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1. A 3D Bioprinted Human Cardiac Cell Platform to Model the Pathophysiology of Diabetes

   Binata Joddar, Shweta AnilKumar ( January 2020 , Circulation research)

   null (Ed.)

   Type-II diabetes (T2D) patients affected by underlying hyperglycemic (high glucose/blood sugar) conditions often suffer from cardiac atrophy, resulting in tissue mass reduction and debilitating cardiac health. To understand pathophysiological mechanisms during progression of cardiac atrophy, a 3D bioprinted organoid platform was developed from a mixture of hydrogels containing human cardiac cells, including cardiomyocytes (CM), fibroblasts (CF) and endothelial cells (EC), to mimic the functionality of the in-vivo tissue. The organoids were cultured using normoglycemic- or hyperglycemic-conditions. The expression of essential biomarkers in these organoids, for myocardin (Myocd), troponin-I (TRP-I), fibroblast protein-1 (FSP-1) and endothelin-1 (ET-1) was confirmed. To assess the physiological cellular connections during hyperglycemia, the presence of Connexin-43 (CX-43) was assessed in the presence of a CX-43 blocker, gap26. Epigenomic tools were used to simultaneously interrogate histone-modifications by histone 3 lysine 9 mono-methylation (H3K9me1) along with the co-regulation of inflammatory mediators, such as the high mobility group box 1 (HMGB1) and toll like receptor 4 (TLR4) in the cardiac organoids cultured using normal versus hyperglycemic conditions. Organoids exposed to high glucose showed an increased expression of H3K9me1 as well as inflammatory mediators HMGB1 and TLR4. Hyperglycemia also exhibited alterations in expression of Myocd and FSP-1 in the organoids, compared to normoglycemic conditions. Treatment with gap26 affected the CX-43 expression significantly, in organoids cultured under hyperglycemia suggesting that high glucose conditions associated with prolonged diabetes may lead to compromised CM-CF coupling, essential for maintenance of cardiac functionality. Increased levels of H3K9me1 suggest decreased expression of Myocd, which may lead to CM degeneration. Epigenetic modifications including alterations in histone methylation in regulation of the myocardial genes and gap junction proteins under hyperglycemic conditions, may lead to cardiac atrophy. We expect to establish an actual T2D patient iPSC cell derived cardiac platform, to offer new therapeutic opportunities within the field. 

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2. Constant-potential environment for activating and synchronizing cardiomyocyte colonies with on-chip ion-depleting perm-selective membranes

   https://doi.org/10.1039/d0lc00809e  

   Yadav, Vivek ; Chong, Nicholas ; Ellis, Bradley ; Ren, Xiang ; Senapati, Satyajyoti ; Chang, Hsueh-Chia ; Zorlutuna, Pinar ( November 2020 , Lab on a Chip)

   null (Ed.)

   In this study, an ion depleted zone created by an ion-selective membrane was used to impose a high and uniform constant extracellular potential over an entire ∼1000 cell rat cardiomyocyte (rCM) colony on-a-chip to trigger synchronized voltage-gated ion channel activities while preserving cell viability, thus extending single-cell voltage-clamp ion channel studies to an entire normalized colony. Image analysis indicated that rCM beating was strengthened and accelerated (by a factor of ∼2) within minutes of ion depletion and the duration of contraction and relaxation phases was significantly reduced. After the initial synchronization, the entire colony responds collectively to external potential changes such that beating over the entire colony can be activated or deactivated within 0.1 s. These newly observed collective dynamic responses, due to simultaneous ion channel activation/deactivation by a uniform constant-potential extracellular environment, suggest that perm-selective membrane modules on cell culture chips can facilitate studies of extracellular cardiac cell electrical communication and how ion-channel related pathologies affect cardiac cell synchronization. The future applications of this new technology can lead to better drug screening platforms for cardiotoxicity as well as platforms that can facilitate synchronized maturation of pluripotent stem cells into colonies with high electrical connectivity. 

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3. 3D bioprinted aged human post‐infarct myocardium tissue model

   https://doi.org/10.1002/hsr2.1945  

   Basara, Gozde ; Celebi, Lara Ece ; Ronan, George ; Discua Santos, Victoria ; Zorlutuna, Pinar ( April 2024 , Health Science Reports)

   Fibrotic tissue formed after myocardial infarction (MI) can be as detrimental as MI itself. However, current in vitro cardiac fibrosis models fail to recapitulate the complexities of post‐MI tissue. Moreover, although MI and subsequent fibrosis is most prominent in the aged population, the field suffers from inadequate aged tissue models. Herein, an aged human post‐MI tissue model, representing the native microenvironment weeks after initial infarction, is engineered using three‐dimensional bioprinting via creation of individual bioinks to specifically mimic three distinct regions: remote, border, and scar.

