Metabolic Maturation Media Improve Physiological Function of Human iPSC-Derived Cardiomyocytes

Feyen, Dries; McKeithan, Wesley L.; Bruyneel, Arne A.N.; Spiering, Sean; Hörmann, Larissa; Ulmer, Bärbel; Zhang, Hui; Briganti, Francesca; Schweizer, Michaela; Hegyi, Bence; Liao, Zhandi; Pölönen, Risto-Pekka; Ginsburg, Kenneth S.; Lam, Chi Keung; Serrano, Ricardo; Wahlquist, Christine; Kreymerman, Alexander; Vu, Michelle M.; Amatya, Prashila; Behrens, Charlotta Sophie; Ranjbarvaziri, Sara; Maas, Renée G C; Greenhaw, Matthew; Bernstein, Daniel; Wu, Joseph C.; Bers, Donald M.; Eschenhagen, Thomas; Metallo, Christian M.; Mercola, Mark

doi:10.1016/j.celrep.2020.107925

Cited by 224 publications

(271 citation statements)

References 61 publications

(69 reference statements)

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“…Altogether, these experimental results are consistent with the prediction of the simulations that pre-treatment with MM increases the SR Ca 2+ store, and its contribution to the cytosolic Ca 2+ transient that fuels contraction. These results are internally consistent with the results of our simulations, and with previous work where matured hiPSC-CM exhibited a more marked calcium decay time in response to thapsigargin 36 . In previous studies, maturation media containing dexamethasone and triiodothyronine 66 , and maturation induced by continuous field pacing 23 have been linked to improvements in hiPSC-CM Ca 2+ handling through formation of T-tubules.…”

Section: Mathematical Modeling Of the Ion Channel And Calcium Transiesupporting

confidence: 93%

“…Strikingly, this media had opposing effects on the action potential duration of genetically unique hiPSCderived tissue chips, with the net result of forcing both genotypes towards an actional potential duration range that is typical for adult human ventricular cardiomyocytes. These results suggest that, as in monolayer culture of hiPSC-CM 36 , maturation with fatty-acid based media may be a prerequisite to using hiPSC-CM based tissue chips to predict how drugs will affect the adult human heart.…”

Section: Resultsmentioning

confidence: 98%

“…Postnatally, the heart switches from glycolysis to fatty-acid oxidation as its primary source of ATP 31,32 . Previously, 2D hiPSC-CM monolayers and engineered tissues exposed to glucose-depleted, fatty-acid enriched media exhibited more mature metabolic profiles and physiology compared to hiPSC-CM cultured in standard media [33][34][35][36] . However, fattyacid based media has not been studied in the context of MPS, and potential population variance in cellular response to fatty-acid media has not been explored.…”

Section: Introductionmentioning

confidence: 99%

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Metabolically-Driven Maturation of hiPSC-Cell Derived Cardiac Chip

Huebsch

Charrez

Siemons

et al. 2018

Preprint

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Human induced pluripotent stem cell derived cardiomyocytes (hiPSC-CM) are a promising in vitro tool for drug development and disease modeling, but their immature electrophysiology limits their diagnostic utility. Tissue engineering approaches involving aligned and 3D culture enhance hiPSC-CM maturation but are insufficient to induce electrophysiological maturation. We hypothesized that recapitulating postnatal switching of the heart's primary adenosine triphosphate source from glycolysis to fatty acid oxidation could enhance maturation of hiPSC-CM. We combined hiPSC-CM with microfabrication to create 3D cardiac microphysiological systems (MPS) that enhanced immediate microtissue alignment and tissue specific extracellular matrix production. Using Robust Experimental design, we identified a maturation media that allowed the cardiac MPS to correctly assess false positive and negative drug response. Finally, we employed mathematical modeling and gene expression data to explain the observed changes in electrophysiology and pharmacology of MPS exposed to maturation media. In contrast, the same media had no effects on 2D hiPSC-CM monolayers. These results suggest that systematic combination of biophysical stimuli and metabolic cues can enhance the electrophysiological maturation of hiPSCderived cardiomyocytes. Results and Discussion Robust Design Experiments Indicate Optimal Carbon Sourcing for Mature Beating PhysiologyWe have developed a microfabricated cardiac MPS, employing hiPSC-CM, for drug testing (Mathur et al. 2015). In the present study, we formed cardiac MPS that that mimicked the mass composition of the human heart by combining 80% hiPSC-CM and 20% hiPSC-SC (Supplemental Methods, Fig. S1-2). We employed Robust Experimental Design to screen for the effects of glucose, oleic acid, palmitic acid, and albumin (bovine serum albumin, BSA) levels on hiPSC-CM maturity ( Table 1). MPS were incubated with different fatty-acid media for ten days, at which time their beating physiology and calcium flux were assessed. Optimal media would reduce automaticity (e.g. reduce spontaneous beating rate), while also reducing the interval between peak contraction and peak relaxation (a surrogate for APD) in field-paced tissues (Fig. 1A-C), while maintaining a high level of beating prevalence during pacing (defined as the percent of the tissue with substantial contractile motion; Fig. 1D). In general, beating prevalence was consistent with calcium flux amplitude (Fig. 1D,F), and beating interval correlated with rate-corrected Full-Width Half Maximum calcium flux time, FWHMc; Fig. 1B,E).

