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The millimeter waves (MMW) region of the electromagnetic spectrum, extending from 30 to 300 GHz in terms of frequency (corresponding to wavelengths from 10 mm to 1 mm), is officially used in non-invasive complementary medicine in many Eastern European countries against a variety of diseases such gastro duodenal ulcers, cardiovascular disorders, traumatism and tumor. On the other hand, besides technological applications in traffic and military systems, in the near future MMW will also find applications in high resolution and high-speed wireless communication technology. This has led to restoring interest in research on MMW induced biological effects. In this review emphasis has been given to the MMW-induced effects on cell membranes that are considered the major target for the interaction between MMW and biological systems.
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Journal of Infrared,
Millimeter, and Terahertz
ISSN 1866-6892
Volume 31
Number 12
J Infrared Milli Terahz Waves
(2010) 31:1400-1411
DOI 10.1007/s10762-010-9731-
Effects of Millimeter Waves Radiation on
Cell Membrane - A Brief Review
1 23
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Effects of Millimeter Waves Radiation
on Cell Membrane - A Brief Review
Alfonsina Ramundo-Orlando
Received: 14 April 2010 /Accepted: 7 October 2010 /
Published online: 27 October 2010
#Springer Science+Business Media, LLC 2010
Abstract The millimeter waves (MMW) region of the electromagnetic spectrum,
extending from 30 to 300 GHz in terms of frequency (corresponding to wavelengths from
10 mm to 1 mm), is officially used in non-invasive complementary medicine in many
Eastern European countries against a variety of diseases such gastro duodenal ulcers,
cardiovascular disorders, traumatism and tumor. On the other hand, besides technological
applications in traffic and military systems, in the near future MMW will also find
applications in high resolution and high-speed wireless communication technology. This
has led to restoring interest in research on MMW induced biological effects. In this review
emphasis has been given to the MMW-induced effects on cell membranes that are
considered the major target for the interaction between MMW and biological systems.
Keywords Millimeter waves .Cell membrane .Lipid bilayer .Biological effects
1 Introduction
The millimeter waves (MMW) region of the electromagnetic spectrum, extending from 30
to 300 GHz in terms of frequency (corresponding to wavelengths from 10 mm to 1 mm), is
officially used in non-invasive complementary medicine in many Eastern European
countries against a variety of diseases such as gastric and duodenal ulcers, coronary artery
disease, chronic nonspecific pulmonary diseases, traumatism, and tumor [18]. Specifically,
the most common frequencies used in therapy are 35, 42.2, 53.6, 61.2 and 78 GHz [9]. The
millimeter-wave energy of the current medical applications is generally in low power levels
below 10 mW/cm
producing imperceptible heating of exposed localized areas of skin. For
this reason the biological responses might be principally different from those caused by
heating. In a few, non-reproducible studies, the effects of MMW often have a sharp,
J Infrared Milli Terahz Waves (2010) 31:14001411
DOI 10.1007/s10762-010-9731-z
A. Ramundo-Orlando (*)
Institute of Neurobiology and Molecular Medicine, Italian National Research Council,
Via del Fosso del Cavaliere, 100-00133 Rome, Italy
Author's personal copy
resonance-like dependence on the radiation frequency, but they depend relatively little on the
radiation intensity [10].
On the other hand, besides technological applications in traffic and military systems, in
the near future MMW will also find applications in high resolution and high-speed wireless
communication technology [1113]. This has led to restoring interest in research on MMW
induced biological effects.
The study of effects induced by MMW radiation is related to the problem of the
interaction between electromagnetic fields (EMFs) and biological systems. This issue is of
interest because of fundamental scientific curiosity, potential medical benefits, and possible
human health hazards. The latter problem has been studying for decades leading to a big
deal of papers indicating potential dangerous effects [14]. The debate is still open, even if
several points have been fixed. The action of high-levels fields is well-known and has led to
the definition of international safety standards by International Commission of Non-
Ionizing Radiation Protection (ICNIRP) in 1998 [14].
2 Biological effects of EM wave: a possible classification
Following classification approaches commonly used in the literature, also if as in every
classification some limitations seem inevitable, a first way to classify the biological effects
of electromagnetic (EM) wave is related to the energy level of incident radiation. We know
that the energy associated with a quantum of electromagnetic radiation can be expressed
through the Planks equation:
This quantity can be or not sufficient to ionize the atoms of the exposed material. In order
to structurally modify the biological material the EM wave should transfer an energy
quantity notably larger than κT, average kinetic energy of order κT=4.3 10
J. For the
frequency spectrum we are considering (above 30 GHz) the energy associated with a
photon can be considered around 2 10
J, at least two order of magnitude less than κT.
Further this energy can be considered lower than the activation energy needed for different
physic-chemical phenomena (Table 1). Consequently the MMW are classified non-ionizing
radiation; they do not destroy inter-atomic bonds, and do not lead to chemical
transformations. For these reasons MMW has potential for medical, security and
environmental protection applications as mentioned before.
Table 1 Energy activation of some phenomena.
