Bridging the Gap in Ashby's Map for Soft Material Properties for Tissue Engineering.

Ashby's map's role in rationally selecting materials for optimal performance is well-established in traditional engineering applications. However, there is a major gap in Ashby's maps in selecting materials for tissue engineering, which are very soft with an elastic modulus of less than 100 kPa. To fill the gap, we create an elastic modulus database to effectively connect soft engineering materials with biological tissues such as the cardiac, kidney, liver, intestine, cartilage, and brain. This soft engineering material mechanical property database is created for widely applied agarose hydrogels based on big-data screening and experiments conducted using ultra-low-concentration (0.01-0.5 wt %) hydrogels. Based on that, an experimental and analysis protocol is established for evaluating the elastic modulus of ultra-soft engineering materials. Overall, we built a mechanical bridge connecting soft matter and tissue engineering by fine-tuning the agarose hydrogel concentration. Meanwhile, a soft matter scale (degree of softness) is established to enable the manufacturing of implantable bio-scaffolds for tissue engineering.

Membrane Remodeling of Human-Engineered Cardiac Tissue by Chronic Electric Stimulation.

Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) show immature features, but these are improved by integration into 3D cardiac constructs. In addition, it has been demonstrated that physical manipulations such as electrical stimulation (ES) are highly effective in improving the maturation of human-engineered cardiac tissue (hECT) derived from hiPSC-CMs. Here, we continuously applied an ES in capacitive coupling configuration, which is below the pacing threshold, to millimeter-sized hECTs for 1-2 weeks. Meanwhile, the structural and functional developments of the hECTs were monitored and measured using an array of assays. Of particular note, a nanoscale imaging technique, scanning ion conductance microscopy (SICM), has been used to directly image membrane remodeling of CMs at different locations on the tissue surface. Periodic crest/valley patterns with a distance close to the sarcomere length appeared on the membrane of CMs near the edge of the tissue after ES, suggesting the enhanced transverse tubulation network. The SICM observation is also supported by the fluorescence images of the transverse tubulation network and α-actinin. Correspondingly, essential cardiac functions such as calcium handling and contraction force generation were improved. Our study provides evidence that chronic subthreshold ES can still improve the structural and functional developments of hECTs.

Directional dependence on concomitant pressure and volume increases during left ventricular filling.

Myocardial infarction continues to be a leading cause of mortality and morbidity globally. A major challenge post-myocardial infarction is scar tissue growth, which eventually can lead to heart failure. Cardiovascular regenerative strategies to minimize scar tissue growth and promote cardiac tissue formation are currently being actively pursued via the development of cardiac patches. However, the patch must have viscoelastic properties that mimic healthy cardiac tissues to facilitate proper cardiac patch-to-cell communications. To this end, we investigated the tissue microstructure and the stress relaxation properties of the porcine left ventricle (LV) along its long and short axes using a nanoindentation technique. We found significantly higher collagen density along the long axis than the short axis (p < 0.05). We then identified a much more rapid stress relaxation along the porcine LV's short axis compared to its long axis during the diastolic filling timeframe. Therefore, these findings show that concomitant LV pressure and volume increases from blood filling during diastole are directional dependent, with its short axis responsible for increase in LV volume and the long axis responsible for increase in LV pressure. These directional-dependent stress relaxation properties are essential in the design of structurally, bio-mimetic cardiac patches to support cardiac function and regeneration.