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Section: Mathematical Modeling Of the Ion Channel And Calcium Transiesupporting

confidence: 93%

Section: Resultsmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Metabolically-Driven Maturation of hiPSC-Cell Derived Cardiac Chip

Huebsch

Charrez

Siemons

et al. 2018

Preprint

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“…It was shown that high glucose concentrations can reduce mitochondrial function [ 16 ], while excluding glucose from the medium favors the metabolic switch to mitochondrial oxidative phosphorylation [ 13 , 17 ]. Also, Feyen and collaborators demonstrated that the inclusion of oxidative substrates to the culture medium of iPSCs-CM produce metabolically mature CMs, improving electrophysiological and mechanical parameters [ 18 ].…”

Section: Resultsmentioning

confidence: 99%

Reorganization of Metabolism during Cardiomyogenesis Implies Time-Specific Signaling Pathway Regulation

Barisón

Pereira

Robert

et al. 2021

IJMS

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Understanding the cell differentiation process involves the characterization of signaling and regulatory pathways. The coordinated action involved in multilevel regulation determines the commitment of stem cells and their differentiation into a specific cell lineage. Cellular metabolism plays a relevant role in modulating the expression of genes, which act as sensors of the extra-and intracellular environment. In this work, we analyzed mRNAs associated with polysomes by focusing on the expression profile of metabolism-related genes during the cardiac differentiation of human embryonic stem cells (hESCs). We compared different time points during cardiac differentiation (pluripotency, embryoid body aggregation, cardiac mesoderm, cardiac progenitor and cardiomyocyte) and showed the immature cell profile of energy metabolism. Highly regulated canonical pathways are thoroughly discussed, such as those involved in metabolic signaling and lipid homeostasis. We reveal the critical relevance of retinoic X receptor (RXR) heterodimers in upstream retinoic acid metabolism and their relationship with thyroid hormone signaling. Additionally, we highlight the importance of lipid homeostasis and extracellular matrix component biosynthesis during cardiomyogenesis, providing new insights into how hESCs reorganize their metabolism during in vitro cardiac differentiation.

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“…Unlike adult cardiomyocytes, neonatal or iPSC cardiomyocytes do not show rectangular morphology, exhibit spontaneous generation of AP, have lower density of mitochondria and higher dependence on glycolytic metabolism over fatty acid oxidation. Several recently developed techniques help iPSC-CM maturation through metabolic supplementation ( Parikh et al, 2017 ; Feyen et al, 2020 ), incremental pacing ( Chan et al, 2013 ) and culture substrate modifications to promote higher contraction forces ( Pandey et al, 2018 ). Currently, these culture procedures from somatic reprogramming to obtaining functionally mature iPSC-CMs require over a month’s time, which may limit their use for point-of-care testing.…”

Section: Addressing Functional and Cellular Heterogeneity In Cardiomymentioning

confidence: 99%

Building Multi-Dimensional Induced Pluripotent Stem Cells-Based Model Platforms to Assess Cardiotoxicity in Cancer Therapies

2021

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Cardiovascular disease (CVD) complications have contributed significantly toward poor survival of cancer patients worldwide. These complications that result in myocardial and vascular damage lead to long-term multisystemic disorders. In some patient cohorts, the progression from acute to symptomatic CVD state may be accelerated due to exacerbation of underlying comorbidities such as obesity, diabetes and hypertension. In such situations, cardio-oncologists are often left with a clinical predicament in finding the optimal therapeutic balance to minimize cardiovascular risks and maximize the benefits in treating cancer. Hence, prognostically there is an urgent need for cost-effective, rapid, sensitive and patient-specific screening platform to allow risk-adapted decision making to prevent cancer therapy related cardiotoxicity. In recent years, momentous progress has been made toward the successful derivation of human cardiovascular cells from induced pluripotent stem cells (iPSCs). This technology has not only provided deeper mechanistic insights into basic cardiovascular biology but has also seamlessly integrated within the drug screening and discovery programs for early efficacy and safety evaluation. In this review, we discuss how iPSC-derived cardiovascular cells have been utilized for testing oncotherapeutics to pre-determine patient predisposition to cardiovascular toxicity. Lastly, we highlight the convergence of tissue engineering technologies and precision medicine that can enable patient-specific cardiotoxicity prognosis and treatment on a multi-organ level.

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Metabolic Maturation Media Improve Physiological Function of Human iPSC-Derived Cardiomyocytes

Cited by 224 publications

References 61 publications

Metabolically-Driven Maturation of hiPSC-Cell Derived Cardiac Chip

Metabolically-Driven Maturation of hiPSC-Cell Derived Cardiac Chip

Reorganization of Metabolism during Cardiomyogenesis Implies Time-Specific Signaling Pathway Regulation

Building Multi-Dimensional Induced Pluripotent Stem Cells-Based Model Platforms to Assess Cardiotoxicity in Cancer Therapies

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