Abstract
Osteoarthritis (OA) pathogenesis is profoundly influenced by dysregulated immune dynamics, where persistent interleukin-17 (IL-17)/T helper 17 (Th17) cell mediated inflammation coordinates with failed regenerative processes to perpetuate joint destruction. Here, we unveil the role of myeloid-derived suppressor cells (MDSCs) as dual-phase regulators that paradoxically orchestrate both inflammatory escalation and tissue repair in OA progression. Intra-articular administration of MDSCs in OA mice amplified IL-17 dependent inflammatory cascades and chemokine-driven leukocyte recruitment, revealing a context-dependent pro-inflammatory phenotype. Unexpectedly, MDSC depletion failed to attenuate joint damage, implying their indispensable yet multifaceted role in OA pathogenesis. Mechanistically, MDSCs exhibited functional plasticity by upregulating arginase-1 to polarize M2 macrophages, fostering a regenerative niche alongside their inflammatory activity. To resolve this duality, we developed a bio-responsive hydrogel-microsphere system integrating transforming growth factor β1 (TGF-β1) and interleukin-1 β1 antibody (anti-IL-1β) loaded mesoporous silica nanoparticles (MSNs). This spatiotemporally controlled platform selectively suppressed MDSC-mediated Th17 cell expansion while harnessing their intrinsic capacity to drive M2 macrophage polarization and chondrogenesis. The resultant shift from a pro-inflammatory to pro-regenerative microenvironment significantly attenuated cartilage erosion and restored joint integrity in OA models. Our findings redefine MDSCs as bifunctional immune orchestrators in OA and establish precision biomaterial guided immune decoding as a paradigm-shifting therapeutic strategy. By engineering MDSCs plasticity through antagonistic cytokine delivery, this work provides a blueprint for microenvironment remodeling in degenerative joint diseases.