Search Results (92)

Background/Objectives: Toothpaste ingredients such as strontium chloride (SrCl₂) and potassium carbonate (K₂CO₃) are recognized for their desensitizing and remineralizing effects but may be absorbed through the oral mucosa. Their potential cytotoxic and cardiotoxic properties, however, remain inadequately characterized. Here, we investigated the effects of SrCl₂ and K₂CO₃ on mouse-induced pluripotent stem cells (iPSCs) and iPSC-derived cardiomyocytes (iPSC-CMs). Methods: Cells were exposed to varying concentrations of each compound for up to 72 h. Real-time cell analysis (xCELLigence RTCA Cardio system) was used to assess proliferation, and flow cytometry was used to evaluate cell viability. Functional properties of iPSC-CMs were examined using multi-electrode array (MEA) recordings and xCELLigence-based impedance measurements. Cardiac marker expression was examined via immunofluorescence and quantitative RT-PCR. Results: Both SrCl₂ and K₂CO₃ affected iPSC proliferation and reduced viability in a dose- and time-dependent manner, accompanied by altered embryoid body (EB) morphology and increased cell death. In iPSC-CMs, both compounds downregulated key cardiac genes and disrupted spontaneous beating activity, with effects intensifying at higher concentrations. Conclusions: These results demonstrate that SrCl₂ and K₂CO₃ induced dose-dependent cytotoxic and arrhythmogenic effects on iPSCs and iPSC-CMs. At elevated concentrations, these compounds impair iPSC-CM function and may pose safety concerns upon chronic exposure. Further mechanistic and long-term in vivo studies are warranted to assess their potential cardiotoxic risk in consumer oral care products. Full article

While the biobased, fermentative production of succinate by Escherichia coli represents a sustainable alternative to its conventional synthesis from petroleum, this process requires substantial amounts of inorganic carbon (C_i) to support CO₂-fixing reactions in the reductive branch of the tricarboxylic acid (rTCA) cycle. Accordingly, intracellular C_i availability represents a potential limiting factor during E. coli succinate fermentations. Here, we first investigate the role and importance of E. coli’s native CO₂ concentrating mechanism (CCM)—comprising two carbonic anhydrases (CAs), Can and CynT—by comparing and contrasting the behaviors of wild-type E. coli and the engineered succinate-producing strain, KJ122. Deletion of can and cynT significantly impaired the aerobic growth of both strains under low CO₂ atmosphere and/or low pH, outcomes that were further exacerbated under anaerobic conditions for KJ122. During bioreactor fermentations, KJ122 Δcan ΔcynT further exhibited a prolonged lag phase (~48 h) and 44% reduced succinate production relative to KJ122 by 96 h. Next, the relative functions and performance of mechanistically diverse, heterologous CCM components were investigated by characterizing their ability to restore growth and/or succinate production. While the cyanobacterial bicarbonate transporter SbtA and the C_i transporter DabAB from Halothiobacillus neapolitanus each complemented growth at 0.05% CO₂ and pH 6.5–7.5, neither fully restored succinate production by KJ122 Δcan ΔcynT. Moreover, individual overexpression of sbtA, dabAB, or can in KJ122 rendered no additional improvements to succinate production. Collectively, while these results point to the critical importance of CA for supporting efficient fermentative succinate production by E. coli, they also suggest that this native CCM alone is sufficient for ensuring C_i acquisition at requisite levels under the conditions examined. Full article

Genomic instability not only drives tumor initiation and progression but also cooperates with apoptosis resistance to promote therapeutic evasion in hepatocellular carcinoma (HCC). Activation of MDM2, a negative regulator of p53, together with XIAP overexpression, represents a critical axis underlying this resistance. Simultaneous targeting of MDM2 and XIAP by MX69, a small molecule inhibitor, may therefore offer a potent interventional strategy to suppress cell proliferation and enhance pro-apoptotic signaling in HCC in vitro models. To evaluate the effects of MX69, cell viability was assessed via CVDK-8, colony formation, and real-time cell analysis. Oxidative stress levels and DNA damage were examined using fluorescence imaging and comet assays, respectively, while mitochondrial membrane potential was monitored through JC-1 staining. Furthermore, flow cytometry was employed to quantify apoptotic cell death and cell cycle distribution, while Western blot analysis was used to characterize the expression of apoptosis-related proteins. In vitro cytotoxicity assays revealed that MX69 reduced the viability of HUH7 and Hep3B cells in a dose-dependent manner, suppressed colony formation, and exerted anti-proliferative effects in real-time proliferation assays. Cell viability and IC50 values were evaluated using CVDK-8 and RTCA assays. Furthermore, MX69 induced oxidative stress and mitochondrial dysfunction, as evidenced by elevated ROS levels and loss of mitochondrial membrane potential. This was accompanied by significant DNA damage, detected by comet assay and γ-H2AX immunofluorescence, and G0–G1 cell cycle arrest. Moreover, MX69 triggered apoptotic cell death, demonstrating potent anticancer activity. Collectively, our findings identify MDM2/XIAP dual inhibition by MX69 as a promising therapeutic approach in HCC, with potential to overcome apoptosis resistance linked to genomic instability. Full article

