The development of a platform to manipulate cardiomyocyte structure and function

Cardiac tissue engineering to replace damaged areas of the postmitotic heart is still presented with significant challenges, due to the complex and dynamic interplay of electrical, mechanical and biochemical signals involved in the myocardium. The advancement of regenerative approaches is focussed on understanding the underlying regulatory mechanisms involved throughout cardiac development. However, current knowledge of how biophysical cues in the stem cell niche can modulate cell behaviour is limited. Firstly, polyacrylamide-co-acrylic acid was used as an in vitro stiffness-tuneable platform to test the effect of substrate mechanics on human induced pluripotent stem cell (hiPSC) differentiation into cardiomyocytes (CM). The results showed that the optimum differentiation efficiency level peaked at the embryonic-like stiffness of 560 Pa, with increased upregulation of cardiac genes. Functionally, hiPSC-CMs showed a biphasic relationship with a faster calcium transient and higher force generation at cardiac physiological stiffness. Next, shape was incorporated into the experimental design via CardioArray, a custom-built platform which mimics both the stiffness and shape of an adult human CM. This system can accommodate individual hiPSC-CMs to adopt the 3D geometry of an adult CM, while at the same time providing the relevant stiffness cues from the underlying substrate. The results highlighted the specific contribution of stiffness and 3D shape to α-sarcomeric structure, cell membrane stiffness, single cell gene expression and intracellular calcium cycling. Finally, the electrical microenvironment was investigated as a third infleuncing factor on hiPSC-CM development. A hybrid conductive polyaniline-Scl2 scaffold was fabricated, showing long term electronic stability and no cell toxicity when interfaced with electrosensitive hiPSC-CMs. This could provide electromechanical stability in model studies. Improvement of conduction velocity was observed in an in vitro myocardial slice model. As a whole, this thesis demonstrates the differential effects of substrate mechanics on hiPSC cardiac differentiation, providing a novel crucial understanding of how biophysical cues modulate the stem cell niche during differentiation and in vitro culture.Open Acces

Glycosylated superparamagnetic nanoparticle gradients for osteochondral tissue engineering

In developmental biology, gradients of bioactive signals direct the formation of structural transitions in tissue that are key to physiological function. Failure to reproduce these native features in an in vitro setting can severely limit the success of bioengineered tissue constructs. In this report, we introduce a facile and rapid platform that uses magnetic field alignment of glycosylated superparamagnetic iron oxide nanoparticles, pre-loaded with growth factors, to pattern biochemical gradients into a range of biomaterial systems. Gradients of bone morphogenetic protein 2 in agarose hydrogels were used to spatially direct the osteogenesis of human mesenchymal stem cells and generate robust osteochondral tissue constructs exhibiting a clear mineral transition from bone to cartilage. Interestingly, the smooth gradients in growth factor concentration gave rise to biologically-relevant, emergent structural features, including a tidemark transition demarcating mineralized and non-mineralized tissue and an osteochondral interface rich in hypertrophic chondrocytes. This platform technology offers great versatility and provides an exciting new opportunity for overcoming a range of interfacial tissue engineering challenges

Remodelling of adult cardiac tissue subjected to physiological and pathological mechanical load in vitro

International audienceAims Cardiac remodelling is the process by which the heart adapts to its environment. Mechanical load is a major driver of remodelling. Cardiac tissue culture has been frequently employed for in vitro studies of load-induced remodelling; however, current in vitro protocols (e.g. cyclic stretch, isometric load, and auxotonic load) are oversimplified and do not accurately capture the dynamic sequence of mechanical conformational changes experienced by the heart in vivo. This limits translational scope and relevance of findings.Methods and results We developed a novel methodology to study chronic load in vitro. We first developed a bioreactor that can recreate the electromechanical events of in vivo pressure–volume loops as in vitro force–length loops. We then used the bioreactor to culture rat living myocardial slices (LMS) for 3 days. The bioreactor operated based on a 3-Element Windkessel circulatory model enabling tissue mechanical loading based on physiologically relevant parameters of afterload and preload. LMS were continuously stretched/relaxed during culture simulating conditions of physiological load (normal preload and afterload), pressure-overload (normal preload and high afterload), or volume-overload (high preload & normal afterload). At the end of culture, functional, structural, and molecular assays were performed to determine load-induced remodelling. Both pressure- and volume-overloaded LMS showed significantly decreased contractility that was more pronounced in the latter compared with physiological load (P < 0.0001). Overloaded groups also showed cardiomyocyte hypertrophy; RNAseq identified shared and unique genes expressed in each overload group. The PI3K-Akt pathway was dysregulated in volume-overload while inflammatory pathways were mostly associated with remodelling in pressure-overloaded LMS.Conclusion We have developed a proof-of-concept platform and methodology to recreate remodelling under pathophysiological load in vitro. We show that LMS cultured in our bioreactor remodel as a function of the type of mechanical load applied to them

Raman spectroscopy imaging reveals interplay between atherosclerosis and medial calcification in the human aorta

Raman spectroscopy of tissue biochemistry reveals the interplay between atherosclerosis and medial calcification in human aorta.</jats:p

Integrins Increase Sarcoplasmic Reticulum Activity for Excitation-Contraction Coupling in Human Stem Cell-Derived Cardiomyocytes

Engagement of the sarcoplasmic reticulum (SR) Ca(2+) stores for excitation–contraction (EC)-coupling is a fundamental feature of cardiac muscle cells. Extracellular matrix (ECM) proteins that form the extracellular scaffolding supporting cardiac contractile activity are thought to play an integral role in the modulation of EC-coupling. At baseline, human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) show poor utilisation of SR Ca(2+) stores, leading to inefficient EC-coupling, like developing or human CMs in cardiac diseases such as heart failure. We hypothesised that integrin ligand–receptor interactions between ECM proteins and CMs recruit the SR to Ca(2+) cycling during EC-coupling. hiPSC-CM monolayers were cultured on fibronectin-coated glass before 24 h treatment with fibril-forming peptides containing the integrin-binding tripeptide sequence arginine–glycine–aspartic acid (2 mM). Micropipette application of 40 mM caffeine in standard or Na(+)/Ca(2+)-free Tyrode’s solutions was used to assess the Ca(2+) removal mechanisms. Microelectrode recordings were conducted to analyse action potentials in current-clamp. Confocal images of labelled hiPSC-CMs were analysed to investigate hiPSC-CM morphology and ultrastructural arrangements in Ca(2+) release units. This study demonstrates that peptides containing the integrin-binding sequence arginine–glycine–aspartic acid (1) abbreviate hiPSC-CM Ca(2+) transient and action potential duration, (2) increase co-localisation between L-type Ca(2+) channels and ryanodine receptors involved in EC-coupling, and (3) increase the rate of SR-mediated Ca(2+) cycling. We conclude that integrin-binding peptides induce recruitment of the SR for Ca(2+) cycling in EC-coupling through functional and structural improvements and demonstrate the importance of the ECM in modulating cardiomyocyte function in physiology