In the present study, the effects of air-flow impedance electrospinning and air-flow rates on silk-based scaffolds for biological tissues were investigated. First, the properties of scaffolds obtained from 7% and 12% silk concentrations were defined. In addition, cell infiltration and viability of MCF-10A breast epithelial cells cultured onto these scaffolds were used to determine the biological suitability of these nanostructures. Air-flow impedance electrospun scaffolds resulted in an overall larger pore size than scaffolds electrospun on a solid mandrel, with the largest pores in 7% silk electrospun with an air pressure of 100 kPa and in 12% silk electrospun with an air pressure of 400 kPa (13.4 +/- 0.67 and 26.03 +/- 1.19 mu m, respectively). After 14 days in culture, the deepest MCF-10A cell infiltration (36.58 +/- 2.28 mu m) was observed into 7% silk air-flow impedance electrospun scaffolds subjected to an air pressure of 100 kPa. In those scaffolds MCF-10A cell viability was also highest after 14 days in culture. Together, these results strongly support the use of 7% silk-based scaffolds electrospun with a 100 kPa air-flow as the most suitable microenvironment for MCF-10A infiltration and viability. Copyright (c) 2013 John Wiley & Sons, Ltd.