The escalating global demand for large-scale, cost-effective, and sustainable high-quality protein has positioned single-cell protein (SCP) production from one-carbon (C1) gases as a highly promising solution. In this study, eight chemolithoautotrophic hydrogen-oxidizing bacteria (HOB) were isolated from mangrove sediments. Based on the 16S rRNA gene sequence analysis, they belonged to genera Sulfurimonas, Sulfurovum, Thiomicrolovo, and Marinobacterium. Among these, Thiomicrolovo sp. ZZH C-3 was identified as the most promising candidate for SCP production based on the highest biomass and protein content, and was selected for further characterization. Strain ZZH C-3 is a Gram-negative, short rod-shaped bacterium with multiple flagella. It can grow chemolithoautotrophically by using molecular hydrogen as an energy source and molecular oxygen as an electron acceptor. Genomic analysis further confirmed that ZZH C-3 harbors a complete reverse tricarboxylic acid (rTCA) cycle gene set for carbon fixation, and diverse hydrogenases (Group I, II, IV) for hydrogen oxidation. Subsequently, its cultivation conditions and medium composition for SCP production were systematically optimized using single-factor experiments and response surface methodology (RSM). Results showed that the optimal growth conditions were 28 °C, pH 7.0, and with 1 g/L (NH₄)₂SO₄ as the nitrogen source, 5–10% oxygen concentration, 9.70 mg/L FeSO₄·7H₂O, 0.17 g/L CaCl₂·2H₂O, and 1.90 mg/L MnSO₄·H₂O. Under the optimized conditions, strain ZZH C-3 achieved a maximum specific growth rate of 0.46 h⁻¹. After 28 h of cultivation, the optical density at 600 nm (OD₆₀₀) reached 0.94, corresponding to a biomass concentration of 0.60 g/L, and the protein content ranked at 73.56%. The biomass yield on hydrogen (Y_H2) was approximately 3.01 g/g H₂, with an average H₂-to-CO₂ consumption molar ratio of about 3.78. Compared to the model HOB Cupriavidus necator, strain ZZH C-3 exhibited a lower H₂/CO₂ consumption ratio, superior substrate conversion efficiency, and high protein content. Overall, this study not only validated the potential of mangrove HOB for SCP production but also offers new insights for future metabolic engineering strategies designed to enhance CO₂-to-biomass conversion efficiency. Full article

Fuel cells offer a promising route to eliminating in-flight emissions from regional aviation, but certification requires proof that stacks can withstand the vibration and shock environment of turboprop aircraft. As part of the EU-funded NEWBORN project, we combined detailed finite element modeling with shaker tests to evaluate the vibration immunity of PowerCell Group’s prototype stack. The numerical model combined an orthotropic, two-zone 3D mesh of the cell package with reduced-order representations of plates, compression bands, disc springs and the mounting cage. The assembled stack was excited between 10 and 300 Hz using pseudo-random and sine-sweep inputs up to 2.0 g, from which 54 frequency response functions were obtained. The tuned model accurately reproduced the first global modes and captured the overall dynamic behavior with good, though not perfect, agreement. The combined numerical–experimental methodology therefore offers a framework for refining test campaigns and delivering early, qualitative evidence of vibration immunity in fuel cell stacks destined for flight. Full article