Physic-chemical phenomenon Energy (eV) Frequency of EMF (Hz)
atom ionization 10 >10
e excitation 1.5-10 10
covalent bond 5 10
conformational changes 0.4 10
hydrogen bond 0.08-2 10
thermal agitation 0.026 5×10
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A second way to classify the biological effects of EM wave is based on the induction of
thermal energy into biological system by the electromagnetic energy of incident radiation. We can
distinguish between thermal and non-thermal or specific effects. The former are due to a sharp
increase in temperature that can be systemic or localized. Such effects typically correspond to high
power radiation, greater than 10 mW/cm
. At the macromolecular level, heating effects will arise
from the motion of water molecule dipoles. These effects should be evaluated in order to
determine the effective energy absorbed by the target; for such a goal, it could be enough (yet
not-trivial) to rigorously characterize the studied system through Maxwells equations, by
applying fundamental EM theorems where the heating process is considered in the energy
balancing [15]. In the latter case of non-thermal or specific effects (i.e. effects where
temperature plays a non primary role, or its just one among several physical parameters),
mechanisms have not been fully demonstrated, and their comprehension is an existing
challenge. Research on specific effects of low-level EM wave has always run into difficulties
from the experimental point of view due to the complexity of the biological system involved,
the instability of the samples, the weakness of the signal measured and/or the non
reproducibility nature of the source. Further research on specific effects of low-level EM wave
has attracted few scientists of the Western Countries due to the still open debate on the
existence of these specific effects and on their biophysical limits [16].
3 Biological effects of millimeter waves
Several studies on the effects induced by millimeter radiation on biological systems have
been reported in the literature. Diverse effects have been observed on cell free systems,
cultured cells, isolated organs of animals and humans. The subject has been extensively
reviewed by Motzkin [17] and more recently by Pakhomov [3]. At the cellular level these
effects are mainly on the membrane process and ion channels, molecular complexes,
excitable and other structures. Many of these effects are quite unexpected from a radiation
penetrating less than 1 mm into biological tissues [3,18,19]. However none of the findings
described in the above reviews has been replicated in an independent laboratory, thus they
cannot be considered as established biological effects.
Further the interpretation of these reported effects is a matter of controversy, especially
regarding whether low intensity MMW exposure (less than 10 mW/cm
) can produce
biological effects via non-thermal mechanism [20]. According to reports that MMW
radiation increased or decreased the growth of E. coli [21] and yeast [22] depending on
different frequencies (136 GHz and 41.68÷41.71 GHz), Fröhlich proposed the existence of
electric vibrations in biological systems (coherent oscillations of a section of membrane,
proteins, or DNA). He suggested that low power MMW could trigger the excitation of the
coherent electric vibrations provided if the biological system is in an active metabolic state
[23]. Even if Fröhlich theory has never been confirmed experimentally in reproducible
studies, his work suggests that supplying such energy by means of millimeter waves at
specific frequency could be a way to regulate the growth of biological entities. As the
power densities used in the above cited reports were low (<10 mW/cm
), the effects on
growth rate were considered as non-thermal ones by the reporters. On the other hand, some
researchers that attempted to reproduce these non-thermal experiments have reported no
effects [2426], or similar results at higher frequencies (200-350 GHz) [27]. The reasons
for these controversial reports could reside in the difference between the biological species,
experimental procedures, the uncertainty of biological meaningful exposure metrics, and
the difficulties in rigorously performing the required controls.
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4 Cell membrane: the major target of MMW interaction
When considering the action of MMW on biological systems the cell membranes are
considered the major target for the interaction since they have been theoretically considered
to be sensible to coherent excitations above 10
Hz [23]. The cell membranes are of
immense interest in biological physics: The membrane acts as a gateway to the cell; 30% of
all proteins within the body are membrane proteins; and 60% of drug targets are membrane
proteins. They control many essential functions in biological tissues. Despite its immense
complexity, however, the functionality of the membrane is ultimately determined by its
mechanical and electrical properties. In this context the cell membrane is of particular
interest because, in principle, interactions between the electrophysiological mechanisms at
the cell membrane and electromagnetic fields might be possible [28].
As mentioned before a large number of cellular studies have indicated that MMW may
alter structural and functional properties of membranes (Table 2).
Effects of MMW on internal membrane system, i.e. sarcoplasmic reticulum, in skeletal
and heart muscles of rat have been reported by Brovkovich et al.[29]. The sarcoplasmic
reticulum (SR) acts as a calcium source during muscles contraction and a calcium sink
during relaxation. The latter is mediated by the transport of calcium into the SR lumen by a
Ca-ATPase. The authors measured the rate of Ca
uptake in SR of skeletal muscle
homogenates by an ion-selective electrode in an ATP-containing medium. They indicated
that intermittent exposures to continuous wave 61 GHz radiations, at 4 mW/cm
significantly activate the Ca
pump in the SR by 23%. Uninterrupted MMW radiation
had no effect in 10 min, but increased Ca
uptake in SR by 27% in 20 min; and the effect
reached a maximum of 48% in 40 min. On the other hand in heart muscle homogenate,
even a 5-min exposure enhanced Ca
uptake in SR by 18%.
