Jürgen Schuderer

Electromagnetic fields, such as those from mobile phones, alter regional cerebral blood flow and sleep and waking EEG

Usage of mobile phones is rapidly increasing, but there is limited data on the possible effects of electromagnetic field (EMF) exposure on brain physiology. We investigated the effect of EMF vs. sham control exposure on waking regional cerebral blood flow (rCBF) and on waking and sleep electroencephalogram (EEG) in humans. In Experiment 1, positron emission tomography (PET) scans were taken after unilateral head exposure to 30‐min pulse‐modulated 900 MHz electromagnetic field (pm‐EMF). In Experiment 2, night‐time sleep was polysomnographically recorded after EMF exposure. Pulse‐modulated EMF exposure increased relative rCBF in the dorsolateral prefrontal cortex ipsilateral to exposure. Also, pm‐EMF exposure enhanced EEG power in the alpha frequency range prior to sleep onset and in the spindle frequency range during stage 2 sleep. Exposure to EMF without pulse modulation did not enhance power in the waking or sleep EEG. We previously observed EMF effects on the sleep EEG (A. A. Borbély, R. Huber, T. Graf, B. Fuchs, E. Gallmann and P. Achermann. Neurosci. Lett., 1999, 275: 207–210; R. Huber, T. Graf, K. A. Cote, L. Wittmann, E. Gallmann, D. Matter, J. Schuderer, N. Kuster, A. A. Borbély, and P. Achermann. Neuroreport, 2000, 11: 3321–3325), but the basis for these effects was unknown. The present results show for the first time that (1) pm‐EMF alters waking rCBF and (2) pulse modulation of EMF is necessary to induce waking and sleep EEG changes. Pulse‐modulated EMF exposure may provide a new, non‐invasive method for modifying brain function for experimental, diagnostic and therapeutic purposes.

Exposure to pulsed high-frequency electromagnetic field during waking affects human sleep EEG.

The aim of the study was to investigate whether the electro-magnetic field (EMF) emitted by digital radiotelephone handsets affects brain physiology. Healthy, young male subjects were exposed for 30 min to EMF (900 MHz; spatial peak specific absorption rate 1 W/kg) during the waking period preceding sleep. Compared with the control condition with sham exposure, spectral power of the EEG in non-rapid eye movement sleep was increased. The maximum rise occurred in the 9.75–11.25 Hz and 12.5–13.25 Hz band during the initial part of sleep. These changes correspond to those obtained in a previous study where EMF was intermittently applied during sleep. Unilateral exposure induced no hemispheric asymmetry of EEG power. The present results demonstrate that exposure during waking modifies the EEG during subsequent sleep. Thus the changes of brain function induced by pulsed high-frequency EMF outlast the exposure period.

Exposure to pulse‐modulated radio frequency electromagnetic fields affects regional cerebral blood flow

We investigated the effects of radio frequency electromagnetic fields (RF EMF) similar to those emitted by mobile phones on waking regional cerebral blood flow (rCBF) in 12 healthy young men. Two types of RF EMF exposure were applied: a ‘base‐station‐like’ and a ‘handset‐like’ signal. Positron emission tomography scans were taken after 30 min unilateral head exposure to pulse‐modulated 900 MHz RF EMF (10 g tissue‐averaged spatial peak‐specific absorption rate of 1 W/kg for both conditions) and sham control. We observed an increase in relative rCBF in the dorsolateral prefrontal cortex on the side of exposure. The effect depended on the spectral power in the amplitude modulation of the RF carrier such that only ‘handset‐like’ RF EMF exposure with its stronger low‐frequency components but not the ‘base‐station‐like’ RF EMF exposure affected rCBF. This finding supports our previous observation that pulse modulation of RF EMF is necessary to induce changes in the waking and sleep EEG, and substantiates the notion that pulse modulation is crucial for RF EMF‐induced alterations in brain physiology.

