Neutrophil and NET-driven pulmonary microvascular injury following myocardial injury: attenuation by S100A8/A9 inhibition

Myocardial infarction (MI) triggers not only local cardiac damage but also a systemic inflammatory response that extends to remote organs. The pulmonary microcirculation, by virtue of its dense capillary network and direct anatomical proximity to the heart, is particularly vulnerable. Neutrophils and their effector mechanisms, including neutrophil extracellular traps (NETs) and the alarmin S100A8/A9, have been implicated in adverse cardiovascular outcomes. However, their role in remote damage post-MI remains unclear. Using intravital in vivo imaging in murine MI models and analysis of human lung tissues, we show that MI induces rapid pulmonary neutrophil and platelet recruitment, formation of platelet-neutrophil aggregates within capillaries, and endothelial activation. These changes are accompanied by NET release, fibrin deposition, and microvascular obstruction, leading to impaired vascular perfusion and necrosis. These pulmonary disturbances closely parallel those in the infarcted myocardium and exceed responses observed in other organs such as the kidney and liver, highlighting the lung as a vulnerable target organ. Increased neutrophil recruitment was associated with marked upregulation of the neutrophil-derived, NET-associated alarmin S100A8/A9 in mouse and human lungs, where it co-localised with infiltrating neutrophils, NETs, and platelet aggregates. Additionally, we show that short-term pharmacological inhibition of S100A8/A9 with ABR-238901 significantly attenuated pulmonary neutrophil infiltration, reduced NETosis and fibrin deposition, and restored capillary perfusion while rebalancing the pulmonary immune landscape. Together, these findings identify the lung as a principal site of remote thrombo-inflammatory injury after MI and implicate S100A8/A9, a neutrophil-derived, NET-associated alarmin, as a mechanistic driver of pulmonary microvascular dysfunction. We propose that targeting this pathway could provide dual protection for both cardiac and pulmonary microcirculations in the acute phase of myocardial injury.