It has been reported [30] that exposure to 38-78 GHz radiation, at 5 mW/cm
, has an
indirect frequency-dependent effect on the activity of chloride channels in the cytoplasmic
membrane of charophytes (Nitellopsis obtusa). Charophytes are water plants useful in
physiological studies. These alga cells possess some of the largest single plant cells known,
and this makes them relatively easy to manipulate for experimental studies on how cells
function. Irradiation for 30-60 min at 41 GHz suppressed the chloride current to zero with
no recovery for 10-14 h. Marked inhibitory effects were also found at 50 and 71 GHz,
whereas exposures at 49, 70, and 76 GHz enhanced the chloride current up to 200-400%.
This activation was reversible, and recovery to the initial value took 30-40 min. MMW
induced-heating did not exceed 1°C, and neither activating nor inhibitory effects were
related to or could be explained by it. The authors assumed that MMW effect was caused by
the modulating effect of radiation on the ATPase activity of chloroplasts, which regulates
the Ca
concentration and pH in the cytoplasm and, thus the activity of chloride channel.
MMW induced-changes on both cooperativity and binding characteristics of the
potassium channel activation by internal calcium ions have been reported by Gelyetuk et
al [31]. The authors measured changes on single Ca
-activated K
channels in cultured
kidney cells (Vero) by using patch voltage-clamp method (inside-out-mode). The effects of
42.25 GHz (CW), at 0.1 mW/cm
, were revealed 20-30 min after the onset of the
irradiation. The increase or inhibition of the activity of the channels was depending on
initial sensitivity of the channels to Ca
and the Ca
concentration applied. Successively
the authors reported [32] that a 20-30 min preliminary irradiation to 42.25 GHz (CW), at
2 mW/cm
, of the test solution (100 mM KCl with Ca
added) would be sufficient to
obtain the MMW effects on the channel activity. The possibility of transfer of
electromagnetic radiation information through water was attributed to a change in the size
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Table 2 Summary of MMW effects induced on membranes. IE = intermittent exposure; I
= time-averaged incident intensity.
Biological system End-point / Technique Frequency / Power Effects Reference
Skeletal/heart muscle (rat) Ca
pump in sarcoplasmic reticulum
/ ion-selective electrode
61 GHz Increased Ca
uptake (IE) Brovkovic [29]
4 mW/cm
Giant alga cells (Nitellopsis obtusa) Cytoplasmic membrane chloride (Cl
channels / voltage clamp
41 GHz Cl
current drops to 0; Kataev [30]
5 mW/cm
No recovery for 10-14 h
50, 71 GHz Marked inhibition
Idem Idem 49, 70, 76 GHz Cl
current increased up to 200-400%; Idem
5 mW/cm
Reversible within 30-40 min
Kidney cell (Ver o ) Single Ca
-activated K
channels / patch
42.25 GHz Increased activity when < [Ca
] Geletyuk [31]
0.1 mW/ cm
Inhibited activity when > [Ca
Lipid bilayer (BLM) membranes Proton carriers transport / nonpolarizing
Ag/AgCl electrodes
42.25 GHz Increased conductance Cojocaru [34]
3 mW/cm
Human blood erythrocyte Energy value of activating Cl
exchange / ionometer hydrogen electrode
38 GHz Speeded up transmembrane Cl
antiport Yemets [38]
Max output 0.4 mW
Lipid bilayer (BLM) membranes Gramicidin channel-Capacitance / voltage clamp 53-78 GHz Slight decrease Alekseev [39]
SAR of 2000 W/Kg Equivalent to heating by 1.1°C
Liposomes Lipid peroxidation products / chemical analysis 42-64 GHz 20-30% increased peroxides Andreev [41]
0.15 -1 mW/cm
Liposomes (SUV)
OH-dependent lipid peroxidation / chemical
53-61-78 GHz None Logani [42,43]
10 -1- 500 mW/cm
Lymnaea neurons A-type K+ currents and Ca
/ Whole-cell voltage-clamp
60-62-75 GHz Thermal Alekseev [44]
SAR 0-2400 W/Kg
Human peripheral blood and epidermal keratinocyte
Externalization of phosphatidylserine
(PS) / fluorescence flow cytometry
42.25 GHz Ca
channel then inducing externalization of PS Szabo [45]
0.55 -1.23 W/cm
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Cationic liposomes loaded carbonic anhydrase Bilayer permeability / real-time enzymatic kinetics 130 GHz Increased substrate diffusion across bilayer Ramundo-Orlando [47]
up to 17 mW/cm
2.6-2.7 kV/cm
Lipid bilayer (Langmuir films) Lateral pressure dynamics / real-time
Wilhelmy technique
60 GHz Increased lateral pressure Zhadobov [48]
0.36 0.9 mW/cm
No modification lipid domain organization
Human glial cell line U-251 MG Endoplasmic reticulum stress / real-time PCR 60.4 GHz No modification on expression of ER-stress sensor
Nicolaz [49,50]
0.14 mW/cm
Human leukemia K562 Endoplasmic reticulum/TEM analysis 53.37-78.33 Ultrastrucutural modification Beneduci [51,52]
Giant vesicles Morphological alteration / real-time optical
53.37 GHz Elongation- induced diffusion of fluorescent
dye- increased
movement of vesicles- attraction
Ramundo-Orlando [54]
0.1 mW/cm
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and concentration of ice-like clusters consisting of a large number of water molecules
bound by hydrogen bonds [32,33].