Electromagnetic fields affect transcript levels of apoptosis-related genes in embryonic stem cell-derived neural progenitor cells

Mouse embryonic stem (ES) cells were used as an experimental model to study the effects of electromagnetic fields (EMF). ES‐derived nestin‐positive neural progenitor cells were exposed to extremely low frequency EMF simulating power line magnetic fields at 50 Hz (ELF‐EMF) and to radiofrequency EMF simulating the Global System for Mobile Communication (GSM) signals at 1.71 GHz (RF‐EMF). Following EMF exposure, cells were analyzed for transcript levels of cell cycle regulatory, apoptosis‐related, and neural‐specific genes and proteins; changes in proliferation; apoptosis; and cytogenetic effects. Quantitative RT‐PCR analysis revealed that ELF‐EMF exposure to ES‐derived neural cells significantly affected transcript levels of the apoptosis‐related bcl‐2, bax, and cell cycle regulatory “growth arrest DNA damage inducible” GADD45 genes, whereas mRNA levels of neural‐specific genes were not affected. RF‐EMF exposure of neural progenitor cells resulted in down‐regulation of neural‐specific Nurr1 and in up‐regulation of bax and GADD45 mRNA levels. Short‐term RF‐EMF exposure for 6 h, but not for 48 h, resulted in a low and transient increase of DNA double‐strand breaks. No effects of ELF‐ and RF‐EMF on mitochondrial function, nuclear apoptosis, cell proliferation, and chromosomal alterations were observed. We may conclude that EMF exposure of ES‐derived neural progenitor cells transiently affects the transcript level of genes related to apoptosis and cell cycle control. However, these responses are not associated with detectable changes of cell physiology, suggesting compensatory mechanisms at the translational and posttranslational level.

UMTS Base Station-like Exposure, Well-Being, and Cognitive Performance

Background Radio-frequency electromagnetic fields (RF EMF) of mobile communication systems are widespread in the living environment, yet their effects on humans are uncertain despite a growing body of literature. Objectives We investigated the influence of a Universal Mobile Telecommunications System (UMTS) base station-like signal on well-being and cognitive performance in subjects with and without self-reported sensitivity to RF EMF. Methods We performed a controlled exposure experiment (45 min at an electric field strength of 0, 1, or 10 V/m, incident with a polarization of 45° from the left back side of the subject, weekly intervals) in a randomized, double-blind crossover design. A total of 117 healthy subjects (33 self-reported sensitive, 84 nonsensitive subjects) participated in the study. We assessed well-being, perceived field strength, and cognitive performance with questionnaires and cognitive tasks and conducted statistical analyses using linear mixed models. Organ-specific and brain tissue–specific dosimetry including uncertainty and variation analysis was performed. Results In both groups, well-being and perceived field strength were not associated with actual exposure levels. We observed no consistent condition-induced changes in cognitive performance except for two marginal effects. At 10 V/m we observed a slight effect on speed in one of six tasks in the sensitive subjects and an effect on accuracy in another task in nonsensitive subjects. Both effects disappeared after multiple end point adjustment. Conclusions In contrast to a recent Dutch study, we could not confirm a short-term effect of UMTS base station-like exposure on well-being. The reported effects on brain functioning were marginal and may have occurred by chance. Peak spatial absorption in brain tissue was considerably smaller than during use of a mobile phone. No conclusions can be drawn regarding short-term effects of cell phone exposure or the effects of long-term base station-like exposure on human health.

