Traumatic injury, stenosis, and malignancy involving large segments of the airway are difficult to reconstruct and require novel solutions. Despite advances in surgical techniques, the reconstruction of long-segment tracheal defects remains a significant challenge. Several bioengineering approaches have been explored for tracheal regeneration in vitro and in vivo, using cells in combination with three dimentional (3D) biological or synthetic scaffolds. This paper reviews recent advances in developing bioengineered trachea and the technologies utilized toward generating transplantable tracheal grafts. Specifically, the review will focus on the recellularization of tissue-engineered grafts using natural or synthetic scaffolds, highlighting relevant cell types used to reconstitute tracheal epithelium and cartilage. The promise of newly explored paradigms, including the application of pluripotent stem cells, will be discussed with an overview of associated challenges and necessary steps for future translation. Overall, these advances provide a foundation for the development of clinically viable tracheal grafts, bringing engineered tracheal reconstruction closer to reality.

Cartilage regeneration remains an unmet clinical challenge. Despite the great advances in the production of hydrogels as support matrices for cartilage regeneration, the resulting mechanical properties remain low. Granular composite hydrogels appear as ideal candidates due to their injectability and modularity in design. Here, we report on the fabrication and characterization of heterogeneous composite granular hydrogels based on methacrylated chitosan (CHIMA) and gelatin (GelMA) microparticles supported by an interstitial methacrylated alginate (ALMA) matrix. Microparticles were prepared by an oil-emulsion method and their size and morphology optimized, resulting in CHIMA and GelMA microparticles of 10.8 µm (95% CI 9.2, 13.1) and 115.8 µm (95% CI 107.5, 137.6) in diameter, respectively. The microparticles were mixed with ALMA and crosslinked to form granular hydrogels that demonstrated reduced swelling and weight loss. The storage modulus increased from 33 to 66.4 kPa for CHIMA/ALMA hydrogels and from 11.5 to 19.5 kPa for GelMA/ALMA hydrogels when the particle concentration increased from 10 to 50%, and was higher than traditional ALMA hydrogels. Hydrogels of 50:50 CHIMA:GelMA permitted a 6.6-fold increase in cell number after 28 days of culture, and promoted the chondrogenic differentiation of embedded mouse mesenchymal stem cells with a glycosaminoglycan deposition of over 15 µg and the expression of chondrogenic markers.

Rheumatoid arthritis (RA) is a chronic autoimmune rheumatic disease of unknown etiolgy, characterized by erosive polyarthritis that leads to joint destruction and systemic inflammatory lesions in internal organs. Pain is a primary symptom of RA and a major contributor to psychological disturbances, which influence patients' subjective evaluation of their condition. These psychological issues may stem from disruptions in central pain regulation mechanisms, such as central sensitization (CS), which can also affect central metabolic processes. The objective was to investigate how the severity of central sensitization, measured by the Central Sensitization Inventory (CSI) questionnaire (Part 1), impacts clinical and neuropsychiatric parameters, as well as the expression of genes related to inflammation, tissue destruction, carbohydrate metabolism, and fatty acid metabolism in peripheral blood mononuclear cells (PBMCs) in patients with RA. Methods involved collecting blood samples from 59 RA patients (mean age 52.0 years). Clinical status was assessed using the DAS28 index and serum levels of CRP, ASPA, and RF. Neuropsychiatric parameters were evaluated through questionnaires measuring CS severity score (CSI), pain intensity (VAS, BPI), neuropathic pain (PainDETECT), anxiety and depression (HADS), fatigue (FSS, FACIT-F), fibromyalgia symptoms (FIRST), and pain catastrophizing. Protein expression in PBMCs was measured by ELISA, while gene expression was analyzed using quantitative real-time RT-PCR. All patients exhibited moderate to high disease activity. Participants were divided into four subgroups according to their CSI scores: subclinical (0-29 points), mild (30-39 points), moderate (40-49 points), and severe/extreme (50-100 points). Higher CSI scores correlated with significant increases in neuropsychiatric symptoms and a notable decrease in vitality. However, clinical parameters showed no significant differences among the subgroups. Gene expression analysis revealed upregulation of genes involved in the pentose phosphate pathway (G6PD), antioxidant defense (SOD1), fatty acid metabolism (FASN, CPT1B), apoptosis (CASP3), and tissue destruction and hypernociception (MMP-9) compared to healthy controls. The pro-inflammatory cytokine IL-1β expression was comparable to controls, while TNFα expression was elevated only in patients with severe/extreme CS scores. These findings suggest that CS-related disturbances may contribute to increased disease severity in RA, even in patients receiving active antirheumatic treatment. At the cellular level, disease severity appears linked to dysregulated expression of genes governing central metabolic processes, despite low expression of pro-inflammatory cytokine genes.