The fact that water can be a peculiar kind of information carrier and can have memory of
physicochemical and structural properties altered under the action of weak millimeter
waves have been also studied by Cojocaru et al. [34]. The authors used the same exposure
regime as in previous works [32,33]. The effect of irradiation to 42.25 GHz (CW), at
2 mW/cm
, directly on water in eliciting the changes of wheat seed germination rate was
reported, suggesting that the main acceptor of MMW radiation is water. Its well known that
the liquid water is the strongest absorber of millimeter waves: it reduces their energy
hundreds to tens of thousands of times [35]. In this context, Ayrapetyan et al.[36] reported
that the non-thermal effects of irradiation to 160 GHz modulated at 4 Hz, with a specific
absorption rate (SAR) of 1.8 mW/g, were directly on water and able to affect heart muscle
contractility. The authors suggested that the increase of the specific electrical conductivity
of cell bathing water solution during MMW radiation induces possible changes of water
dissociation. Furthermore MMW-induced elevation of water dissociations leads to the
formation of reactive oxygen species (ROS) that, in turn, modulates Ca-dependent
metabolic mechanisms responsible for increased heart muscle contractility [36]. Recently,
Kalantaryan et al.[37] reported that the effects of MMW irradiation increased the thermo
stability and density of water-salt solution of DNA. The authors measured by
spectrophotometry and densitometry the changes of the physical properties of DNA
solutions irradiated to 64.5 GHz, amplitude modulated at 1 Hz, with incident power density
of 50 μW/cm
. It has been suggested that the effect of 64.5 GHz, in correspondence with
resonance frequency of oscillations of hexagonal structure of water, was direct on water
solution, and by changing the structure of bound water the thermo stability of different
nucleotide pairs can consequently change.
Cojocaru et al. also reported [34] that irradiation to 42.25 GHz, with energy flux density
of 3 mW/cm
, and the carrier frequency modulated at 16 Hz, increased the electrical
conductivity of lipid bilayer membranes. The authors measured the conductance by
following the proton transport through black lipid membranes (BLM) in the presence of
proton carriers such as bithionol, epigallocatechol and gossypol. The increase of electrical
conductivity of lipid bilayer membranes exposed to MMW was depended on concentration
of the carriers in the solution, pH of the medium, the dissociation coefficient pK of the
carrier, and the ratio between the dissociated forms of the carrier at the membrane boundary
(liquid-medium interface). The increase of electrical conductivity of lipid bilayer
membranes was related to the enhancement of the convective flow in the aqueous solutions
and, especially, in the nonmixed near-membrane layer, which leads to a significant increase
in the passive proton transport through membranes.
In this context Yemets [38] reported that exposure to 38 GHz radiation (CW), at a
maximum output power of 0.4 mW, lowered the energy value of activating Cl
exchange (antiport of ions), i.e. the energy barrier height, through human erythrocyte
membrane. The antiport was realized by placing erythrocytes into non-buffer isotonic
medium having lower concentration of chlorine ions. The authors suggested that the MMW
radiation indirectly speeds up the transmembrane Cl
antiport, causing motion of the
air bubbles in the liquid medium. Their motion provide mixing-up of the liquid medium,
which leads to decreasing the thickness of a near-membrane liquid layer, thus facilitating
the diffusion of a molecule from intercellular medium into the cell. The mixing-up
efficiency is proportional to the temperature thickness gradient formed under MMW
irradiation. It is known that when an open surface of the liquid medium is irradiated from
above, the latter is heated. Herewith, a temperature thickness gradient is created.
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On the other hand, Alekseev and Ziskin [39] reported only slight effects on black lipid
membranes (BLM) induced by exposure to 53-78 GHz (CW), at SAR of 2000 W/Kg.
MMW exposure decreased reversibly the capacitance of the unmodified BLM by 1.2% ±
0.5%. The changes of conductance (ionic channels current) of BLM modified in the
presence of gramicidin A, and amphotericin B were small (0.6%±0.4%). At the same time
the changes of the transport of lipid-soluble tetraphenylboron (TPhB) anions in BLM
modified in the presence of TPhB were reversible increased by 5% ± 1%. No frequency-
specific effects as well as no noticeable structural changes in the membrane were revealed
in agreement with results obtained by Motzkin [40], who did not observe any noticeable
changes in fluidity of irradiated liposomes. The authors indicated that all changes in
membrane capacitance and currents were equivalent to heating by approximately 1.1°C.
