Regulatory Macrophages Inhibit Alternative Macrophage Activation and Attenuate Pathology Associated with Fibrosis.

Diversity and plasticity are the hallmarks of macrophages. The two most well-defined macrophage subsets are the classically activated macrophages (CAMϕs) and the IL-4-derived alternatively activated macrophages (AAMϕs). Through a series of studies, we previously identified and characterized a distinct population of macrophages with immunoregulatory functions, collectively termed regulatory macrophages (RMϕs). Although considerable advances have been made in understanding these various macrophage subsets, it is not known whether macrophages of one activation state can influence the other. In this study, we examined whether RMϕs capable of inhibiting inflammatory responses of CAMϕs could also inhibit AAMϕs and their profibrotic responses. Our results demonstrated that RMϕs significantly dampened the alternate activation phenotype of AAMϕs generated in vitro and intrinsically occurring AAMϕs from TACI-/- macrophages. Further, RMϕs inhibited AAMϕ-promoted arginase activity and fibroblast proliferation in vitro. This inhibition occurred regardless of the strength, duration, and mode of alternative activation and was only partially dependent on IL-10. In the chlorhexidine gluconate-induced peritoneal fibrosis model, AAMϕs worsened the fibrosis, but RMϕs rescued mice from AAMϕ-mediated pathological conditions. Taken together, our study demonstrates that RMϕs are a specialized subset of macrophages with a nonredundant role in limiting overt proregenerative functions of AAMϕs, a role distinct from their well-defined role of suppression of inflammatory responses by CAMϕs.

Antiviral Efficacy Testing of a Rechargeable Textile.

INTRODUCTION: In light of the COVID-19 (Coronovirus Disease 2019) pandemic, the use of personal protective equipment has become essential to reduce viral transmission and maintain public health. Viruses, particularly human coronavirus and influenza, pose significant challenges because of their various transmission routes. UMF Corporation's innovation, Micrillon, aims to address these challenges by creating durable, antiviral technology for textiles without harmful chemicals, reducing viral transmission risks. MATERIALS AND METHODS: The study followed ISO Standard 18184:2019, testing Micrillon textiles against Human Coronavirus OC43 and H1N1 Influenza A virus using MDCK and HCT-8 cell lines. Cell propagation, viral application, TCID50 (Median Tissue Culture Infectious Dose) testing, and maintenance protocols were rigorously implemented to assess antiviral efficacy. RESULTS: Micrillon gloves, fabrics, and fibers exhibited high antiviral efficacy against both viruses across various contact times. Gloves demonstrated exceptional antiviral activity against H1N1 (99.88%) and OC43 (99.67%) at 120 minutes. Rolled fabrics showed strong efficacy against H1N1 (99.42% at 30 minutes) and OC43 (>97%) at all time points. Bundled fibers displayed substantial efficacy against H1N1 (99.17% at 120 minutes) and OC43 (>98%) at all time points. CONCLUSIONS: The study demonstrates that Micrillon technology effectively inhibits viral activity, particularly in gloves, fabrics, and fibers. The innovation not only shows high antiviral efficacy against both Human Coronavirus and Influenza but also promises a reusable, sustainable solution, mitigating environmental impact and reducing the use of harmful chemicals in personal protective equipment. The technology holds promise for widespread use in health care and hospitality, offering a layer of protection while being environmentally conscious. Further development of such technologies can significantly reduce infection risks while minimizing environmental harm.

Key features of the innate immune response is mediated by the immunoproteasome in microglia.

Microglia are the resident immune cells of the central nervous system (CNS). We and others have shown that the inflammatory response of microglia is partially regulated by the immunoproteasome, an inducible form of the proteasome responsible for the generation of major histocompatibility complex (MHC) class I epitopes. While the role of the proteasome in the adaptive immune system is well established, emerging evidence suggests the immunoproteasome may have discrete functions in the innate immune response. Here, we show that inhibiting the immunoproteasome reduces the IFNγ-dependent induction of complement activator C1q, suppresses phagocytosis, and alters the cytokine expression profile in a microglial cell line and microglia derived from human inducible pluripotent stem cells. Moreover, we show that the immunoproteasome regulates the degradation of IκBα, a modulator of NF-κB signaling. Finally, we demonstrate that NADH prevents induction of the immunoproteasome, representing a potential pathway to suppress immunoproteasome-dependent immune responses.