The adrenocorticotropic hormone (ACTH) is a key regulator of adrenal cortex function, promoting glucocorticoid synthesis and modulating cell proliferation. However, the role of extracellular steroid availability in shaping ACTH responses is still not fully defined. In this study, the functional and transcriptomic effects of ACTH were investigated in primary rat adrenocortical cells cultured under standard conditions and under simulating serum starvation (charcoal-stripped serum). The cells were treated with ACTH (10 nM), and proliferation was monitored using xCELLigence RTCA, while corticosterone secretion was assessed via ELISA. The RNA extracted from these samples was then utilised for the purpose of microarray-based gene expression profiling. The present study revealed that charcoal-stripped serum markedly improved ACTH-induced corticosterone output, suggesting that the absence of endogenous steroids sensitises cells to ACTH stimulation possibly by removing negative feedback constraints. This enhanced steroidogenic response was accompanied by a significant suppression of proliferation, confirming that the stimulation of specialised functions (such as steroid secretion) reduces proliferative capacity of adrenocortical cells. Transcriptomic data revealed that the steroids stimulating effect on corticosterone output was mainly mediated via steroid biosynthetic and lipid metabolic processes while inhibitory effect on proliferation rate was mediated mainly by cell adhesion molecules. These results suggest that, in primary culture of rat adrenocortical cells, the stimulatory effect of ACTH on their specialised function (corticosteroid secretion) simultaneously reduces their basal function, which is their proliferation process. Changes in this type are also observed in cells cultured in steroid-depleted conditions. Full article

Breast cancer (BC) is the most frequently diagnosed malignancy in women worldwide. Despite therapeutic advances, disease relapse and metastasis remain major challenges and drivers of mortality. Fascin, an actin-bundling protein, promotes BC progression by enhancing drug resistance. However, the role of fascin in proliferation, a hallmark of cancer, and the underlying mechanism remain poorly elucidated. In this study, bioinformatics analysis of publicly available BC datasets, gene manipulation (gain and loss of function) in BC cell lines, flow cytometry, Western blots, and a real-time cell analyzer (RTCA) were employed to assess the role of fascin in proliferation. The clinical relevance of bioinformatics data and in vitro findings was assessed in BC patient samples using immunohistochemistry. FSCN1 expression exhibited a significant correlation with proliferation signature scores in BC datasets. Ectopic expression of fascin in fascin-negative SK-BR-3 and its silencing in fascin-positive MDA-MB-231 BC cell lines demonstrated its direct role in driving proliferation. In-depth bioinformatics analyses revealed a significant correlation between FSCN1 and the cell cycle signature score, particularly the G1-S signature score gene set. Indeed, fascin accelerated the cell cycle progression of synchronized cells from the G to S phase. Mechanistically, fascin upregulated nuclear SKP2 levels and reduced p27 expression—important G1-S cell cycle checkpoint regulators. Immunohistochemistry in samples from 68 patients demonstrated significant correlations between fascin and Ki-67 expression, in addition to SKP2 overexpression and p27 downregulation. Collectively, these data demonstrate the role of fascin as a driver of the G1-S-phase transition during cell cycle proliferation, thereby revealing new opportunities for targeted therapeutic intervention. Full article

Decabromodiphenyl ether (BDE209) has been widely used because of its excellent flame-retardant properties and ability. On the one hand, many studies have shown that the presence of BDE209 can potentially threaten human health and the environment. The production and processing of products containing BDE209 is prohibited except for special applications in China. On the other hand, the study of BDE209 on respiratory cells is not yet fully understood. Consequently, this study aims to investigate the mechanisms of toxic damage and oxidative stress induced by BDE209 exposure in lung epithelial Beas-2B cells. The proliferation of Beas-2B cells under BDE209 exposure was first analyzed by using a real-time label-free cell analyzer (RTCA). Then the cells’ morphological changes were observed using laser confocal microscopy. Subsequently, the effects of BDE209 exposure alone, combined exposure to N-acetylcysteine (NAC) and BDE209, on reactive oxygen species (ROS) levels and antioxidant defense-related factors in Beas-2B cells were analyzed separately. The results show that BDE209 exposure induces the proliferation of Beas-2B cells with a dose-dependent increase in inhibition. Microscopic observation of Beas-2B cells reveals significant damage and death. The levels of ROS are significantly increased (p < 0.01), the contents of superoxide dismutase (SOD) and malondialdehyde (MDA) are increased, the contents of catalase (CAT) are decreased, and the activities of glutathione peroxidase (GPX) are first decreased and then increased. However, under the co-exposure of NAC and BDE209, ROS levels are significantly reduced (p < 0.01), MDA contents decrease, and SOD activities increase. In summary, BDE209 exposure leads to inhibition of Beas-2B cell proliferation, cellular morphology damage, increased ROS levels, and disturbances in antioxidant defense-related factors. The cells showed toxic damage and oxidative stress. In contrast, NAC can suppress ROS levels, enhance SOD activity, and inhibit GPX activity, thereby alleviating BDE209-induced cellular damage. Full article