Respiratory syncytial virus (RSV), a member of the genus Orthopneumovirus, is an etiological agent in infant lower respiratory tract infections (LRTIs) producing substantial global morbidity. Here, secretoglobin (Scgb1a1)-derived progenitors play a primary role in triggering innate, inflammatory, and cell state transitions in response to RSV LRTIs. Whether RSV activation of innate signaling in this epithelial sentinel population leads to chronic airway disease is unknown. To understand the role of innate signaling in Scgb1a1-derived progenitors, a model of RSV post-viral disease (PVLD) was developed and studied in the presence or absence of RelA conditional knockout (CKO). Single-cell RNA sequencing (scRNA-seq) studies showed that RSV-PVLD induced a transition of atypical, differentiation-intermediate, alveolar type 2 (aAT2) cells characterized by tumor protein 63 (TRP63), aquaporin 3 (AQP3), and Itgβ4 expression, as well as changes in PDGFRβ mesenchyme. A single-cell trajectory analysis and lineage-tracing experiments using Scgb1a1 CreERTM X mTmG mice demonstrated that the Scgb1a1+ populations were precursors to the aAT2 population. Mechanistically, we found that the formation of the aAT2 population was prevented by RelA CKO. A differential gene expression analysis revealed that RSV-PVLD coordinately upregulates nuclear receptor subfamily 1 group D (Nr1d1/2), clock and basic helix-loop-helix ARNT-like 1 (Bmal) genes both in the aAT2 cell and in its Pdgfrα+ mesenchymal niche in a RelA-dependent manner. A systematic analysis of intercellular epithelial-mesenchymal communication in the scRNA-seq data showed that the clock-dysregulated epithelial-mesenchymal niche produces aberrant ANGPTL4 expression. ANGPTL4 upregulation was confirmed by the measurement of both its mRNA and protein. Moreover, ANGPTL4 is biologically active in the BALF of RSV-PVLD mice, inhibiting lipoprotein lipase activity. We conclude that RSV-PVLD is mediated, at least in part, by RelA signaling in Scgb1a1-derived epithelial progenitors, dysregulating ANGPTL4 signaling in an epithelial-mesenchymal niche, resulting in persistence of atypical alveolar epithelial cells with dysregulated of clock gene expression.

7-ketocholesterol (7-KC) is a bioactive oxysterol generated under oxidative stress and may contribute to bone marrow niche reprogramming in acute myeloid leukemia (AML), thereby promoting stress tolerance and therapeutic resistance Bone marrow mesenchymal stromal cells (MSCs) from healthy donors and AML patients were exposed to subtoxic 7-KC concentrations for 24 h. We evaluated the ABC transporters involved in lipid transport, multidrug resistance and membrane microdomain remodeling; Hedgehog pathway proteins; stress-survival signaling; redox balance by glutathione measurements, and mitochondrial function and dynamics, including membrane potential and gene expression of mitochondrial fission and fusion regulators. Results were integrated using principal component analysis (PCA), heatmaps, and correlation-based networks. Multivariate analyses revealed an integrated, lineage-dependent response. Healthy donor MSCs showed greater plasticity of the efflux and microdomain axis and higher oxidative and mitochondrial vulnerability at high 7-KC doses. AML-MSCs exhibited a basal preconditioned state phenotype and preferentially routed the response toward Hedgehog and stress-survival modules, accompanied by glutathione expansion and adaptive mitochondrial remodeling. 7-KC acts as a broad modulator of several MSC functions, linking sterol homeostasis to Hedgehog signaling, stress-survival pathways, redox balance, and mitochondrial remodeling, potentially supporting a pro-survival, more therapy-tolerant leukemic niche.