It has been suggested by Cojocaru et al.[34] that another possible cause of the increase
in the electrical conductivity of membranes induced by MMW radiation could be the
activation of lipid peroxidation. This assumption was supported by early data [41] on a 20-
30% increase of lipid peroxidation products in 15 min after exposure of liposome samples
to 42-64 GHz radiations, at 0.15-1 mW/cm
. The observed effect was attributed to
structural changes in membranes and water surrounding the membranes. On the contrary,
no enhancement in the formation of lipid peroxides was reported by Logani and Ziskin [42]
that exposed liposome samples to frequencies of 53.6, 61.2 and 78.2 GHz (CW), at incident
power densities of 10, 1 and 500 mW/cm
, respectively. These frequencies have been found
particularly useful for the treatment of various diseases. Further the same authors [43]
indicated that irradiation with 25 mW/cm
continuous millimeter waves at 53.6 GHz did
not inhibit lipid peroxidation induced by hydroxyl radicals (
OH). Since the power level
(25 mW/cm
) applied in this study is commonly used in cancer therapy, it has been
suggested that the beneficial effects of MMW in reducing the toxic effect of chemotherapy
could not be related to the inhibition of
OH-dependent lipid peroxidation.
Successively, Alekseev and Ziskin [44] reported effects of exposures to 60.22÷62.22 and
75 GHz (CW), with SAR in the range of 0-2400 W/Kg, on Lymnaea stagnalis neurons. The
authors examined the effects of MMW on Ca
and fast-inactivating A-type K
with a whole-cell voltage clamp technique. They concluded that the reversible changes in
the amplitudes and kinetics of both currents resulted from the temperature rise produced by
irradiation, suggesting that the membrane surface charge and binding of calcium ions to the
membrane in the area of channel locations did not change.
Szabo et al. [45] studied the effect to 42.25 GHz radiations, at spatial-average incident
power of 0.55 and 1.23 W/cm
, on human peripheral blood and epidermal keratinocyte
(HaCaT cells). MMW exposure was capable of inducing reversible externalization of
phosphatidylserine (PS) molecules in the membrane of the exposed cells without detectable
membrane damage or induction of cell death. Externalization is the rotation of the
negatively charged pole of PS molecule from the inner surface of the cell membrane to the
outer ones. This phenomenon is considered an early event of programmed cell death
allowing recognition of apoptotic cells by phagocytes [46]. Since the presence of
extracellular calcium was found to be required for the externalization to occur the authors
suggested that the direct effect of MMW was on the calcium channel, indirectly causing
externalization of the PS molecule.
Changes on the permeability of lipid bilayer membranes were reported by Ramundo-
Orlando et al.[47]. The effects induced by 130 GHz radiations, pulse-modulated at low
frequencies of 5, 7 or 10 Hz, and at time-averaged incident intensity (I
) up to 17 mW/cm
were studied in real-time during the irradiation of cationic liposomes loaded with carbonic
anhydrase. The increase of the substrate diffusion across lipid bilayer induced by MMW
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was taken as an index of induced permeability change. The higher substrate influx rate
resulted at I
7.7 mW/cm
when the pulse repetition rate was 7 Hz. It is worth nothing that
liposome bilayer is about 4 nm thick and that the peak electric field applied through the
130 GHz radiations was up to 2700 V/cm, about 2 orders of magnitude lower than naturally
developed across lipid bilayers. Since a clear role of the peak electric field resulted in these
studies, with a windoweffect around 2.6-2.7 kV/cm, the authors hypothesized a possible
rectification of MMW pulse by liposome, which in turn could lead to change in the lipid
membrane permeability.
Zhadobov et al.[48] reported of exposures of lipid membrane model to 60 GHz
radiations, at 0.36-0.9 mW/cm
. The authors studied alterations of the lateral pressure
dynamics within phospholipid monolayer formed by Langmuir-Blodgett method. The
lateral pressure dynamic is a membrane property highly sensitive to small changes in
membrane composition, and has a clear mechanistic link to protein function: In the cell
membrane the dynamic property of the bilayer can indirectly influence the interaction of
membrane protein and bilayer components (lipids or other membrane soluble molecules).
The authors reported a significant increase of superficial pressure in phospholipid
monolayers during the exposures even at very low power densities (9 μW/cm
). However
no significant transformations in the phospholipid domain organization were observed after
5 h of exposure as resulted by topographic AFM analysis.
Recently, Nicolaz et al. [49] reported the absence of direct effect of exposure to
60.4 GHz (CW) radiation. The authors studied the effect of MMW radiations on
endoplasmic reticulum (ER) stress in human glial cell line (U-251 MG). ER is a cellular
organelle formed of a membrane-interconnected network of tubules, vesicles and cisternae.
ER is the site of synthesis and folding of secreted proteins, for this reason is very sensitive
to environmental insults and its homeostasis is altered in various pathologies. The authors
reported that various time of exposure (24, 46 and 72 h) to 60.4 GHz, at 0.14 mW/cm
, did
not modify the expression of ER-stress sensor (BiP/GRP78) examined by real-time PCR.
Successively, the same authors [50] confirmed the previous results on ER stress by using
thirteen frequency points between 59.1 and 61.2 GHz (CW) to irradiate the glial cell line in
order to evaluate the role of the exact exposure frequency in correspondence of the peak of
absorption of molecular oxygen. Great care was also taken to avoid any possible artifactual
thermal effects.