Cell transplantation is often performed with ultrasonographic guidance for accurate delivery through injection. In such procedures, using ultrasonographic contrast greatly improves target delivery. However, accumulating evidence suggests that exposure to such contrast agents may have negative effects on transplanted cells. No study so far has researched this issue. Stabilized sulfur hexafluoride (SF6) microbubbles are a widely used sonographic contrast agent. Skin hCD55 porcine transgenic fibroblasts and mesenchymal stem cells from human bone marrow (hMSCs) were exposed in vitro to SF6 in concentrations ranging from 1.54 µM to 308 µM. The effects on viability and cell growth were registered using an impedance-based label-free Real-Time Cell Analyzer (RTCA). Data was recorded every 15 min for 50 h of total study time. Both cell lines behave distinctly when exposed to SF6. Porcine fibroblast growth showed relevant alterations only when exposed to higher concentrations. In contrast, hMSCs showed progressive growth decrease in relation to SF6 concentration. Taken together, while SF6-based contrast agents pose no threat to patient safety, our results indicate that exposure of suspended stem cells to the contrast agent could affect the effective dose administered in cell therapy procedures. This prompts specific cell lineage testing, adjusting methods and properly compensating for cell loss, with a potential impact on procedural cost and success rates. Full article

Lung cancer is among the most aggressive malignancies, with the highest incidence and mortality rates worldwide. Standard treatments include surgery, radiotherapy, and chemotherapy; however, chemoresistance often develops, reducing therapeutic efficacy. Combination therapy offers a promising strategy to enhance drug effectiveness and overcome resistance. In lung cancer, the increased energy demands within cells result in a marked rise in the expression of PFKFB3, a regulatory protein involved in the glucose metabolic pathway. The small-molecule inhibitor KAN0438757, recognized as a novel PFKFB3 inhibitor, is significant in targeted therapy due to its essential role in the DNA damage response mechanism in cancer cells. Curcumin, the primary bioactive compound found in the rhizomes of Curcuma longa, has demonstrated a variety of biological functions and anticancer properties. This study aimed to evaluate the anticancer effects of KAN0438757 in combination with curcumin in lung cancer cells. Evaluation of cell viability and IC₅₀ values (KAN0438757: A549, 41.13 µM; H1299, 53.74 µM; Curcumin: A549, 44.37 µM; H1299, 66.25 µM) using the WST-1 and RTCA assays revealed pronounced inhibition of proliferation in the combination groups, accompanied by decreased cell migration (fold change, untreated cell; 1, CUR-20 µM; 0.681, KAN-20 µM; 0.530, and COMB; 0.0039 for 48 h). The comet assay revealed severe DNA damage (Tail DNA, fold change, untreated cell; 1, CUR-20 µM; 1.2, KAN-20 µM; 3, and COMB; 4.6) in the A549 cells, while MMP analysis (color change from red to green) and apoptotic staining confirmed cell death morphologically (color change from green to orange). Moreover, Western blot analysis demonstrated that the combination markedly enhanced apoptosis in the A549 cells. Full article

Melanoma represents a worldwide public health problem due to its high incidence and mortality rates. Despite the advances in melanoma therapy, not all patients respond to single or combined therapy because of primary or acquired resistance to the anti-tumor agents. Recently, positive results have been reported since the specific monoclonal antibodies, such as Ipilimumab (Ipi) and Nivolumab (Niv), were included in therapeutic protocols as immune checkpoint inhibitors. The evolution of neoplastic diseases and the therapeutic approaches in cancer involve several biological processes, including apoptosis, DNA progression through cell cycle phases, the release of pro-inflammatory cytokines, and changes in the expression of melanoma genes. Therefore, the potential modulation of these processes and associated molecules, due to single or combined treatments with oncolytic drugs like Carboplatin and Paclitaxel, checkpoint inhibitors such as Ipi and Niv, or natural bioactive compounds like Resveratrol or Quercetin, could represent a great benefit in melanoma treatment, contributing to the decrease or even reversal of the drug resistance in melanoma cells. Full article

