Recent investigations indicate that innate immune "danger- signaling" pathways mediate metal implant debris induced-inflammatory responses, for example, NALP3 inflammasome. How the physical characteristics of particles (size, shape, and chemical composition) affect this inflammatory reactivity remains controversial. We examined the role of Cobalt-Chromium- Molybdenum (CoCrMo) alloy particle shape and size on human macrophage phagocytosis, lysosomal destabilization, and inflammasome activation. Round/smooth versus irregularly shaped/rough CoCrMo-alloy particles of ∼1 and 6-7 μm diameter were investigated for differential lysosomal damage and inflammasome activation in human monocytes/macrophages. While spherical/smooth 1 μm CoCrMo-alloy particles did not measurably affect macrophage IL-1β production, irregular 1 μm CoCrMo-alloy particles induced significant IL-1β increases over controls. Both round/smooth particles and irregular CoCrMo-alloy particles that were 6-7 μm in size induced >10-fold increases in IL-1β production compared to similarly shaped smaller particles (p < 0.05). Larger irregular particles induced a greater degree of intracellular lysosomal damage and a >3-fold increase in IL-1β versus similarly sized round/smooth particles (at an equal dose, particles/cell). CoCrMo-alloy particle-size-induced IL-1β production was dependent on the lysosomal protease Cathepsin B, further supporting lysosomal destabilization as causative in inflammation. Phagocytosable larger/irregular shaped particles (6 μm) demonstrated the greatest lysosomal destabilization (observed immunofluorescently) and inflammatory reactivity when compared on an equal dose basis (particles/cell) to smaller/spherical 1 μm particles in vitro. Copyright © 2013 Orthopaedic Research Society.
CITATION STYLE
Caicedo, M. S., Samelko, L., McAllister, K., Jacobs, J. J., & Hallab, N. J. (2013). Increasing both CoCrMo-alloy particle size and surface irregularity induces increased macrophage inflammasome activation in vitro potentially through lysosomal destabilization mechanisms. Journal of Orthopaedic Research, 31(10), 1633–1642. https://doi.org/10.1002/jor.22411
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