not have the same mechanical cell-cell coupling as found in the native heart (13). To address this, researchers have developed more physiologically-relevant 3D engineered heart tissues (EHTs) in the form papillary muscle-like linear bundles (14-18) myocardium-like sheets (19,20), and ventricle-like chambers (21,22). Incorporating human induced pluripotent stem cell (hi...

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Dynamic Loading of Human Engineered Heart Tissue Enhances Contractile Function and Drives Desmosome-linked Disease Phenotype

Bliley

Vermeer

Duffy

et al. 2020

Preprint

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“…The simpler form is cardiac organoid, which involves self-aggregation of hiPSC-CMs and or other cell types into spherical organoids in 3D with cellular organization comparable to native heart tissue and which can assess parameters such as cell viability and cytotoxicity (Polonchuk et al, 2017). A more sophisticated type of 3D tissue is engineered cardiac tissue which involves tight control of cellular organization with specific scaffold materials and cell density (Mannhardt et al, 2017a;Keung et al, 2019). The improved alignment of these engineered tissue constructs yields more mature cells and more physiologically relevant functional assessment capabilities that can be adapted to high throughput and high content assays, including true twitch forces, pressure-volume relationships, stroke work and macroelectrophysiological parameters (Mannhardt et al, 2017b;Li et al, 2018;Keung et al, 2019).…”

Section: Hipsc Based Models For Studying Cardiotoxicitymentioning

confidence: 99%

“…A more sophisticated type of 3D tissue is engineered cardiac tissue which involves tight control of cellular organization with specific scaffold materials and cell density (Mannhardt et al, 2017a;Keung et al, 2019). The improved alignment of these engineered tissue constructs yields more mature cells and more physiologically relevant functional assessment capabilities that can be adapted to high throughput and high content assays, including true twitch forces, pressure-volume relationships, stroke work and macroelectrophysiological parameters (Mannhardt et al, 2017b;Li et al, 2018;Keung et al, 2019). For example, in a recent study using a form of 3D microtissue to model cardiotoxicity, the authors were able to demonstrate an increase in afterload on cardiomyocytes with increased sunitinibinduced cardiotoxicity, highlighting the superiority of 3D models to assess more complex physiological parameters which are not feasible with 2D culture models (Truitt et al, 2018).…”

Section: Hipsc Based Models For Studying Cardiotoxicitymentioning

confidence: 99%

Human Pluripotent Stem Cells for Modeling of Anticancer Therapy-Induced Cardiotoxicity and Cardioprotective Drug Discovery

Keung

Cheung

2021

Front. Pharmacol.

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Anticancer chemotherapies have been shown to produce severe side effects, with cardiotoxicity from anthracycline being the most notable. Identifying risk factors for anticancer therapy-induced cardiotoxicity in cancer patients as well as understanding its underlying mechanism is essential to improving clinical outcomes of chemotherapy treatment regimens. Moreover, cardioprotective agents against anticancer therapy-induced cardiotoxicity are scarce. Human induced pluripotent stem cell technology offers an attractive platform for validation of potential single nucleotide polymorphism with increased risk for cardiotoxicity. Successful validation of risk factors and mechanism of cardiotoxicity would aid the development of such platform for novel drug discovery and facilitate the practice of personalized medicine.

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“…Fluid-ejecting 3D human ventricular-like cardiac organoid chambers (hvCOC) can mimic physiologically complex behaviors, such as pressure-volume relationships, and have been used for detecting contractile responses to different pharmacological compounds[127,128]. The hvCOC system can accurately identify inotropic effects of pharmacological compounds such as isoproterenol and levosimendan, with increased sensitivity with respect to human ventricular-like cardiac tissues strips.…”

Section: Cardiotoxicitymentioning

confidence: 99%

Induced pluripotent stem cells for therapy personalization in pediatric patients: Focus on drug-induced adverse events

Genova¹,

Cavion²,

Lucafò³

et al. 2019

WJSC

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Adverse drug reactions (ADRs) are major clinical problems, particularly in special populations such as pediatric patients. Indeed, ADRs may be caused by a plethora of different drugs leading, in some cases, to hospitalization, disability or even death. In addition, pediatric patients may respond differently to drugs with respect to adults and may be prone to developing different kinds of ADRs, leading, in some cases, to more severe consequences. To improve the comprehension, and thus the prevention, of ADRs, the set-up of sensitive and personalized assays is urgently needed. Important progress is represented by the possibility of setting up groundbreaking patient-specific assays. This goal has been powerfully achieved using induced pluripotent stem cells (iPSCs). Due to their genetic and physiological species-specific differences and their ability to be differentiated ideally into all tissues of the human body, this model may be accurate in predicting drug toxicity, especially when this toxicity is related to individual genetic differences. This review is an up-to-date summary of the employment of iPSCs as a model to study ADRs, with particular attention to drugs used in the pediatric field. We especially focused on the intestinal, hepatic, pancreatic, renal, cardiac, and neuronal levels, also discussing progress in organoids creation. The latter are three-dimensional in vitro culture systems derived from pluripotent or adult stem cells simulating the architecture and functionality of native organs such as the intestine, liver, pancreas, kidney, heart, and brain. Based on the existing knowledge, these models are powerful and promising tools in multiple clinical applications including toxicity screening, disease modeling, personalized and regenerative medicine.

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Human Cardiac Ventricular‐Like Organoid Chambers and Tissue Strips From Pluripotent Stem Cells as a Two‐Tiered Assay for Inotropic Responses

Cited by 36 publications

References 52 publications

Dynamic Loading of Human Engineered Heart Tissue Enhances Contractile Function and Drives Desmosome-linked Disease Phenotype

Dynamic Loading of Human Engineered Heart Tissue Enhances Contractile Function and Drives Desmosome-linked Disease Phenotype

Human Pluripotent Stem Cells for Modeling of Anticancer Therapy-Induced Cardiotoxicity and Cardioprotective Drug Discovery

Induced pluripotent stem cells for therapy personalization in pediatric patients: Focus on drug-induced adverse events

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