   The aged post‐MI tissue model is engineered through combination of gelatin methacryloyl, methacrylated hyaluronic acid, aged type I collagen, and photoinitiator at variable concentrations with different cell types, including aged human induced pluripotent stem cell‐derived cardiomyocytes, endothelial cells, cardiac fibroblasts, and cardiac myofibroblasts, by introducing a methodology which utilizes three printheads of the bioprinter to model aged myocardium. Then, using cell‐specific proteins, the cell types that comprised each region are confirmed using immunofluorescence. Next, the beating characteristics are analyzed. Finally, the engineered aged post‐MI tissue model is used as a benchtop platform to assess the therapeutic effects of stem cell‐derived extracellular vesicles on the scar region.

   As a result, high viability (>74%) was observed in each region of the printed model. Constructs demonstrated functional behavior, exhibiting a beating velocity of 6.7 μm/s and a frequency of 0.3 Hz. Finally, the effectiveness of hiPSC‐EV and MSC‐EV treatment was assessed. While hiPSC‐EV treatment showed no significant changes, MSC‐EV treatment notably increased cardiomyocyte beating velocity, frequency, and confluency, suggesting a regenerative potential.

   In conclusion, we envision that our approach of modeling post‐MI aged myocardium utilizing three printheads of the bioprinter may be utilized for various applications in aged cardiac microenvironment modeling and testing novel therapeutics.

    

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4. In need of age‐appropriate cardiac models: Impact of cell age on extracellular matrix therapy outcomes

   https://doi.org/10.1111/acel.13966  

   Ozcebe, S. Gulberk ; Zorlutuna, Pinar ( October 2023 , Aging Cell)

   Aging is the main risk factor for cardiovascular disease (CVD). As the world's population ages rapidly and CVD rates rise, there is a growing need for physiologically relevant models of aging hearts to better understand cardiac aging. Translational research relies heavily on young animal models; however, these models correspond to early ages in human life, therefore cannot fully capture the pathophysiology of age‐related CVD. Here, we first investigated the transcriptomic and proteomic changes that occur with human cardiac aging. We then chronologically aged human induced pluripotent stem cell‐derived cardiomyocytes (iCMs) and showed that 14‐month‐old iCMs exhibited a similar aging profile to the human CMs and recapitulated age‐related disease hallmarks. Using aged iCMs, we studied the effect of cell age on the young extracellular matrix (ECM) therapy, an emerging approach for myocardial infarction (MI) treatment and prevention. Young ECM decreased oxidative stress, improved survival, and post‐MI beating in aged iCMs. In the absence of stress, young ECM improved beating and reversed aging‐associated expressions in 3‐month‐old iCMs while causing the opposite effect on 14‐month‐old iCMs. The same young ECM treatment surprisingly increased SASP and impaired beating in advanced aged iCMs. Overall, we showed that young ECM therapy had a positive effect on post‐MI recovery; however, cell age was determinant in the treatment outcomes without any stress conditions. Therefore, “one‐size‐fits‐all” approaches to ECM treatments fail, and cardiac tissue engineered models with age‐matched human iCMs are valuable in translational basic research for determining the appropriate treatment, particularly for the elderly.

    

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5. Syncytium cell growth increases Kir2.1 contribution in human iPSC-cardiomyocytes

   https://doi.org/10.1152/ajpheart.00148.2020  

   Li, Weizhen ; Han, Julie L. ; Entcheva, Emilia ( November 2020 , American Journal of Physiology-Heart and Circulatory Physiology)

   null (Ed.)

   Human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) enable cardiotoxicity testing and personalized medicine. However, their maturity is of concern, including relatively depolarized resting membrane potential and more spontaneous activity compared with adult cardiomyocytes, implicating low or lacking inward rectifier potassium current ( I k1 ). Here, protein quantification confirms Kir2.1 expression in hiPSC-CM syncytia, albeit several times lower than in adult heart tissue. We find that hiPSC-CM culture density influences Kir2.1 expression at the mRNA level (potassium inwardly rectifying channel subfamily J member 2) and at the protein level and its associated electrophysiology phenotype. Namely, all-optical cardiac electrophysiology and pharmacological treatments reveal reduction of spontaneous and irregular activity and increase in action potential upstroke in denser cultures. Blocking I k1 -like currents with BaCl 2 increased spontaneous frequency and blunted action potential upstrokes during pacing in a dose-dependent manner only in the highest-density cultures, in line with I k1 ’s role in regulating the resting membrane potential. Our results emphasize the importance of syncytial growth of hiPSC-CMs for more physiologically relevant phenotype and the power of all-optical electrophysiology to study cardiomyocytes in their multicellular setting. NEW & NOTEWORTHY We identify cell culture density and cell-cell contact as an important factor in determining the expression of a key ion channel at the transcriptional and the protein levels, KCNJ2/Kir2.1, and its contribution to the electrophysiology of human induced pluripotent stem cell-derived cardiomyocytes. Our results indicate that studies on isolated cells, out of tissue context, may underestimate the cellular ion channel properties being characterized. 

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