Macrophages Modulate the Function of MSC- and iPSC-Derived Fibroblasts in the Presence of Polyethylene Particles.

Fibroblasts in the synovial membrane secrete molecules essential to forming the extracellular matrix (ECM) and supporting joint homeostasis. While evidence suggests that fibroblasts contribute to the response to joint injury, the outcomes appear to be patient-specific and dependent on interactions between resident immune cells, particularly macrophages (Mφs). On the other hand, the response of Mφs to injury depends on their functional phenotype. The goal of these studies was to further explore these issues in an in vitro 3D microtissue model that simulates a pathophysiological disease-specific microenvironment. Two sources of fibroblasts were used to assess patient-specific influences: mesenchymal stem cell (MSC)- and induced pluripotent stem cell (iPSC)-derived fibroblasts. These were co-cultured with either M1 or M2 Mφs, and the cultures were challenged with polyethylene particles coated with lipopolysaccharide (cPE) to model wear debris generated from total joint arthroplasties. Our results indicated that the fibroblast response to cPE was dependent on the source of the fibroblasts and the presence of M1 or M2 Mφs: the fibroblast response as measured by gene expression changes was amplified by the presence of M2 Mφs. These results demonstrate that the immune system modulates the function of fibroblasts; furthermore, different sources of differentiated fibroblasts may lead to divergent results. Overall, our research suggests that M2 Mφs may be a critical target for the clinical treatment of cPE induced fibrosis.

Obesity inhibits the osteogenic differentiation of human adipose-derived stem cells.

BACKGROUND: Craniomaxillofacial defects secondary to trauma, tumor resection, or congenital malformations are frequent unmet challenges, due to suboptimal alloplastic options and limited autologous tissues such as bone. Significant advances have been made in the application of adipose-derived stem/stromal cells (ASCs) in the pre-clinical and clinical settings as a cell source for tissue engineering approaches. To fully realize the translational potential of ASCs, the identification of optimal donors for ASCs will ensure the successful implementation of these cells for tissue engineering approaches. In the current study, the impact of obesity on the osteogenic differentiation of ASCs was investigated. METHODS: ASCs isolated from lean donors (body mass index <25; lnASCs) and obese donors (body mass index >30; obASCs) were induced with osteogenic differentiation medium as monolayers in an estrogen-depleted culture system and on three-dimensional scaffolds. Critical size calvarial defects were generated in male nude mice and treated with scaffolds implanted with lnASCs or obASCs. RESULTS: lnASCs demonstrated enhanced osteogenic differentiation in monolayer culture system, on three-dimensional scaffolds, and for the treatment of calvarial defects, whereas obASCs were unable to induce similar levels of osteogenic differentiation in vitro and in vivo. Gene expression analysis of lnASCs and obASCs during osteogenic differentiation demonstrated higher levels of osteogenic genes in lnASCs compared to obASCs. CONCLUSION: Collectively, these results indicate that obesity reduces the osteogenic differentiation capacity of ASCs such that they may have a limited suitability as a cell source for tissue engineering.

Evaluation of the host immune response to decellularized lung scaffolds derived from α-Gal knockout pigs in a non-human primate model.

Whole organ tissue engineering is a promising approach to address organ shortages in many applications, including lung transplantation for patients with chronic pulmonary disease. Engineered lungs may be derived from animal sources after removing cellular content, exposing the extracellular matrix to serve as a scaffold for recellularization with human cells. However, the use of xenogeneic tissue sources in human transplantation raises concerns due to the presence of the antigenic Gal epitope. In the present study, lungs from wild type or α-Gal knockout pigs were harvested, decellularized, and implanted subcutaneously in a non-human primate model to evaluate the host immune response. The decellularized porcine implants were compared to a sham surgery control, as well as native porcine and decellularized macaque lung implants. The results demonstrated differential profiles of circulating and infiltrating immune cell subsets and histological outcomes depending on the implanted tissue source. Upon implantation, the decellularized α-Gal knockout lung constructs performed similarly to the decellularized wild type lung constructs. However, upon re-implantation into a chronic exposure model, the decellularized wild type lung constructs resulted in a greater proportion of infiltrating CD45+ cells, including CD3+ and CD8+ cytotoxic T-cells, likely mediated by an increase in production of Gal-specific antibodies. The results suggest that removal of the Gal epitope can potentially reduce adverse inflammatory reactions associated with chronic exposure to engineered organs containing xenogeneic components.