Medical/biological study (experimental study)

Effects of 940 MHz EMF on Luciferase solution: structure, function, and dielectric studies med./bio.

By: Sefidbakht Y, Hosseinkhani S, Mortazavi M, Tavakkolnia I, Khellat MR, Shakiba-Herfeh M, Saviz M, Faraji-Dana R, Saboury AA, Sheibani N, Moosavi-Movahedi AA

Published in: Bioelectromagnetics 2013; 34 (6): 489-498

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Aim of study (acc. to author)

To study the effects of mobile phone frequency (940 MHz) electromagnetic fields on luciferase structure and activity (as a model enzyme).

Background/further details

Luciferase activities of exposed and control samples with different pre-exposure incubation times on ice (10 and 50 min) were compared.

Endpoint

luciferase structure and enzyme activity

Exposure

- 940 MHz
- RF field
- mobile communications
- mobile phone

Exposure	Parameters
Exposure 1: 940 MHz Exposure duration: exposure duration not given clearly (30 min?)	power: 1 W (input power) electric field strength: 6 V/m effective value SAR: 0.021 W/g average over mass (1 g) (along the length of the sample tube)

Exposure 1

Main characteristics

Frequency	940 MHz
Type	electromagnetic field
Exposure duration	exposure duration not given clearly (30 min?)

Exposure setup

Exposure source	waveguide rectangular waveguide
Chamber	5 cm plastic vial (0,5 mm wall thickness) placed in the X-shaped sample holder
Setup	waveguide unit (aluminium box 600 mm in length and 170 mm in width and height); two probes generated the electromagnetic wave of 940 MHz at one end of the waveguide, and the other end was matched with the same configuration (only the vertical probe was used); four aluminum stubs were used for impedance matching of waveguide and elimination of standing wave pattern; X-shape Teflon sample holder for five samples (horizontally oriented; only central position was used) placed in the centre of the waveguide; waveguide was placed in an incubator (25°C); at each end of the waveguide, four pores were covered by metal meshes and equipped with fans to circulate the air inside the waveguide;
Additional info	control samples were shielded with aluminium cylinders (1 cm in thickness) and placed in the incubator outside of the waveguide at the same temperature

Parameters

Measurand	Value	Type	Method	Mass	Remarks
power	1 W	-	-	-	input power
electric field strength	6 V/m	effective value	calculated	-	-
SAR	0.021 W/g	average over mass	calculated	1 g	along the length of the sample tube

Additional parameter details

temperature rise (approx. 0.023°C) was neglected

Exposed system:

isolated bio./chem. substance
luciferase solution

Methods Endpoint/measurement parameters/methodology

luciferase structure and activity: bioluminescence activity (spectrofluorometry); luciferase activity (in different concentrations of luciferin and ATP; determination of Michaelis-Menten constant); aggregation assay (spectrophotometry); particle size (dynamic light scattering measurement); calculation of luciferase dipole moment (via a specific software); hydration properties; dielectric measurements in the range of 0.3-20 GHz

Investigated system:

isolated bio./chem. substance
luciferase solution

Time of investigation:

before exposure
after exposure

Main outcome of study (acc. to author)

The luciferase activity of exposed samples was significantly higher than that of unexposed samples. The particle size (mean diameter) of the control samples was significantly larger than that of the exposed samples. The exposed samples showed a less tendency to form aggregates. The change in the dielectric properties of the exposed luciferase solution was related to the disaggregation potency of the applied field.
The authors conclude that the data suggest that direct interactions with luciferase molecules and its dipole moment were responsible for the reduced aggregation and enhanced luciferase activity following exposure to the electromagnetic field.

Study character:

medical/biological study
experimental study
full/main study

Study funded by

Centre of Excellence in Biothermodynamics, University of Tehran, Tehran, Iran
Iran National Science Foundation (INSF)
University of Tehran, Iran

Sefidbakht Y et al. (2014): Effects of 940 MHz EMF on bioluminescence and oxidative response of stable luciferase producing HEK cells
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Fortune JA et al. (2010): Radio frequency radiation causes no nonthermal damage in enzymes and living cells
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