Optimizing a five-factor cocktail to prepare reparative macrophages for wound healing.

The treatment of non-healing wounds, such as diabetic ulcers, remains a critical clinical challenge. Recent breakthroughs in cell therapy have shown great promise, with one primary focus on preparing cells with comprehensive reparative functions and foreseeable safety. In our previous study, we recapitulated the pro-regenerative and immunosuppressive functions of tumor-associated macrophages (TAMs) in non-tumor-derived macrophages, endowing the latter with characteristics for promoting diabetic wound healing - termed TAMs-educated macrophages (TAMEMs). To eliminate the use of tumor-derived sources and devise a more controllable method to prepare TAMEM-like cells, in this study, we identify a cocktail comprising five recombinant proteins as an essential condition to induce non-polarized macrophages (termed TAMEMs5) into therapeutic cells with pro-healing functions. The screened five factors are osteopontin (OPN), macrophage inflammatory protein (MIP)-2, chemokine (C-C motif) ligand 8 (CCL8), vascular endothelial growth factor (VEGF)-B, and macrophage colony-stimulating factor (M-CSF). We demonstrate the rationale for screening these factors and the phenotype of TAMEMs5 prepared from murine bone marrow-derived macrophages, which exhibit angiogenic and immunomodulatory effects in vitro. Then, we induce primary human monocytes from periphery blood into TAMEMs5, which show pro-healing effects in a human primary cell-based ex vivo model (T-SkinTM). Our study demonstrates a simple, effective, and controllable approach to induce primary macrophages to possess repairing activities, which may provide insights for developing cell-based therapeutics for non-healing wounds clinically.

Differential Foreign Body Reactions between Branched and Linear Glucomannan Scaffolds.

The extent and patterns of foreign body reaction (FBR) influence the function and feasibility of biomaterials. Polysaccharides, as an important biomaterial category, have received increasing attention in diverse biomaterials design and biomedical applications due to their excellent polymeric and biocompatible characteristics. Their biological effects are usually associated with their monosaccharide composition or functional groups, yet the contribution of their glycan structure is still unknown. Herein, two glucomannans, similar in composition and molecular weight with differences in glycan structure, linear-chain (Konjac glucomannan, KGM), and branched-chain (Bletilla striata polysaccharide, BSP), were adopted to explore the host-biomaterials interaction. After acetyl modification, these polysaccharides were fabricated into electrospun scaffolds to reduce the impacts derived from the physical properties and surface morphology. According to a systematic study of their biological effects on immune cells and host response in a subcutaneous implantation model in vivo, it was revealed that acetyl KGM (acKGM) scaffolds caused a stronger FBR than acetyl BSP materials. Additionally, acKGM could stimulate macrophages to release pro-inflammatory cytokines, suggesting the influence of sugar chain arrangement on FBR and providing clues for the fine regulation of immune response and novel biomaterials design.