The blood-brain barrier is a multicellular and basement membrane unit that regulates molecular transport between the blood and central nervous system. Many cerebral pathologies, such as acute stroke and chronic vascular dementia, result in a disrupted blood-brain barrier, increasing its permeability and allowing the entry of potentially neurotoxic molecules. The activation of matrix metalloproteinases mediates further blood-brain barrier damage. The inhibition of matrix metalloproteinases is a potential strategy for stroke therapy. As inhibitors are developed, efficient context-specific screening methods will be required. Models of the blood-brain barrier have been extensively used to study neuropathologies and the effect of various treatment options.Herein, we describe a co-culture model of the blood-brain barrier composed of brain microvascular endothelial cells and astrocytes grown on an artificial basement membrane-coated membrane insert. Our cell model forms a barrier and is a simple first approximation of blood-brain barrier integrity. As currently developed, the model may be applied to testing the effect of matrix metalloproteinases and matrix metalloproteinase inhibitors on blood-brain barrier physiology and pathophysiology. The model is a quick and effective evaluation tool for generating nonclinical data in a living cell system before proceeding to animal models.