Static and Electromagnetic Fields Differently Affect Proliferation and Cell Death Through Acid Enhancement of ROS Generation in Mesenchymal Stem Cells

Advances in magnetic field approaches for non-invasive targeting neuromodulation

Neuromodulation, the targeted regulation of nerve activity, has emerged as a promising approach for treating various neurological and psychiatric disorders. While deep brain stimulation has shown efficacy, its invasive nature poses substantial risks, including surgical complications and high costs. In contrast, non-invasive neuromodulation techniques, particularly those utilizing magnetic fields (MFs), have gained increasing attention as safer, more accessible alternatives. Magnetothermal stimulation has emerged as an innovative method that enables precise modulation of neuronal ion channels through localized heating induced by interaction of MF with biological tissues. This review discusses the principles of MF-based neuromodulation and highlights the critical role of ion channels in synaptic transmission, and the therapeutic potential of these advanced techniques. Additionally, it highlights key challenges such as spatial targeting precision, safety considerations, and the long-term effects of magnetic exposure on brain function. The findings presente the promise of MF-based neuromodulation as a non-invasive, highly targeted therapeutic strategy for conditions such as epilepsy, movement disorders, and neurodegenerative diseases, with potential applications in chronic pain management and future clinical interventions.

Static magnetic field promotes the doxorubicin toxicity effects on osteosarcoma cells

Osteosarcoma, a highly aggressive bone cancer, primarily affects adolescents and is frequently treated with conventional chemotherapy, such as doxorubicin (DOX). However, the efficacy of DOX is often limited by severe side effects and drug resistance. This study investigates the synergistic effects of static magnetic fields (SMF) and DOX on G292 osteosarcoma cells and HFF normal fibroblasts. Cell viability was assessed using the MTT assay, intracellular reactive oxygen species (ROS) levels were quantified via DCFDA staining and flow cytometry, and iron and calcium homeostasis were analyzed using ICP-OES. Apoptosis and necrosis were determined through Annexin V-FITC/PI staining. Results demonstrated that the combination of SMF and DOX significantly reduced G292 cell viability compared to DOX alone, with IC50 values decreased from 3.2 µM (at 3 mT, p < 0.01) to 0.8 µM (at 24 mT, p < 0.001) at 24 h. Apoptosis rates increased from 8.12% with DOX alone to 16% with SMF + DOX. While DOX alone elevated ROS levels by 59.15% in G292 cells, SMF further amplified apoptosis by enhancing ROS generation and disrupting iron and calcium homeostasis. These findings suggest that SMF enhances DOX-induced cytotoxicity in osteosarcoma cells by promoting ROS production, altering metal ion homeostasis, and increasing apoptosis. SMF represents a promising adjuvant therapy for osteosarcoma treatment, though further in vivo studies are necessary to optimize treatment parameters and evaluate clinical applicability.

Thermomagneto-responsive injectable hydrogel for chondrogenic differentiation of mesenchymal stem cells

Damaged cartilage tissue has a limited ability to self-heal due to its avascular nature and low cellularity. To effectively engineer cartilage tissue, innovative techniques such as injectable and interactive hydrogels using a minimally invasive approach are required to mimic the natural properties of cartilage. In this study, an injectable hydrogel containing magnetic iron oxide nanoparticles (MNPs) has been rationally designed to induce chondrogenic differentiation in bone marrow mesenchymal stem cells (BMSCs) using an external magnetic field application. The effect of the incorporation of MNPs with the surface functional group of either carboxyl or amine on the properties of the hydrogels (denoted as HS and HA samples, respectively) has been investigated, and compared to control hydrogel without MNPs (denoted as H). The hydrogels demonstrated thermomagnetic-responsive and shear-thinning behavior. Incorporating MNPs in the hydrogel combination resulted in the formation of a more robust network with increased compressive modulus (by 2 and 2.5 times), cell viability (by 24 % and 7 %), swelling ratio (by 97 % and 42 %) for HS and HA, respectively, as well as better cell adhesion. Also, incorporating MNPs resulted in decreased elastic modulus (by 28 and 5 times), biodegradation rate (by 5 % and 9 %), and viscosity (by 4 and 20 times) for HS and HA, respectively. The results of glycosaminoglycans (GAG) staining indicated the synergistic effect of MNP incorporation and magnetic field application in improving chondrogenic differentiation of BMSCs in vitro. The research findings could lead to the development of superior injectable hydrogels and bioinks for tissue engineering applications.

Mobile phone specific radiation disturbs cytokinesis and causes cell death but not acute chromosomal damage in buccal cells: Results of a controlled human intervention study

Several human studies indicate that mobile phone specific electromagnetic fields may cause cancer in humans but the underlying molecular mechanisms are currently not known. Studies concerning chromosomal damage (which is causally related to cancer induction) are controversial and those addressing this issue in mobile phone users are based on the use of questionnaires to assess the exposure. We realized the first human intervention trial in which chromosomal damage and acute toxic effects were studied under controlled conditions. The participants were exposed via headsets at one randomly assigned side of the head to low and high doses of a UMTS signal (n = 20, to 0.1 W/kg and n = 21 to 1.6 W/kg Specific Absorption Rate) for 2 h on 5 consecutive days. Before and three weeks after the exposure, buccal cells were collected from both cheeks and micronuclei (MN, which are formed as a consequence of structural and numerical chromosomal aberrations) and other nuclear anomalies reflecting mitotic disturbance and acute cytotoxic effects were scored. We found no evidence for induction of MN and of nuclear buds which are caused by gene amplifications, but a significant increase of binucleated cells which are formed as a consequence of disturbed cell divisions, and of karyolitic cells, which are indicative for cell death. No such effects were seen in cells from the less exposed side. Our findings indicate that mobile phone specific high frequency electromagnetic fields do not cause acute chromosomal damage in oral mucosa cells under the present experimental conditions. However, we found clear evidence for disturbance of the cell cycle and cytotoxicity. These effects may play a causal role in the induction of adverse long term health effects in humans.