Advanced-stage ovarian cancer remains a major clinical challenge because of its aggressive behavior and the frequent development of chemoresistance. The nuclear factor erythroid-derived 2-like 2 (NRF2) signaling pathway regulates cellular redox homeostasis. However, its role in ovarian cancer stem-like cells remains unclear. Therefore, we aimed to investigate the effects of NRF2 overexpression on acetaldehyde dehydrogenase (ALDH)+ KURAMOCHI ovarian cancer cells in vitro and in vivo. In particular, we investigated the effects of NRF2 on tumor-associated behaviors, chemoresistance, and signaling pathways. Lentivirus-mediated NRF2 overexpression activated extracellular signal-regulated kinase and AKT signaling. Moreover, it modulated tumor-associated phenotypes, including proliferation, migration, and invasion. NRF2-overexpressing cells exhibited significantly enhanced migratory and invasive capacities, increased resistance to paclitaxel and carboplatin, and reduced apoptosis. Furthermore, the expression of anti-apoptotic proteins was upregulated, and caspase-3 activation was attenuated. In xenograft models, NRF2 overexpression promoted tumor growth and increased the expression of antioxidant and angiogenic factors, including heme oxygenase-1 and vascular endothelial growth factor A. Collectively, these findings demonstrate that NRF2 regulates ovarian cancer aggressiveness and chemoresistance by coordinating stress response signaling, survival pathways, and tumor progression. Therefore, targeting NRF2-mediated signaling represents a promising therapeutic strategy for overcoming drug resistance and improving outcomes in patients with ovarian cancer.

Stem cells, also known as progenitor cells, can differentiate into specialized cells for specific tissues. Genetic mutations and epigenetic changes may cause normal stem cells to become cancer-initiating cells. Research indicates that cells acquiring a mutation for myeloproliferative neoplasm (MPN) are likely to be long-term hematopoietic stem cells (LT-HSCs) at the top of the hematopoietic hierarchy. Natural killer (NK) cells play a crucial role in combating cancer by targeting and eliminating cancer stem cells (CSCs) while promoting their maturation. NK cells do this through direct lysis of CSCs or by releasing cytokines like interferon-gamma (IFN-γ) and tumor necrosis factor-alpha (TNF-α), which inhibit tumor growth and metastasis by driving differentiation of CSCs. Interleukin-2 (IL-2) enhances the activity of CD4+ and CD8+ T cells and boosts NK cell cytotoxicity. This study highlights a case of MPN with a more clinically aggressive Type 1 calreticulin (CALR) mutation, where a combination of low-dose IL-2 immunotherapy and targeted therapy with oral tretinoin (all-trans retinoic acid, ATRA, a vitamin A derivative) improved immune cells, particularly NK-cell-mediated destruction of malignant cells, reduced CALR mutation levels to undetectable, and alleviated disease symptoms. The aim is to offer a new, low-toxicity personalized treatment strategy that eradicates cancer-initiating stem cells, reduces side effects, and provides an option for patients with limited conventional therapy alternatives.

(1) Heterotopic ossification (HO) is a pathological process characterized by ectopic bone formation in soft tissues, often following trauma or neurological injury, and is associated with spasticity and chronic inflammation. Mesenchymal stem cells (MSCs) play a central role in HO by differentiating into osteoblasts through endochondral or intramembranous ossification, while alternative fates such as adipogenesis are suppressed. In this study, we investigated the effects of two commonly used antispastic drugs, baclofen and tizanidine, on MSC differentiation under adipogenic and inflammatory conditions in vitro. (2) Mouse C3H10T1/2 MSCs were cultured and induced toward adipogenesis in the presence of baclofen or tizanidine, and inflammatory stimuli (Interleukin-1β or lipopolysaccharides) were applied where indicated. Gene expressions of adipogenic and osteochondrogenic markers were assessed by RT-qPCR, while osteopontin protein levels were quantified by Simple Western. (3) Baclofen treatment significantly inhibited adipogenic gene expression and promoted osteochondrogenic markers and osteopontin protein under basal conditions, whereas tizanidine had minimal effects. Under inflammatory conditions, baclofen partially suppressed adipogenesis but did not strongly induce osteochondrogenesis. (4) These findings indicate that baclofen can directly modulate MSC fate, potentially contributing to HO risk, while tizanidine may offer a safer alternative for spasticity management in patients at risk of ectopic bone formation.

