Medical/biological study (observational study)

Assessment of cortisol secretory pattern in workers chronically exposed to ELF-EMF generated by high voltage transmission lines and substations med./bio.

By: Touitou Y, Selmaoui B, Lambrozo J

Published in: Environ Int 2022; 161: 107103

Aim of study (acc. to author)

The effect of extremely low frequency magnetic fields on the secretion of cortisol in 14 men working in extra-high voltage substations were investigated.

Background/further details

Additionally, the workers lived in houses that were close to substations and high voltage power lines. Thus, they had long histories (1-20 years) of long-term exposure to extremely low frequency magnetic fields. Blood samples were taken hourly from 20:00 to 08:00 the next morning. Cortisol concentrations and patterns were compared to age-matched, unexposed control subjects (n=15) whose exposure level was ten times lower.

Endpoint

endocrine changes: cortisol level in blood

Exposure

- 50/60 Hz
- magnetic field
- power transmission line
- electrical substation
- occupational
- residential

Exposure	Parameters
Exposure 1: 50 Hz Exposure duration: continuous for up to 20 years	magnetic flux density: 0.1 µT minimum (weekly geometric mean (individual exposure)) magnetic flux density: 2.6 µT maximum (weekly geometric mean (individual exposure)) magnetic flux density: 0.72 µT mean (of 15 workers) magnetic flux density: 0.82 µT mean (arithmetic means of the residential exposure) magnetic flux density: 0.64 µT mean (arithmetic means of the daytime exposure)

Exposure 1

Main characteristics

Frequency	50 Hz
Type	magnetic field
Exposure duration	continuous for up to 20 years

Exposure setup

Exposure source	extra high voltage substations (occupational and residential exposure) and power lines (residential exposure)

Parameters

Measurand	Value	Type	Method	Mass	Remarks
magnetic flux density	0.1 µT	minimum	measured	-	weekly geometric mean (individual exposure)
magnetic flux density	2.6 µT	maximum	measured	-	weekly geometric mean (individual exposure)
magnetic flux density	0.72 µT	mean	calculated	-	of 15 workers
magnetic flux density	0.82 µT	mean	calculated	-	arithmetic means of the residential exposure
magnetic flux density	0.64 µT	mean	calculated	-	arithmetic means of the daytime exposure

Measurement and calculation details

the subjects wore a dosimeter (Emdex; Enertech Consultants, Campbell, CA, USA) day and night for one week

Reference articles

Touitou Y et al. (2013): Long-term (up to 20 years) effects of 50-Hz magnetic field exposure on immune system and hematological parameters in healthy men

Exposed system:

human
whole body

Methods Endpoint/measurement parameters/methodology

endocrine changes: cortisol level (ELISA)

Investigated system:

blood samples

Investigated organ system:

endocrine system

Time of investigation:

during exposure

Main outcome of study (acc. to author)

The comparison of the control group and the exposure groups (0.1-0.3 μT (n = 5) and > 0.3 μT (n = 9)) revealed a significant effect of field intensity on the cortisol secretory pattern. The data suggest that chronic exposure to extremely low frequency magnetic fields alters the serum cortisol levels with a statistically significant decline in the peak-time (06:00–08:00) cortisol levels even at the lower intensity of exposure, although the general secretory pattern of cortisol was unaffected.

Study character:

medical/biological study
observational study
full/main study

Study funded by

Electricité de France (EDF)
Foundation Adolphe De Rothschild, France

Touitou Y et al. (2020): Evaluation in humans of ELF-EMF exposure on chromogranin A, a marker of neuroendocrine tumors and stress
Touitou Y et al. (2013): Long-term (up to 20 years) effects of 50-Hz magnetic field exposure on immune system and hematological parameters in healthy men
Touitou Y et al. (2012): Long-term (up to 20 years) effects of 50-Hz magnetic field exposure on blood chemistry parameters in healthy men
Mortazavi SM et al. (2012): Occupational exposure of dentists to electromagnetic fields produced by magnetostrictive cavitrons alters the serum cortisol level
Vangelova K et al. (2007): Changes in excretion rates of stress hormones in medical staff exposed to electromagnetic radiation
Touitou Y et al. (2003): Magnetic fields and the melatonin hypothesis: a study of workers chronically exposed to 50-Hz magnetic fields
Kurokawa Y et al. (2003): Acute exposure to 50 Hz magnetic fields with harmonics and transient components: Lack of effects on nighttime hormonal secretion in men
Levallois P et al. (2001): Effects of electric and magnetic fields from high-power lines on female urinary excretion of 6-sulfatoxymelatonin
Selmaoui B et al. (1999): Assessment of the effects of nocturnal exposure to 50-Hz magnetic fields on the human circadian system. A comprehensive study of biochemical variables
Selmaoui B et al. (1997): Endocrine functions in young men exposed for one night to a 50-Hz magnetic field. A circadian study of pituitary, thyroid and adrenocortical hormones
Selmaoui B et al. (1996): Acute exposure to 50 Hz magnetic field does not affect hematologic or immunologic functions in healthy young men: a circadian study
Gamberale F et al. (1989): Acute effects of ELF electromagnetic fields: a field study of linesmen working with 400 kV power lines