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A Review on the Consequences of Molecular and Genomic Alterations Following Exposure to Electromagnetic Fields: Remodeling of Neuronal Network and Cognitive Changes

Authors: Shima Abtin, Fatemehsadat Seyedaghamiri, Zahra Aalidaeijavadi, Amir Mohammad Farrokhi, Fazel Moshrefi, Tayebeh Ziveh, Mohammad Ismail Zibaii, Hadi Aliakbarian, Mostafa Rezaei-Tavirani, Abbas Haghparast


Abstract Summary:

The pervasive use of electromagnetic fields (EMFs) in daily life has raised concerns about their potential health hazards, particularly regarding their effects on the central nervous system (CNS) and cognitive functions. This review article explores the molecular and genomic alterations induced by EMF exposure, focusing on neuronal network remodeling and cognitive changes.

A review on the consequences of molecular and genomic alterations following exposure to electromagnetic fields_ Remodeling of neuronal network and cognitive changes

Key Highlights:

  • Neurogenesis and Apoptosis: EMF exposure can alter neurogenesis (the formation of new neurons) and apoptosis (programmed cell death), impacting neuronal plasticity and potentially leading to cognitive impairments.
  • Gene Expression Regulation: EMFs affect both epigenetic (e.g., DNA methylation, histone modification) and non-epigenetic regulation of gene expression, which may lead to changes in cellular processes and adaptability.
  • Ion Channel Modifications: Exposure to EMFs can modify the expression, function, and structure of ion channels, affecting neuronal excitability and signaling.
  • Synaptic Transmission and Glial Function: EMFs influence synaptic transmission and the function of glial cells (supporting cells in the CNS), which can disrupt neuronal communication and network stability.
  • Behavioral Consequences: Changes at the molecular and cellular levels due to EMF exposure can lead to neuronal network remodeling, resulting in alterations in cognitive functions such as memory, learning, and behavior.

Detailed Insights:

  1. Effects on Neurogenesis:
    • Low-frequency EMFs may enhance neurogenesis and improve cognitive functions.
    • High-frequency EMFs can disrupt neurogenesis, leading to cognitive deficits.
  2. Apoptotic Pathways:
    • EMFs have varying effects on apoptosis, with some studies showing neuroprotective effects and others indicating increased cell death, depending on frequency and duration of exposure.
  3. Gene Expression and Epigenetics:
    • EMF exposure can alter the expression of genes related to cognitive processes, including neurotransmitter receptors and neurotrophic factors.
    • Epigenetic changes induced by EMFs may affect DNA methylation and histone modifications, potentially impacting neurodevelopment and behavior.
  4. Prenatal Exposure and Cognitive Deficits:
    • Prenatal EMF exposure is particularly concerning, as it can affect fetal brain development, leading to long-term cognitive impairments and structural changes in the hippocampus.
  5. Neurotransmitter Levels:
    • EMFs can alter levels of critical neurotransmitters like dopamine, serotonin, glutamate, and GABA, which play key roles in mood regulation and cognitive functions.
  6. Glial Cells and Ion Channels:
    • EMFs influence the activity and function of glial cells, affecting neuroinflammation and neuronal support.
    • Modifications in ion channels due to EMF exposure can disrupt neuronal excitability and signaling pathways.
  7. Synaptic Plasticity and Structural Changes:
    • EMF exposure can impair synaptic plasticity, affecting learning and memory processes.
    • Structural changes in dendritic spines and alterations in the blood-brain barrier permeability have been observed.
  8. Behavioral Implications:
    • Cognitive impairments, anxiety-like behaviors, and mood disorders have been associated with EMF exposure.
    • The effects are dependent on factors such as frequency, intensity, duration, and developmental stage at the time of exposure.

Conclusion:

The review underscores that EMF exposure can lead to significant molecular and genomic alterations in the CNS, resulting in neuronal network remodeling and cognitive changes. While extremely low-frequency EMFs might have neuroprotective effects, prolonged exposure to high-frequency EMFs is often associated with adverse neurological outcomes. The authors emphasize the need for more comprehensive studies to elucidate the exact mechanisms by which EMFs affect neuronal function and cognition.

Implications for Future Research:

  • Standardization of Study Parameters: There’s a need for standardized protocols regarding EMF frequency, intensity, and exposure duration to allow for more consistent and comparable results.
  • Mechanistic Studies: Further research is required to understand the precise molecular pathways affected by EMFs, including ion channel dynamics, neurotransmitter systems, and epigenetic modifications.
  • Long-term and Developmental Studies: Investigating the long-term effects of EMF exposure, especially during critical periods like prenatal development, can provide insights into lifelong cognitive and behavioral outcomes.
  • Protective Strategies: Exploring potential interventions or protective measures to mitigate the adverse effects of EMFs on the CNS could have significant public health implications.
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