The α-gal epitope is synthesized in non-primate mammals and New-World monkeys by the glycosylation enzyme α1,3galactosyltransferase (α1,3GT), encoded by the GGTA1 gene. Ancestral Old-World monkeys and apes synthesizing α-gal epitopes underwent extinction 20-30 million years ago. Their mutated offspring, with the inactivated GGTA1 gene, survived and produced the natural anti-Gal antibody, specifically binding α-gal epitopes. Anti-Gal protected the surviving offspring from lethal viruses presenting α-gal epitopes, which killed α-gal-synthesizing parental primates. Anti-Gal constitutes ~1% of human immunoglobulins and is also produced in Old-World monkeys and apes. α-Gal epitopes can serve as therapeutic agents in several clinical disciplines: 1. Cancer immunotherapy: Engineering cancer cells to express α-gal epitopes results in anti-Gal binding to these cells and localized activation of the complement system that kills these cancer cells and recruits the antigen-presenting cells (APCs) dendritic cells and macrophages. Anti-Gal bound to cancer cells targets them for robust uptake by APCs, which process internalized tumor antigens (TAs) and transport them to lymph nodes for activation of cytotoxic T-cells. These T-cells kill TA-presenting metastatic tumor cells. Clinical trials demonstrated that such engineering is achieved by intra-tumoral injection of α-gal glycolipids, the use of recombinant α1,3GT, or the use of oncolytic viruses containing the GGTA1 gene. 2. Viral vaccines: Inactivated whole-virus vaccines presenting α-gal epitopes bind anti-Gal, which targets them for extensive uptake by APCs, thereby increasing their immunogenicity by ~100-fold. 3. Injured-tissue regeneration: Anti-Gal binding to α-gal-presenting nanoparticles administered to wounds, into the post-myocardial infarction (MI) injured myocardium and into injured spinal cord, activates the complement system that recruits pro-regenerative macrophages, which orchestrate regeneration by recruiting stem cells and the secretion of pro-regenerative cytokines. All these findings suggest that α-gal/anti-Gal antibody interaction can serve as a novel therapeutic approach, applicable to various clinical settings.

Liver fibrosis is a regenerative mechanism, but it pathologically intensifies in the course of various diseases, leading to progressive impairment of organ function. This process involves parenchymal cells (hepatocytes) and non-parenchymal cells (Kupffer cells, stellate cells, and endothelial cells). Its classic mechanism is based on the activation of stellate cells, the main effector of fibrosis, by transforming growth factor β (TGF-β), which stimulates excessive collagen production. The role of interleukin 13 (IL-13), which enters the liver parenchyma from resident lymphoid cells, seems to be equally important. By binding to the IL-13Rα receptor on stellate cells, IL-13 initiates their activation and increases the production of type I collagen. This process is supported by the Erk1/2 pathway, which induces the expression of genes promoting extracellular matrix deposition. Due to its role as an initiator of the fibrotic cascade, IL-13 represents a promising therapeutic target for inhibiting progressive scarring. In this context, cell therapies are considered to be of great importance. Mesenchymal and epithelial stem cell secretions contain, among others, exosomes that carry paracrine mediators that can inhibit the profibrotic effects of IL-13 by modulating IL-13 signalling, limiting the development of organ scarring. However, the data on clinical applications of this molecular pathway is scarce, as there are no significant studies focusing on IL-13 influence in liver fibrosis. This review emphasizes the lack of clear clinical data linking the beneficial effects of cell therapy with modulation of the IL-13 pathway, which highlights the need for such studies.