Harmonizing Magnetic Mitohormetic Regenerative Strategies: Developmental Implications of a Calcium-Mitochondrial Axis Invoked by Magnetic Field Exposure

Mitohormesis is a process whereby mitochondrial stress responses, mediated by reactive oxygen species (ROS), act cumulatively to either instill survival adaptations (low ROS levels) or to produce cell damage (high ROS levels). The mitohormetic nature of extremely low-frequency electromagnetic field (ELF-EMF) exposure thus makes it susceptible to extraneous influences that also impinge on mitochondrial ROS production and contribute to the collective response. Consequently, magnetic stimulation paradigms are prone to experimental variability depending on diverse circumstances. The failure, or inability, to control for these factors has contributed to the existing discrepancies between published reports and in the interpretations made from the results generated therein. Confounding environmental factors include ambient magnetic fields, temperature, the mechanical environment, and the conventional use of aminoglycoside antibiotics. Biological factors include cell type and seeding density as well as the developmental, inflammatory, or senescence statuses of cells that depend on the prior handling of the experimental sample. Technological aspects include magnetic field directionality, uniformity, amplitude, and duration of exposure. All these factors will exhibit manifestations at the level of ROS production that will culminate as a unified cellular response in conjunction with magnetic exposure. Fortunately, many of these factors are under the control of the experimenter. This review will focus on delineating areas requiring technical and biological harmonization to assist in the designing of therapeutic strategies with more clearly defined and better predicted outcomes and to improve the mechanistic interpretation of the generated data, rather than on precise applications. This review will also explore the underlying mechanistic similarities between magnetic field exposure and other forms of biophysical stimuli, such as mechanical stimuli, that mutually induce elevations in intracellular calcium and ROS as a prerequisite for biological outcome. These forms of biophysical stimuli commonly invoke the activity of transient receptor potential cation channel classes, such as TRPC1.

Polyethylenimine-based iron oxide nanoparticles enhance cisplatin toxicity in ovarian cancer cells in the presence of a static magnetic field

Background

Drug resistance in cancer cells is a major concern in chemotherapy. Cisplatin (CIS) is one of the most effective chemotherapeutics for ovarian cancer. Here, we investigated an experimental approach to increase CIS cytotoxicity and overcome cell resistance using nanoparticle-based combination treatments.

Methods

Polyethylenimine (PEI)-based magnetic iron oxide nanocomplexes were used for drug delivery in genetically matched CIS-resistant (A2780/CP) and -sensitive (A2780) ovarian cancer cells in the presence of a 20 mT static magnetic field. Magnetic nanoparticles (MNPs) were synthesized and bonded to PEI cationic polymers to form binary complexes (PM). The binding of CIS to the PM binary complexes resulted in the formation of ternary complexes PM/C (PEI-MNP/CIS) and PMC (PEI-MNP-CIS).

Results

CIS cytotoxicity increased at different concentrations of CIS and PEI in all binary and ternary delivery systems over time. Additionally, CIS induced cell cycle arrest in the S and G2/M phases and reactive oxygen species production in both cell lines. Ternary complexes were more effective than binary complexes at promoting apoptosis in the treated cells.

Conclusion

PEI-based magnetic nanocomplexes can be considered novel carriers for increasing CIS cytotoxicity and likely overcoming drug resistance of ovarian cancer cells.

Mesenchymal stem cell therapy for neurological disorders: The light or the dark side of the force?

Neurological disorders are recognized as major causes of death and disability worldwide. Because of this, they represent one of the largest public health challenges. With awareness of the massive burden associated with these disorders, came the recognition that treatment options were disproportionately scarce and, oftentimes, ineffective. To address these problems, modern research is increasingly looking into novel, more effective methods to treat neurological patients; one of which is cell-based therapies. In this review, we present a critical analysis of the features, challenges, and prospects of one of the stem cell types that can be employed to treat numerous neurological disorders-mesenchymal stem cells (MSCs). Despite the fact that several studies have already established the safety of MSC-based treatment approaches, there are still some reservations within the field regarding their immunocompatibility, heterogeneity, stemness stability, and a range of adverse effects-one of which is their tumor-promoting ability. We additionally examine MSCs' mechanisms of action with respect to in vitro and in vivo research as well as detail the findings of past and ongoing clinical trials for Parkinson's and Alzheimer's disease, ischemic stroke, glioblastoma multiforme, and multiple sclerosis. Finally, this review discusses prospects for MSC-based therapeutics in the form of biomaterials, as well as the use of electromagnetic fields to enhance MSCs' proliferation and differentiation into neuronal cells.