Biological effects of 5G-modulated 700 MHz RF-EMF exposure on neuronal and glial cell models under isothermal conditions

PAPER manual Scientific Reports 2026 In vitro study Effect: no_effect Evidence: Low

Read original paper → Evidence Lab

Abstract

Whether radiofrequency electromagnetic fields (RF-EMF) at wireless telecommunication frequencies can alter brain physiology remains a matter of debate. The 700 MHz band, recently allocated for 4G and early 5G deployment, is increasingly prevalent in the environment, yet its biological effects are poorly documented. Here, we investigated the impact of 700 MHz 5G-modulated RF-EMF exposure on two complementary central nervous system cell models: primary rat cortical astrocytes and human SH-SY5Y neuroblastoma cells. Cells were exposed in transverse electromagnetic (TEM) cells at specific absorption rates (SAR) of 0.08 W/kg and 4 W/kg, for 1 h or 24 h, and analyzed immediately or after a 24 h recovery period. Multiparametric flow cytometry quantified mitochondrial reactive oxygen species (ROS), cell viability, and apoptosis stratified as early and late, together with astrocytes’ proliferation. Across all exposure conditions, no statistically significant differences were detected compared to sham controls, while positive controls with hydrogen peroxide elicited significant increases in ROS and apoptosis, validating assay sensitivity. These results demonstrate that, under strictly controlled iso-thermal conditions, 5G-modulated 700 MHz RF-EMF exposure does not induce measurable oxidative stress, apoptosis, or proliferative alterations in astrocytic and neuronal models. Our findings provide evidence supporting the absence of acute or subacute biological effects in vitro at isothermal exposure levels up to 4 W/kg, thereby reinforcing the scientific basis for current exposure guidelines.

AI evidence extraction

At a glance

Study type

In vitro study

Effect direction

no_effect

Population

Primary rat cortical astrocytes and human SH-SY5Y neuroblastoma cells

Sample size

—

Exposure

RF 5G-modulated 700 MHz RF-EMF · 700 MHz · 4 W/kg · 1 h or 24 h, analyzed immediately or after a 24 h recovery period

Evidence strength

Low

Confidence: 96% · Peer-reviewed: yes

Main findings

Primary rat cortical astrocytes and human SH-SY5Y neuroblastoma cells were exposed to 5G-modulated 700 MHz RF-EMF at SARs of 0.08 W/kg and 4 W/kg for 1 h or 24 h under isothermal conditions. No statistically significant differences versus sham controls were detected for ROS, viability, apoptosis, or astrocyte proliferation across exposure conditions.

Outcomes measured

mitochondrial reactive oxygen species (ROS)
cell viability
apoptosis (early and late)
astrocyte proliferation

Limitations

In vitro cell models only
Acute and subacute exposure durations only
Only two cell models were studied
Outcomes were limited to ROS, viability, apoptosis, and astrocyte proliferation

Suggested hubs

5g-policy (0.84)
Study examines 5G-modulated 700 MHz exposure and states findings support current exposure guidelines.
who-icnirp (0.71)
Abstract explicitly notes reinforcement of the scientific basis for current exposure guidelines.

View raw extracted JSON

{
    "study_type": "in_vitro",
    "exposure": {
        "band": "RF",
        "source": "5G-modulated 700 MHz RF-EMF",
        "frequency_mhz": 700,
        "sar_wkg": 4,
        "duration": "1 h or 24 h, analyzed immediately or after a 24 h recovery period"
    },
    "population": "Primary rat cortical astrocytes and human SH-SY5Y neuroblastoma cells",
    "sample_size": null,
    "outcomes": [
        "mitochondrial reactive oxygen species (ROS)",
        "cell viability",
        "apoptosis (early and late)",
        "astrocyte proliferation"
    ],
    "main_findings": "Primary rat cortical astrocytes and human SH-SY5Y neuroblastoma cells were exposed to 5G-modulated 700 MHz RF-EMF at SARs of 0.08 W/kg and 4 W/kg for 1 h or 24 h under isothermal conditions. No statistically significant differences versus sham controls were detected for ROS, viability, apoptosis, or astrocyte proliferation across exposure conditions.",
    "effect_direction": "no_effect",
    "limitations": [
        "In vitro cell models only",
        "Acute and subacute exposure durations only",
        "Only two cell models were studied",
        "Outcomes were limited to ROS, viability, apoptosis, and astrocyte proliferation"
    ],
    "evidence_strength": "low",
    "confidence": 0.95999999999999996447286321199499070644378662109375,
    "peer_reviewed_likely": "yes",
    "keywords": [
        "5G",
        "700 MHz",
        "RF-EMF",
        "in vitro",
        "astrocytes",
        "SH-SY5Y",
        "neuronal cells",
        "glial cells",
        "ROS",
        "apoptosis",
        "cell viability",
        "proliferation",
        "SAR",
        "isothermal"
    ],
    "suggested_hubs": [
        {
            "slug": "5g-policy",
            "weight": 0.83999999999999996891375531049561686813831329345703125,
            "reason": "Study examines 5G-modulated 700 MHz exposure and states findings support current exposure guidelines."
        },
        {
            "slug": "who-icnirp",
            "weight": 0.70999999999999996447286321199499070644378662109375,
            "reason": "Abstract explicitly notes reinforcement of the scientific basis for current exposure guidelines."
        }
    ]
}

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AI-extracted fields are generated from the abstract/metadata and may be incomplete or incorrect. This content is for informational purposes only and is not medical advice.

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