The immune microenvironment critically influences bone healing, particularly in the oral cavity where inflammation and microbial biofilms can compromise regeneration. Plant-derived extracellular vesicles (PDEVs) offer a biocompatible means to modulate immune responses, and apple-derived extracellular vesicles (ADEVs) have shown antioxidant and anti-inflammatory activity, although their osteoregenerative potential remains unclear. Here, we investigate the indirect effects of ADEVs on bone regeneration by assessing how their immunomodulatory action on macrophages influences the osteogenic commitment of human dental pulp stem cells (DPSCs). ADEVs were isolated, characterized, and applied to THP-1-derived macrophages to evaluate polarization via morphology and immunofluorescence for M1 (iNOS) and M2 (ARG1) markers. Then, the extracellular vesicles (EVs) from untreated and ADEV-treated macrophages were isolated and applied to DPSCs. All EVs were efficiently internalized by both macrophages and DPSCs. Treated macrophages shifted toward an M2-like phenotype, and macrophage-derived EVs (MDEVs) promoted stem cell morphological features consistent with osteogenic activation. These findings suggest that ADEVs promote osteoregeneration indirectly by influencing macrophage polarization and modifying the osteoactive cargo of MDEVs, thereby supporting their potential in cell-free, immunomodulatory approaches for oral bone regeneration.

We prospectively evaluated whether cytotoxic T-lymphocyte (CTL) activation and T-cell receptor (TCR) Vβ clonality predict treatment-free remission (TFR) after tyrosine kinase inhibitor (TKI) cessation in chronic-phase chronic myeloid leukemia (CML). Forty-five patients with sustained deep molecular response (DMR) were enrolled (On-TKI, n = 38; Off-TKI, n = 7) and underwent one-year immuno-monitoring from consent. The primary endpoint was 12-month TFR, defined as retention of MR4. Overall, 32/45 patients (71%) maintained TFR at 12 months. Longer TKI exposure and stable DMR were associated with TFR; notably, patients fulfilling "≥7 years of TKI plus ≥1 year of DMR" and exhibiting CTL activation features-CD8 > CD4, memory > effector, and/or highly activated CTL clones on TCR Vβ repertoire-showed the highest likelihood of durable TFR. By contrast, NK cells, effector Tregs, and G-/M-MDSCs did not discriminate TFR status in this cohort. Although antigen specificity against CML stem cells was not directly tested, the memory-dominant CTL phenotype is consistent with immune control after antigen reduction. These findings suggest that a simple, clinically accessible strategy based on flow cytometric CTL profiling and TCR Vβ clonality may help inform TKI discontinuation decisions in CML. External validation is warranted to confirm transportability and refine clinical thresholds.

Chemokine CXCL1, also known as Gro-α and MGSA, a ligand of CXCR2, is the best-known CXC chemokine in cancer processes, after CXCL8/IL-8 and CXCL12/SDF-1. This paper is the first review on the role of CXCL1 in general molecular processes associated with cancer. It provides a comprehensive overview that allows for an in-depth understanding of the importance of CXCL1 in tumor-related processes. In this review, however, we did not address the clinical aspects of CXCL1, as these were discussed in our previous review articles. The present paper focuses on the involvement of CXCL1 in cancer processes such as proliferation, cancer stem cell (CSC) function, senescence, angiogenesis, lymphangiogenesis, migration and metastasis, and effects on tumor-associated cells such as neutrophils, tumor-associated macrophages (TAMs), myeloid-derived suppressor cells (MDSCs), mesenchymal stem cells (MSCs), and cancer-associated fibroblasts (CAFs). It also describes the significance of CXCL1 in cancer-associated diseases such as cancer cachexia, cancer-associated immunodeficiency, neuroinflammatory-mediated affective-like behaviors, bone cancer pain, and acute kidney injury. We also present the effects of obesity on CXCL1-related cancer processes.

Triple-negative breast cancer (TNBC) lacks effective targeted therapies, and the mechanisms by which developmental endothelial locus-1 (EDIL3/Del-1) promotes TNBC remain incompletely defined. We profiled Del-1 and AMPK subunits in TNBC cell lines by RT-PCR and immunoblotting, performed functional assays in CRISPR/Cas9 Del-1 knockout and AMPKβ-manipulated cells, and evaluated AMPKβ in early-stage TNBC tumors using tissue microarrays (TMA) (immunohistochemistry; n = 100) and AMPKβ2 mRNA quantification. Del-1 and AMPKβ were enriched in TNBC cells, most prominently in the mesenchymal stem-like subtype, whereas AMPKα levels were relatively stable. Increased Del-1 and activated AMPKβ enhanced proliferation and invasion, while Del-1 deletion reduced AMPKβ expression and suppressed tumor-promoting phenotypes. Mechanistically, Del-1 increased AMPKβ phosphorylation at serine 108, and a phospho-mimetic AMPKβ mutant further amplified oncogenic effects. In the pilot TMA study, high AMPKβ protein expression showed a trend toward poorer DFS in Kaplan-Meier analysis, while multivariate analysis identified high AMPKβ protein expression as an independent factor associated with poorer DFS in patients with early TNBC. These data support AMPKβ as a key mediator of Del-1-driven signaling and suggest AMPKβ could be a therapeutic target in aggressive TNBC subsets.

