Myocardial infarction (MI) and congestive heart failure (CHF) are major cardiovascular diseases with high mortality rates. Via the discovery and application of biomaterials, cardiac patch tissue engineering has become an advanced strategy for surgical intervention of MI and CHF therapy. The criteria of scaffold for cardiac patch tissue engineering include porous, elastic, biocompatible and mimic biomechanical properties of the cardiac muscle. Electrospin is a promising technique to fabricate nanofibrous scaffold which is structurally similar to the native extracellular matrix (ECM) and provides high surface‐to‐volume ratios with interconnected pores. In this thesis, we demonstrate a successfully developed scaffold utilizing electrospin technique based on polyurethane / ethyl cellulose (PU/EC) blends. The fiber diameters can be well controlled in the range of 100 nm to 1 μm by rationally tuning the processing parameters of electrospin. The developed scaffold features significant mechanical properties and biocompatibility. Namely, as compared to the pristine PU scaffold, adjusting the blending ratio of PU/EC could enhance the mechanical properties including tensile strength and Young’s modulus but still remain high elongation and flexibility. Additionally, the in vitro test of culturing the H9C2 cells (rat cardiomyocyte cell lines) on scaffolds showed the increasing cell amount over time in all types of scaffolds, indicating their good biocompatibility. Furthermore, the relation between fiber width and cell growth was also systematically studied by culturing H9C2 cells on scaffolds with different diameters. The fibrous structure was found to facilitate the cell adhesion and spread in the beginning 4 hours as compared to the flat tissue-culture polystyrene (TCPS). More pronounced spread rate was discovered in the scaffold with wider fibers, which suggests the more potential applicability in cardiac patch tissue engineering. In additional to the scaffold with randomly oriented fibers, we also successfully developed scaffold with aligned fibers by employing a rolling collector which guided the fiber deposition. Such scaffold showed considerably improved mechanical properties including higher Young’s modulus and tensile strength as compared to the isotropic one. The proliferation of H9C2 cell was also enhanced on aligned fibers with elongated morphology along fiber direction which is distinctive to the flat morphology observed in scaffolds with isotropic fibers. The present thesis extends the current technology in the scaffold development which possesses promising potential in realistic application of cardiac patch tissue engineering.