Abstract
The immune system is a vital regulator of tissue repair after trauma and the response to implantable scaffolds for regenerative medicine. Decellularized extracellular matrix (ECM) scaffolds promote tissue integration and remodeling following traumatic injury in part due initiating a pro-reparative Type-2 immune response. However, exogenous soluble inflammatory immune signals can be introduced during scaffold implantation, including microbial products in contaminated surgical fields or during immunotherapy to treat autoimmunity and cancer. It remains largely unknown how such immune mediators modulate the ECM scaffold immune environment and subsequent scaffold remodeling. In the present study, we co-delivered 3 distinct inflammatory immune adjuvants (cyclic di-AMP [CDA], monophosphoryl lipid A [MPLA], and granulocyte colony stimulating factor [GM-CSF]) with small intestinal submucosa (SIS) ECM in a murine volumetric muscle loss injury model, evaluating acute (1 week) and long-term (8-week) immune environments and scaffold remodeling. High parameter spectral cytometry, histologic analysis, and PCR revealed differential potentiation of the ECM scaffold microenvironment. Type 2 immune programs including IL-4, eosinophils, CD4 T cells, and CD206/CD86 macrophage ratios were induced in all ECM groups but attenuated by varying amounts with the CDA and MPLA co-delivery. By 8-weeks, inflammation had largely subsided, and histologically ECM with GM-CSF or MPLA showed the greatest degradation and remodeling into adipose tissue. These findings suggest that early pro-inflammatory compound delivery does not abrogate the ECM immune environment but does attenuate some programs while inducing others. These have long-term effects on scaffold remodeling and should be a consideration for surgical reconstruction in patients receiving immune stimulatory therapies.