Retinoblastoma (Rb) is an intraocular tumor caused by genetic alterations in the RB1 and MYCN genes within developing retinal cells. Chemoresistance and metastasis are major challenges for treatment, with the bone marrow (BM) representing the most common metastatic site. We investigated the effect of tumor-derived sEVs (TDsEVs) on the crosstalk between metastatic site cells (BM-derived mesenchymal stem cells (BM-MSC)) and tumor cells, and characterized them according to MISEV guidelines. The uptake of sEVs and the associated phenotypic changes in the BM-MSCs were analyzed with confocal microcopy. The functional effects were assessed through MTT assays for viability, scratch and Transwell assays for migration, and colony- and sphere-formation assays to evaluate clonogenicity and self-renewal, while stemness marker expression was examined by immunoblotting. Secretome changes following sEV exposure were analyzed using dot blot assays. sEVs were taken up by both cells. TD-sEVs significantly enhanced BM-MSC migration and induced differentiation into a myofibroblast-like phenotype without affecting cell viability. Conversely, BM-MSC-derived sEVs promoted tumor cell viability, migration, and stemness marker expression. Both the BM-MSCs and tumor cells exhibited altered secretory profiles after sEV treatment. The in vitro findings provide cumulative evidence that sEV-mediated interactions contribute to a tumor-supportive milieu or premetastatic niche at the BM in Rb.

Leucine-rich repeat-containing 8A (LRRC8A; also known as SWELL1), the essential subunit of volume-regulated anion channels (VRACs), is amplified in multiple malignancies and has been implicated in tumor progression and therapeutic resistance. Three-dimensional (3D) cancer spheroids have been well-established as in vitro models that recapitulate characteristics of tumor stemness and intrinsic drug resistance. In the present study, spheroid formation in human breast cancer cell lines, YMB-1 and MDA-MB-468, conferred resistance to multiple anticancer drugs, including doxorubicin (DOX), gemcitabine (GEM), and 5-fluorouracil (5-FU), thereby mimicking the characteristic properties of breast cancer stem-like cells. LRRC8A expression was upregulated in 3D spheroids compared with adherent 2D monolayers, and its pharmacological inhibition induced membrane hyperpolarization accompanied by intracellular Cl- accumulation. Inhibition of LRRC8A significantly sensitized spheroids to DOX, GEM, and 5-FU. Spheroid formation increased the expression of multidrug resistance-related protein 3 (MRP3) and the drug-metabolizing enzyme cytochrome P450 3A4 (CYP3A4), whereas LRRC8A inhibition suppressed their expression. The transcriptional upregulation of MRP3 and CYP3A4 was mediated through the NRF2-CEBPB/D transcriptional axis. Collectively, these findings suggest that LRRC8A inhibition may represent a therapeutic strategy to overcome chemoresistance by repressing MRP3 and/or CYP3A4 expression in breast cancer stem cells.