On the other hand, Beneduci et al. have suggested endoplasmic reticulum to be potential
target of MMW. The authors indicated that MMW-irradiated (53.37- 78.33 GHz, 1 μW/
cells line K562 [51] and MCF-7 [52] presented ultrastructural modification of their ER
compartment as resulted by transmission electron analysis. Recently, Titushkin et al.[53]
reported alterations induced by 94 GHz irradiation, at power density of 18.6 kW/cm
dynamics in P19-derived neuron-like cells. The authors suggested that the activation
of N-type calcium channels and G-protein-coupled receptors in the plasma membrane
induced by MMW, in turn could lead to Ca
release from ER.
Recently, Ramundo-Orlando et al. [54] reported the effect of 53.37 GHz radiations on
giant vesicles. This membrane model system have a size in the micrometer range (i.e. are of
cell size), thus allowing direct observation, under optical microscope, of membrane
response to external stimuli. Real time exposures to MMW resulted in three distinct effects:
on vesicles geometry, i.e. elongation consisting of an increase in their lengths and changes
in their direction angle; induced diffusion of fluorescent dye, di-8-ANEPPS, located in the
region between the aqueous phase and hydrocarbon interior of the lipid bilayer; and an
increase of movement of vesicles in the aqueous medium and relative attraction among
them. A local specific absorption rate (SAR
) of 0.12±0.01 W/Kg was calculated for the
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vesicles under irradiation. The authors suggested that the major factor determining the
overall perturbation of the vesicles was the action of the field on charged and dipolar
residues located at membrane-water interface. Its worth emphasizing that the MMW effects
were fully reversible and not dependent on thermal energy.
5 Conclusion
In this review emphasis has been given to the low-level MMW effects on cell membranes.
Above all, it should be mentioned that the reported effects are of a non-thermal character,
that is, the action of radiation does not produce essential heating of the biological system or
destroy its structure. In this context it appears that no permanent structural change of lipid
bilayer could arise under low level (less than 10 mW/cm
) millimeter waves irradiation.
On the other hand, MMW radiation may affect intracellular calcium activities, and, as a
consequence, several cellular and molecular processes controlled by Ca
themselves. The effects of MMW radiation on ion transport may be the consequence of a
direct effect on membrane proteins as well as on phospholipid domain organization. Water
molecules seem to play an important role in these biological effects of MMW radiation.
Unfortunately, detailed cellular and molecular mechanisms mediating physiological
responses to MMW exposure remain largely unknown.
Usually the search at a molecular level is simpler if we can reduce the complexity of our
biological samples. This is the case for cell membranes by using model systems. They can
be formed by a simple lipid bilayer without interfering components and they give
independence from biological activity that can create complication in searching for
electromagnetic fields bioeffects. The emphasis is on the search for molecular mechanisms
of the membrane effect induced by MMW with different frequencies and power density.
Furthermore, replication studies are needed including good temperature control and appropriate
internal control samples. It is also advantageous if the future studies are multidisciplinary,
invoking an integration of high quality exposure and effects methodologies.
Clearly a significant amount of accurate experimental work is still required in order to
fully understand the interactions between MMW radiation and cell membrane.
1. M.A. Rojavin, M.C. Ziskin, Medical application of millimeter waves. Q J M 91 (1998) 57-66.
2. V.N. Skresanov, I.V. Kas, E.A. Okhryamkina, V.P. Palamrchuck, and L. Tondy, Complex treatment
cardiovascular disease with a low power millimeter-wave radiation. In Proc. IEEE 4th Int. Kharkov Symp.
Phys. Eng. Microwaves, Millimeter, Submillimeter. Waves, Kharkov, Ukraine, vol.2 (2001) 939-940.
3. A.G. Pakhomov, Y. Akyel, O.N. Pakhomova, B.E.Stuck and M.R. Murphy, Current state and implications of
research on biological effects of millimeter wave. Bioelectromagnetics 19 (1998) 393-413.
4. X.-H. Li, J.-T. Tang, Y.-P. Liao, H.-K. Jin, J.-M. Zhou, G.-H. Wang, H. Wang, Millimeter wave in the
treatment of acute radiation-induced cervical skin ulcers. J. Clin. Rehab. Tissue Eng. Res. 12 (2008) 663-
5. M. Markov, Expanding use of pulsed electromagnetic field therapy. Elec. Biol. And Med., 26 (2007)
6. W. -D. Li, W. Wang, J.-L. Chen, Efficacy of IZL-2003 immunotherapeutic system in patients with liver
cancer. World Chinese J. Digestology 17 (2009) 3553-3557.
7. O.V. Betskii, Y.G. Yaremenko, The skin and electromagnetic waves. Millimeter Waves in Biol Med N1
(11) (1998) 3-14.
8. T.I. Usichenko, H. Edinger, V. V. Gizhko, C. Lehmann, M. Wendt and F. Feyerherd, Low-Intensity
Electromagnetic Millimeter Waves for Pain Therapy. eCAM 3 (2006) 201-207.
J Infrared Milli Terahz Waves (2010) 31:14001411 1409
Author's personal copy
9. M.C. Ziskin, Physiological mechanisms underlying millimeter wave therapy. In Bioelectromagnetics:
Current Concepts NATO Science Series, S. Ayrapetyan & M. Markov Eds. Springer Press, The
Netherlands, (2006) pp.241-251.
