Laminin nanofiber meshes that mimic morphological properties and bioactivity of basement membranes.

The basement membrane protein, laminin I, has been used broadly as a planar two-dimensional film or in a three-dimensional form as a reconstituted basement membrane gel such as Matrigel to support cellular attachment, growth, and differentiation in vitro. In basement membranes in vivo, laminin exhibits a fibrillar morphology, highlighting the electrospinning process as an ideal method to recreate such fibrous substrates in vitro. Electrospinning was employed to fabricate meshes of murine laminin I nanofibers (LNFs) with fiber size, geometry, and porosity of authentic basement membranes. Purified laminin I was solubilized and electrospun in parametric studies of fiber diameters as a function of polymer solution concentration, collecting distance, and flow rate. Resulting fiber diameters ranged from 90 to 300 nm with mesh morphologies containing beads. Unlike previously described nanofibers (NFs) synthesized from proteins such as collagen, meshes of LNFs retain their structural features when wetted and do not require fixation by chemical crosslinking, which often destroys cell attachment and other biological activity. The LNF meshes maintained their geometry for at least 2 days in culture without chemical crosslinking. PC12 cells extended neurites without nerve growth factor stimulation on LNF substrates. Additionally, LNFs significantly enhance both the rate and quantity of attachment of human adipose stem cells (ASCs) compared to laminin films. ASCs were viable and maintained attachment to LNF meshes in serum-free media for at least 3 days in culture and extended neurite-like processes after 24 h in serum-free media conditions without media additives to induce differentiation. LNF meshes are a novel substrate for cell studies in vitro, whose properties may be an excellent scaffold material for delivering cells in tissue engineering applications in vivo.