Neutrophils are innate immune effector cells that traffic from the peripheral blood to extravascular sites of inflammation. β2 integrins are involved during multiple phases of neutrophil recruitment, including the transition from rolling to arrest, firm attachment and motility within the vasculature. Following neutrophil arrest, adhesion stabilization occurs as the neutrophil interacts with the endothelial surface and crawls into a favorable position for extravasation. The cytoskeletal protein vinculin has been implicated in other cell types as a regulator of adhesion strength by promoting focal adhesion maturation and as a sensor of the mechanical properties of the microenvironment. Neutrophils express vinculin but do not form mature focal adhesions. Here, we characterize the role of vinculin in β2 integrin-dependent neutrophil adhesion, motility, mechanosensing, and recruitment. We observe that knockout of vinculin attenuates, but does not completely abrogate, neutrophil adhesion, spreading, and crawling under static conditions. In the presence of forces from fluid flow, vinculin was not required for neutrophil adhesion or migration. Vinculin deficiency only mildly attenuated neutrophil traction stresses and spreading on stiff, but not soft, polyacrylamide gels indicating a minor role for vinculin in the mechanosensing of the neutrophil as compared to slower moving mesenchymal cells that form mature focal adhesions. Consistent with these findings, we observe in vivo neutrophil recruitment into the inflamed peritoneum of mice remains intact in the absence of vinculin. Together, these data suggest that while vinculin regulates some aspects of neutrophil adhesion and spreading, it may be dispensable for neutrophil recruitment and motility in vivo.