10. A.G., Pakhomov, M. R., Murphy, Low-Intensity Millimeter Waves as a Novel Therapeutic Modality:
non-thermal medical/biological treatments using electromagnetic waves and ionized gases. IEEE Trans
Plasma Science 20 (2000) 34-40.
11. M. Marcus, B. Pattan, Millimeter wave propagation: spectrum management implications. IEEE
Microwave Mag 6 (2005) 54-63.
12. C. Park and S. Rappaport, Short-range wireless communications for next-generation networks: UWB, 60
GHz millimetre wave WPAN, and ZigBee. IEEE Wireless Commun 14 (2007) 70-78.
13. Proceedings of International Conference on Microwave and Millimeter Wave Technology, Ed.W. Hong,
G. Yang. Nanjing, China IEEE Publisher, April 21-24, 2008.
14. ICNIRP Guidelines Guidelines for Limiting Exposure to Time-varying Electric, Magnetic, and
Electromagnetic fields (up to 300 GHz). Health Physics 74 (1998) 494-522.
15. ICNIRP Dosimetry of high frequency electromagnetic fields (100 kHz to 300 GHz) in Exposure to high
frequency electromagnetic fields, biological effects and health consequences (100 kHz-300 GHz) (Eds P.
Vecchia, R. Matthes, G. Ziegelberger J. Lin, R. Saunders, A. Swerdlow) 16 (2009) 52-62.
16. Adair, R. Biophysical Limits on Athermal Effects of RF and Microwave RadiationBioelectromagnetics 24
(2003) 39-48.
17. S. M. Motzkin, Biological effects of millimeter-wave radiation. In Biological Effects and Medical Applications
of Electromagnetic Energy. Gandhi O.P. (Ed), Prentice Hall, Hanglewood Cliffs, NJ, (1990) 373.
18. E. Postow and L. Swicord, Window effects in the millimeter-wave region, in C. Polk, E. Postow (Eds),
Handbook of Biological Effects of Electromagnetic Fields CRC Press LLC, Second Edition (1996) 537-541.
19. I. Belayev, Non-thermal Biological Effects of Microwaves, Microwave Review 11 (2005) 13-29.
20. A. Beneduci, Review on the mechanisms of interaction between millimeter waves and biological
systems, in M.E. Bernstain (Ed), Bioelectrochemistry Research Developments, NOVAScience Publishers
Inc, NewYork (2008) 35-80.
21. S.J. Webb and D.E. Dodds, Inhibition of Bacterial Cell Growth by 136 Microwaves. Nature 218 (1968)
22. W. Grundler, F. Keilmann, and H. Fröhlich, Resonant Growth Rat Response of Yeast Cells Irradiated by
Weak Microwaves. Physics Letter A62 (1977) 463-466.
23. H. Fröhlich, Biological coherence and response to external stimuli, Springer-Verlag Berlin, 1988, pp.1-
24. P. Gos, B. Eicher, J. Kohli, and W.D. Heyer, Extremely high frequency electromagnetic fields at low
power density do not affect the division of exponential phase Saccharomyces cerevisiae cells.
Bioelectromagnetics 18 (1997) 142-155.
25. G. Yu, E.A. Coln, K.H. Schoenbach, M. Gellerman, P. Fox, L. Rec, S.J. Beebe, L. Shengang, A study on
biological effects of low-intensity millimeter waves. Plasma Science IEEE Trans. 30 (2002) 1489-1496.
26. A. Beneduci, Evaluation of the potential in vitro antiproliferative effects of millimeter waves at some
therapeutic frequencies on RPMI 7932 human skin malignant melanoma cells. Cell Biochem. Biophys 55
(2009) 25-32.
27. S. Hadjiloucas, M.S. Chahal and J.W. Bowen, Preliminary results on the non-thermal effects of 200350
GHz radiation on the growth rate of S. cerevisiae cells in microcolonies. Phys. Med. Biol. 47 (2002)
28. P. Mueller, D. Ru, H. Tien, W. Wescott, Reconstitution of a cell membrane structure in vitro and its
transformation into an excitable system, Nature 194 (1962) 979-980.
29. V.M. Brovkovich, N.B. Kurilo, V.L. Barishpol, Action of millimeter-range electromagnetic radiation on
the Ca pump of sarcoplasmic reticulum. Radiobiologia 31 (1991) 268-271 (in Russian)
30. A.A. Kataev, A.A. Alexandrov, L.L. Tikhonova, G.N. Berestovsky, Frequency dependent effects of the
electromagnetic millimeter waves on the ion currents in the cell membrane of Nitellopsis: Non thermal
action. Biofizika 38(1993) 446-462. (In Russian)
31. V.I. Geletyuk, V.N. Kazachenko, N.K. Chemeris, E.E. Fesenko, Dual effects of microwaves on single
Ca2+-activated K+ channels in cultured kidney cells Vero. FEBS Letters 359 (1995) 85-88.
32. E.E. Fesenko, V.I. Geletyuk, V.N. Kazachenko, N.K. Chemeris, Preliminary microwave irradiation of
water solutions changes their channel-modifying activity. FEBS Letters 366 (1995) 49-52.
