Vaccines delivered to the skin by microneedles-with and without adjuvants-have increased immunogenicity with lower doses than standard vaccine delivery techniques such as intramuscular or intradermal injection. However, the mechanisms underlying this skin-mediated "adjuvant" effect are not clear. Here, we show that the dynamic application of a microprojection array (the Nanopatch) to skin generates localized transient stresses invoking cell death around each projection. Nanopatch application caused significantly higher levels (∼65-fold) of cell death in murine ear skin than i.d. injection using a hypodermic needle. Measured skin cell death is associated with modeled stresses ∼1-10 MPa. Nanopatch-immunized groups also yielded consistently higher anti-immunoglobulin G endpoint titers (up to 50-fold higher) than i.d. groups after delivery of a split virion influenza vaccine. Importantly, colocalization of cell death with nearby live skin cells and delivered antigen was necessary for immunogenicity enhancement. These results suggest a correlation between cell death caused by the Nanopatch with increased immunogenicity. We propose that the localized cell death serves as a "physical immune enhancer" for the adjacent viable skin cells, which also receive antigen from the projections. This natural immune enhancer effect has the potential to mitigate or replace chemical-based adjuvants in vaccines.