3D Printed Stem-Cell-Laden, Microchanneled Hydrogel Patch for the Enhanced Release of Cell-Secreting Factors and Treatment of Myocardial Infarctions.

Over the past several years, biomaterials loaded with mesenchymal stem cells (MSCs) have increasingly been used to reduce the myocardial fate of postinfarction collagen deposition and scar tissue formation. Despite successful gains, therapeutic efficacy has remained limited because of restricted transport of cell-secreting factors at the site of implantation. We hypothesized that an MSC-laden hydrogel patch with multiple microchannels would retain transplanted cells on target tissue and support transport of cell-secreting factors into tissue. By doing so, the gel patch will improve the therapeutic potential of the cells and minimize the degradation of myocardial tissue postinfarction. To examine this hypothesis, a stereolithographic apparatus (SLA) was used to introduce microchannels of controlled diameters (e.g., 500 and 1000 µm) during in situ cross-linking reaction of poly(ethylene glycol)dimethacrylate solution suspended with cells. Placement of the MSC-laden, microchanneled gel patch on the occluded left coronary artery in a murine model showed significant improvement in the ejection fraction, fractional shortening, and stroke volume, compared with gel patches without MSCs and MSC-laden gel patches without microchannels. In particular, the microchannels significantly reduced the number of cells required to recover cardiac function, while minimizing cardiac remodeling. In sum, the microchanneled gel patch would provide a means to prevent abnormal fibrosis resulting from acute ischemic injury.

A Hydrogel Construct and Fibrin-based Glue Approach to Deliver Therapeutics in a Murine Myocardial Infarction Model.

The murine MI model is widely recognized in the field of cardiovascular disease, and has consistently been used as a first step to test the efficacy of treatments in vivo. The traditional, established protocol has been further fine-tuned to minimize the damage to the animal. Notably, the pectoral muscle layers are teased away rather than simply cut, and the thoracotomy is approached intercostally as opposed to breaking the ribs in a sternotomy, preserving the integrity of the ribcage. With these changes, the overall stress on the animal is decreased. Stem cell therapies aimed to alleviate the damage caused by MIs have shown promise over the years for their pro-angiogenic and anti-apoptotic benefits. Current approaches of delivering cells to the heart surface typically involve the injection of the cells either near the damaged site, within a coronary artery, or into the peripheral blood stream. While the cells have proven to home to the damaged myocardium, functionality is limited by their poor engraftment at the site of injury, resulting in diffusion into the blood stream. This manuscript highlights a procedure that overcomes this obstacle with the use of a cell-encapsulated hydrogel patch. The patch is fabricated prior to the surgical procedure and is placed on the injured myocardium immediately following the occlusion of the left coronary artery. To adhere the patch in place, biocompatible external fibrin glue is placed directly on top of the patch, allowing for it to dry to both the patch and the heart surface. This approach provides a novel adhesion method for the application of a delicate cell-encapsulating therapeutic construct.