Abstract
Appropriate macrophage response to an implanted biomaterial is crucial for successful tissue healing outcomes. In this work we investigated how intrinsic topological cues from electrospun biomaterials and extrinsic mechanical loads cooperate to guide macrophage activation and macrophage-tendon fibroblast cross-talk. We performed a series of in vitro and in vivo experiments using aligned or randomly oriented polycaprolactone nanofiber substrates in both mechanically loaded and unloaded conditions. Across all experiments a disorganized biomaterial fiber topography was alone sufficient to promote a pro-inflammatory signature in macrophages, tendon fibroblasts, and tendon tissue. Extrinsic mechanical loading was found to strongly regulate the character of this signature by reducing pro-inflammatory markers both in vitro and in vivo. We observed that macrophages generally displayed a stronger response to biophysical cues than tendon fibroblasts, with dominant effects of cross-talk between these cell types observed in mechanical co-culture models. Collectively our data suggest that macrophages play a potentially important role as mechanosensory cells in tendon repair, and provide insight into how biological response might be therapeutically modulated by rational biomaterial designs that address the biomechanical niche of recruited cells.
Highlights
The use of ‘mechanical augmentation’ with biomaterial patches that increase strength of surgically repaired soft tissues has emerged as a major clinical advance in orthopedic medicine, with increasing use of a wide range of natural or synthetic patches [1,2,3,4]
In this work we present a range of in vitro and in vivo studies to characterize the effects of mechanical cues presented to macrophages and/or human tendon fibroblasts from electrospun PCL scaffolds mimicking those used in surgical repairs of torn tendons
Surface micro- and nano-topography and chemical composition have been considered central to this response, and these properties have been considered in biomaterial design [40]
Summary
The use of ‘mechanical augmentation’ with biomaterial patches that increase strength of surgically repaired soft tissues has emerged as a major clinical advance in orthopedic medicine, with increasing use of a wide range of natural or synthetic patches [1,2,3,4]. While natural extracellular matrix (ECM)-derived scaffolds, such as collagen patches, provide strong cues for cell infiltration, their degradation rate is rapid and the mechanical support they offer is limited [3,5]. Polycaprolactone (PCL) nanofiber scaffolds are synthetic, degradable and biomimetic constructs that offer good biocompatibility, slow degradation rates and ‘tunable’ mechanical properties [11,12,13,14]. Due to their capacity to promote tissue healing by simultaneously providing biological cues and mechanical support, clinical use of such scaffolds is growing [2]
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