GNSS-Inertial integration brings great potential to detect and mitigate the effect of erroneous (spoofed) GNSS data. When a trajectory of an airplane diverges from (or is inconsistent with) inertial data, the integrated system may detect this erroneous GNSS trajectory and may be able to maintain navigation integrity by rejecting this data. A GNSS-Aided Inertial System can provide both self-contained detection of a GNSS spoofing event as well as mitigation, where mitigation is hard to achieve globally with other commercial aviation systems relying on good ground system coverage. This paper provides an overview of the newly developed Inertial Spoofing Monitor for aviation grade navigation systems, which was designed to detect multiple simultaneous erroneous (spoofed) satellite measurements. The Inertial Spoofing Monitor was then thoroughly tested, and simulations were performed to evaluate and demonstrate the detection, mitigation, and recovery capability of the spoofing monitor. The performance validation followed the process prescribed by Appendix Q of the RTCA DO-384 MOPS (Minimum Operation Performance Standard). The results show great detection, mitigation, and recovery performance of the developed Inertial Spoofing Monitor, but also indicate constraints regarding the assumed sensor error model. Full article

While under-ice submarine hydrothermal systems provide critical insights into extremophile adaptations, the ecological impacts of explosive volcanism on these ecosystems remain poorly constrained. We successfully detected evidence of hydrothermal activities and explosive volcanism at 85° E, the eastern volcanic zone, ultra-slow spreading Gakkel Ridge. Hydrothermal plume, surface sediments, and volcanic glass samples were systematically collected to investigate the diversity of microbial communities. Our results revealed two distinct microbial regimes in hydrothermal plume: (1) chemoautotrophic bacteria (Sulfurimonas and SUP05_cluster), prevalent in global basaltic hydrothermal systems, potentially involved in carbon fixation through the CBB and rTCA cycles and (2) Alcanivorax (up to 82.5%), known for degrading hydrocarbons. Sediment profiles showed a depth-dependent decline of Alcanivorax, tightly coupled with TOC (1.05% to 0.45%, r = 0.75, p < 0.05). Additionally, the Alcanivorax MAGs demonstrated their potential in degrading various types of organic carbon, especially in alkane degradation. Strikingly, this pattern contrasts with hydrothermal plumes from effusive volcanic zones (Aurora and Polaris regions), where Alcanivorax was undetectable. We speculate that the surge of Alcanivorax in the 85° E hydrothermal plume was associated with the violent disturbances caused by explosive volcanism. This mechanism accelerates microbial-mediated carbon turnover rates compared to a stable hydrothermal ecosystem. Full article

Impedance-based cellular assays allow determination of biological functions of cell populations in real-time by measuring electrical impedance. As compared to end-point assays, such as trans-epithelial electrical resistance assays, for example, they enable fast, non-invasive, and easy detection of cell kinetics—their growth, attachment, and interaction can be monitored over time. In our experiment, Caco-2 cells were cultured on E-plates 16. Next, fully differentiated cells were treated with either TNF-α or 3,4-dihydroxy-L-phenylalanine (L-DOPA). We aimed to verify the possibility of real-time testing of the viability, monolayer formation, and integrity (i.e., the presence of a functional and polarized monolayer) of Caco-2 cells by the xCELLigence real-time cell analyzer (RTCA) S16 system (Agilent Technologies). Full article

This study aimed to evaluate the cytotoxicity of two resin materials, Tera Harz TC-85 DAC and Clear-A, along with the effects of two different post-printing protocols applied to Clear-A. Samples were produced using the Ackuretta Sol printer. The following three groups were formed based on the resins used and the post-curing methods applied: Group 1: Tera Harz TC-85 DAC resin + Tera Harz Cure; Group 2: Clear-A resin + Curie machine; and Group 3: Clear-A resin + Tera Harz Cure. All samples were sterilized in 70% ethanol for 5 min, rinsed with sterile deionized water, and incubated in Dulbecco’s Modified Eagle Medium at 37 °C for 72 h. Cytotoxicity assessment was performed by the XTT and RTCA methods using the human gingival fibroblast cell line. According to the XTT assay, undiluted resin extracts exhibited approximately 75–80% cell viability at 24 h, while further dilutions resulted in a viability exceeding 90%. No significant differences in viability were observed among the groups at any dilution at 48 and 72 h. The xCELLigence RTCA results aligned with the XTT findings, showing a transient decrease in cell viability within the first 24 h, followed by continued cell growth. This study demonstrated that extracts from all tested 3D-printed resins exhibited biocompatibility with human gingival fibroblasts. These findings support their potential for further applications in the dental and biomedical fields. Full article