Pulsed radio-frequency electromagnetic fields: dose-dependent effects on sleep, the sleep EEG and cognitive performance

To establish a dose–response relationship between the strength of electromagnetic fields (EMF) and previously reported effects on the brain, we investigated the influence of EMF exposure by varying the signal intensity in three experimental sessions. The head of 15 healthy male subjects was unilaterally exposed for 30 min prior to sleep to a pulse‐modulated EMF (GSM handset like signal) with a 10 g‐averaged peak spatial specific absorption rate of (1) 0.2 W kg–1, (2) 5 W kg–1, or (3) sham exposed in a double‐blind, crossover design. During exposure, subjects performed two series of three computerized cognitive tasks, each presented in a fixed order [simple reaction time task, two‐choice reaction time task (CRT), 1‐, 2‐, 3‐back task]. Immediately after exposure, night‐time sleep was polysomnographically recorded for 8 h. Sleep architecture was not affected by EMF exposure. Analysis of the sleep electroencephalogram (EEG) revealed a dose‐dependent increase of power in the spindle frequency range in non‐REM sleep. Reaction speed decelerated with increasing field intensity in the 1‐back task, while accuracy in the CRT and N‐back task were not affected in a dose‐dependent manner. In summary, this study reveals first indications of a dose–response relationship between EMF field intensity and its effects on brain physiology as demonstrated by changes in the sleep EEG and in cognitive performance.

Pulsed radio frequency radiation affects cognitive performance and the waking electroencephalogram.

We investigated the effects of radio frequency electromagnetic fields on brain physiology. Twenty-four healthy young men were exposed for 30 min to pulse-modulated or continuous-wave radio frequency electromagnetic fields (900 MHz; peak specific absorption rate 1 W/kg), or sham exposed. During exposure, participants performed cognitive tasks. Waking electroencephalogram was recorded during baseline, immediately after, and 30 and 60 min after exposure. Pulse-modulated radio frequency electromagnetic field exposure reduced reaction speed and increased accuracy in a working-memory task. It also increased spectral power in the waking electroencephalogram in the 10.5–11 Hz range 30 min after exposure. No effects were observed for continuous-wave radio frequency electromagnetic fields. These findings provide further evidence for a nonthermal biological effect of pulsed radio frequency electromagnetic fields.

1800 MHZ RADIOFREQUENCY (MOBILE PHONES, DIFFERENT GLOBAL SYSTEM FOR MOBILE COMMUNICATION MODULATIONS) DOES NOT AFFECT APOPTOSIS AND HEAT SHOCK PROTEIN 70 LEVEL IN PERIPHERAL BLOOD MONONUCLEAR CELLS FROM YOUNG AND OLD DONORS

Purpose: To study if prolonged in vitro exposure to 1800 MHz radiofrequency (RF) could exert an effect on human peripheral blood mononuclear cells (PBMC) from young and elderly donors by affecting apoptosis, mitochondrial membrane potential and heat shock protein (HSP) 70 levels. Materials and methods: Endpoints were analysed in the presence or absence of the apoptosis‐inducing agent 2‐deoxy‐D‐ribose. Three different signal modulations typical of the Global System for Mobile communication (GSM) system were applied. The modulations are widely used in mobile telephony (GSM Basic, discontinuous transmission [DTX] and Talk) at specific absorption rates of 1.4 and 2.0 W kg−1. Results: In all conditions and for all endpoints tested, there was no significant difference between RF‐ and sham‐exposed cells. Conclusion: 1800 MHz RF could not induce apoptosis by itself or affect the apoptotic phenomenon when induced by an apoptotic agent. Moreover, RF did not modify the mitochondrial functionality and the expression of HSP 70.

Novel high-resolution temperature probe for radiofrequency dosimetry

A novel integrated thermistor probe for temperature evaluations in radiofrequency-heated environments was realized. The probes sensitive area is based on a highly resistive 50 microm x 100 microm layer of amorphous germanium processed on a glass tip. The small dimensions allow measurements with a distance as close as 150 microm from solid boundaries. Due to its high temperature resolution of 4 mK and its short response time of the order of 10 ms, the sensor is very well suited for dosimetric measurements in strong absorption gradients. The influence of radiofrequency (RF) electric fields on the signal is minimized due to the high resistance of the sensor and the leads. The probe was successfully used to determine the highly nonuniform absorption distribution resulting from the RF exposure of cell cultures placed in Petri dishes.