Cells

Electronic cigarettes (ECs) are promoted as a safer alternative to traditional cigarettes, yet their impact on immune cells remains incompletely understood. This study investigates the activation of human primary adherent and non-adherent monocytes exposed ex vivo to aerosols from four flavored ECs (classic tobacco, menthol, watermelon, and strawberry) compared to cigarette smoke (CS) and nicotine alone. EC aerosols (ECEs) induced modest cytotoxicity, oxidative stress, and superoxide dismutase activity compared to CS, with high cell response heterogeneity indicating subpopulation-specific effects. Adherent monocytes showed elevated integrin expression (CD11a, CD11b), ICAM-1 (CD54), TNFα, and oxidative stress versus non-adherent cells, amplified by ECE. Dual fluorescence flow cytometry (green DCF for ROS and red for anti-TNFα Ab) revealed shifts toward pro-inflammatory/oxidative quadrants, particularly upper-right high-intensity relatively small subsets with macrophage M1-like CD68 expression in adherent cells. ECEs reduced phagocytosis in adherent monocytes, mimicking CS effects, probably driven by non-nicotine components. Strawberry flavor (ECE 4) elicited the strongest TNFα induction. These findings demonstrate EC-induced subclinical inflammation via selective monocyte activation, potentially contributing to chronic cardiopulmonary risks despite significantly lower overall toxicity than CS.

Marrow-isolated adult multilineage inducible (MIAMI) cells are a subpopulation of mesenchymal stem/stromal cells (MSC) with enhanced self-renewal, multilineage plasticity, and anti-inflammatory properties, suggesting that their extracellular vesicles (MIA-EVs) may confer advantages over conventional MSC-EVs. MIAMI cells were transcriptionally profiled and expressed regenerative markers, including PDGFRB, CDX2, and TERT. We report the first successful isolation and characterization of MIA-EVs. EVs were isolated by ultracentrifugation and characterized by nanoparticle tracking analysis, transmission electron microscopy, flow cytometry, and surface markers. Cargo analysis identified growth factors (IGFBP-1, HGF, VEGF-D) and 19 highly expressed miRNA targeting survival, regenerative, and immune regulatory pathways. MIA-EVs were efficiently internalized, enhanced keratinocyte wound closure and suppressed osteosarcoma proliferation in vitro. Conditioned MIA-EVs reshaped pathway weighting without altering core regulatory identity, as a conserved 15-miRNA backbone persisted across naïve, irradiated, and cytokine-primed states. In contrast, a 9-miRNA core shared with MSC-EVs defined a basal mesenchymal framework, while MIA-EVs expanded regenerative, survival, and immune network connectivity. Similar to embryonic stem cell (ESC)-EVs, both MIA- and cytokine-primed EVs promoted M2 macrophage polarization, selectively upregulating IL1R2 and PPARG/STAT1, respectively. Meanwhile, MSC-EVs induced heterogeneous responses. These findings establish MIA-EVs as a conditioning-resistant, systems-regulated, cell-free platform with regenerative, immunomodulatory, and cytoprotective potential under hostile microenvironments.

Cancer immunotherapy has transformed modern oncology, yet durable responses remain limited for many patients due to immune exclusion, adaptive resistance, and tumor heterogeneity. Oncolytic viruses (OVs) have emerged as a novel class of immunotherapeutics that unify direct tumor cytolysis with stimulation of antitumor immunity. By inducing immunogenic cell death (ICD) and releasing tumor-associated antigens (TAAs), OVs remodel the tumor microenvironment (TME) into an inflamed and immune-permissive niche capable of enabling systemic immune activation. Rapid advances in viral engineering have strengthened the translational potential of OVs through tumor-selective gene deletions, tumor-specific promoters, microRNA-based detargeting, and receptor-retargeting strategies that collectively enhance safety, specificity, and intratumoral propagation. Next-generation OVs are increasingly “armed” with immunostimulatory payloads—including cytokines, chemokines, checkpoint inhibitors, bispecific T-cell engagers, and suicide gene systems—allowing localized immune modulation with reduced systemic toxicity. These innovations have propelled significant clinical progress, exemplified by the approvals of talimogene laherparepvec (T-VEC), G47Δ, and H101, and have driven a surge of combination trials integrating OVs with immune checkpoint blockade, adoptive cell therapies, radiotherapy, and targeted therapies to overcome multilayered tumor immune resistance. Despite this momentum, clinical implementation remains challenged by antiviral immunity, heterogeneous viral distribution, stromal barriers, and dynamic interferon (IFN) signaling in the TME. Emerging delivery approaches, including carrier cell systems, nanotechnology-enabled viral shielding, and synthetic virology platforms, offer promising solutions to these limitations. Oncolytic virotherapy is rapidly evolving into a multifunctional immunotherapeutic platform capable of reshaping antitumor responses at both local and systemic levels. By integrating advanced viral engineering with rational combination strategies and innovative delivery technologies, OVs hold substantial potential to overcome current barriers in cancer immunotherapy and advance precision oncology. Continued translational research will be essential to fully harness their therapeutic impact and broaden their clinical applicability.