The maturation of induced pluripotent stem cell-derived cardiomyocytes (iPSC-CMs) remains a major translational bottleneck in regenerative cardiac medicine, as current differentiation platforms yield electrophysiologically and metabolically immature phenotypes. This review explores emerging strategies to engineer "smart" biomaterial interfaces that actively instruct iPSC-CM maturation through synergistic biophysical and metabolic reprogramming. By integrating nanotopographical patterning, mechanoelectric coupling, and tunable substrate stiffness with metabolic interventions such as mitochondrial substrate optimization and fatty acid oxidation induction, the literature reveals consistent links between cell-matrix crosstalk, sarcomeric organization, calcium handling, and oxidative metabolism. Recent advances in bioactive scaffolds and extracellular vesicle (EV)-functionalized hydrogels are highlighted as platforms capable of approximating key features of the myocardium's native electromechanical and bioenergetic environment. Across two- and three-dimensional culture systems, this review identifies recurring maturation patterns, persistent gaps in metric standardization and long-term phenotype stability, and ongoing limitations related to scalability and translational implementation. Collectively, the findings synthesized here indicate that convergence between biomaterial engineering and metabolic programming represents a critical design principle for advancing iPSC-CMs toward functionally mature, clinically relevant phenotypes. This integrated approach enhances the fidelity of iPSC-CMs for disease modeling, drug screening, and regenerative cardiac therapies.

Ultraviolet (UV) radiation induces DNA damage and oxidative stress in melanocytes, shaping pigmentation phenotypes and elevating photocarcinogenesis risk. Human models that capture donor-linked genetic determinants of UV sensitivity remain limited. Here, we establish a genotype-informed UV response model using induced pluripotent stem cell (iPSC)-derived melanocytes from donors carrying defined MC1R variants. Differentiated cells recapitulated melanocytic morphology, marker expression, and pigmentation consistent with donor sun-sensitivity traits. Following narrowband UVB exposure, melanocyte lines with higher UV sensitivity showed reduced survival, prolonged checkpoint activation, and CPD-associated DNA damage signaling dynamics. Mechanistic analysis suggests that the interferon-regulated GTPase MX2 is associated with amplification of UV-induced p53 and p38 activation while promoting apoptosis independently of AKT. These findings support MX2 as a physiological enhancer of DNA damage signaling in normal melanocytes, distinct from its interferon-mediated role in melanoma. Our study provides a human-relevant platform linking pigmentation genotype to UV resilience and supports iPSC-derived systems as new approach methodologies (NAMs) for mechanistic and translational phototoxicology.

Copper-based nanoparticles (Cu-based NPs) represent a major focus in nanomedicine due to their unique physicochemical properties and excellent biocompatibility. In this paper, we present an interdisciplinary study bridging engineering and biomedical sciences by employing a novel synthesis approach to produce highly stable and uniformly dispersed spherical copper nanoparticles (CuNPs), which were subsequently tested for their cytotoxic effects on SKBR3 and MSC human cells. The synthesis of CuNPs was performed in the presence of the complexing agent trisodium citrate (TSC), while starch was used for the chemical reduction step. Characterization of the Cu-based NPs via UV-Vis, FT-IR, Mie theory, DLS and SEM confirmed their nanoscale structure. The obtained CuNPs were subsequently assessed for their biological effects and cytotoxic responses induced in normal and SKBR3 cancer cell lines. The SKBR3 cell line showed a dose-dependent decrease in the cell index and a higher proportion of apoptotic cells compared to normal MSCs, with apoptosis representing the dominant mode of cell death. Although SKBR3 cells appeared to mount an antioxidant response against CuNP oxidative stress, the response was insufficient to counteract the apoptotic progression. In comparison, MSCs showed a greater resilience to CuNP-induced cellular stress. By promoting oxidative stress and disrupting the antioxidant defense system of cancer cells, CuNPs exhibit promising anti-cancer properties.

Glioblastoma (GBM) is an aggressive brain tumour known for its ability to resist the current treatment protocols. A major reason for this resistance is a minor group of cells within the tumour called glioblastoma stem cells (GSCs). These cells drive tumour growth, invasion, and recurrence after therapy. GSCs survive and expand within a specific microenvironment that protects and supports them. Three of the most important niches are: hypoxic (low oxygen) regions, which trigger survival pathways and make GSCs more resistant to treatment; perivascular areas near blood vessels, which provide nutrients and signals that maintain stem-like properties; and immune-related zones, where inflammatory and suppressive signals help GSCs escape the body's defences. Together, these environments allow GSCs to thrive and contribute to the tumour's persistence. This review highlights how hypoxia, blood vessel niches, and immune interactions work together to sustain GSCs and promote GBM progression. A clearer understanding of these supportive environments may lead to new treatment approaches aimed at disrupting GSC survival and improving patient outcomes.