33. E.E. Fesenko, and A.Ya. Gluvstein, Changes in the state of water, induced by radiofrequency
electromagnetic fields. FEBS Letters 367 (1995) 53-55.
34. A.F. Cojocaru, N.L. Cojocaru and Zh.I. Burkovetsakaya, Mechanisms of water-mediated action of weak
radio-frequency electromagnetic radiation on biological objects. Biophysics 50 (2005) S141-S156.
35. O.V. Betskii, N.D. Devyatkov, V.V. Kislov, Low intensity millimeter waves in medicine and biology.
Critical Reviewsin Biomedical Engineering 28 (2000) 247-268.
1410 J Infrared Milli Terahz Waves (2010) 31:14001411
Author's personal copy
36. G.S. Ayrapetyan, E.H. Dadasyan, E.R. Mikaleyan, S.V. Barseghyan, S. Ayrapetyan, Cell bathing
medium as a target for non-thermal effect of MMW on heart muscle contractility. Progress in Elect.
Magnetic Res. Symposium, Moscow, Russia (2009) 1057-1060.
37. V. P. Kalantaryan, Y.S. Babayan, E.S. Gevorgyan, S.N. Hakobayan, A.P. Antoyan, P.O. Vardevayan,
Influence of low intensity coherent electromagnetic millimeter radiation on aqua solution of DNA. Prog.
In Electromagnetics Res. Letters 13 (2010) 1-9.
38. B.G. Yemets, On causes of biological efficiency of low-intensive millimeter waves. Int. J. Infrared and
Millimeter Waves 19 (1998) 1587-1593.
39. S.I. Alekseev, and M.C. Ziskin, Millimeter microwave effect on ion transport across lipid bilayer
membranes. Bioelectromagnetics 16 (1995) 124-131.
40. S.M. Motzkin, Low power continuous wave millimeter irradiation fails to produce biological effects in
lipid vesicles, mammalian muscle cells, and E.coli. Digest of papers from Int. SymposiumMMW of
non-thermal intensity MedicineMoscow USSR Academy of Sciences, (1991) 367-368.
41. V.E. Andreev, O.V. Betskii, S.A. Ilina, K.D. Kazarinov, and A.V. Putvinskii, in Non thermal Effects of
Extremely High Frequency Electromagnetic Radiation, Moscow (1981) 167-176.
42. M.K. Logani and M.C. Ziskin, Continuous millimeter-wave radiation has no effect on lipid peroxidation
in liposomes. Rad. Res. 145 (1996) 231-235.
43. M.K. Logani and M.C. Ziskin, Millimeter waves at 25 mW/cm
have no effect on hydroxyl radical-
dependent lipid peroxidation. Electro and Magneto Biology, 17 (1998) 67-73.
44. S.I. Alekseev and M.C. Ziskin, Effects of millimeter waves on ionic currents of Lymnaea Neurons.
Bioelectromagnetics 20 (1999) 24-33.
45. I. Szabo, J. Kappelmayer, S.I. Alekseev, and M. C. Ziskin, Millimeter wave induced reversible
externalization of phosphatidylserine molecules in cells exposed in vitro. Bioelectromagnetics 27 (2006)
46. S.J. Martin, C.P. Reutelingesperger, A.J. McGahon, J.A. Rader, R.C. Van Schie, D.M. La Face, D.R.
Green, Early redistribution of plasma membrane phosphatidylserine is a general feature of apoptosis
regardless of the initiating stimulus: Inhibition by overexpresion of Bcl-2 and Abl. J. Exp. Med. 182
(1995) 1545-1556.
47. A. Ramundo-Orlando, G. P. Gallerano, P. Stano, A. Doria, E. Giovenale, G. Messina, M. Cappelli, M.
DArienzo, I. Spassovsky, Permeability changes induced by 130 GHz pulsed radiation on cationic
liposomes loaded with carbonic anhydrase. Bioelectromagnetics 22 (2007) 303-313.
48. M. Zhadobov, R. Saileau, V. Viè, M. Hindi, L. Le Coq, and D. Thouroude, Interactions between 60-GHz
millimeter waves and artificial biological membranes: dependence on radiation parameters. IEEE Tras.
MW Theory and Tec. 54 (2006) 2534-2542.
49. C. N. Nicolaz, M. Zhadobov, F. Desmots, R. Sauleau, D. Thouroude, D. Michel, Y. Le Drean, Absence
of direct effect of low-power millimeter-wave radiation at 60.4 GHz on endoplasmic reticulum stress.
Cell Biol. Toxicol. 25 (2009) 471-478.
50. C. N. Nicolaz, M. Zhadobov, F. Desmots, A. Ansart, R. Sauleau, D. Thouroude, D. Michel, Y. Le Drean,
Absence of direct effect of low-power millimeter-wave radiation at 60.4 GHz on endoplasmic reticulum
stress. Bioelectroamgnetics 30 (2009) 365-373.
51. A. Beneduci, G. Chidichimo, S. Tripepi, E. Perrotta, F. Cufone, Antiproliferative effect of MMW on
human erythromyeloid leukemia cell line K562 in culture: ultrastructural- and metabolic-induced
changes. Bioelectrochemistry 7 (2007) 214-20.
52. A. Beneduci, G. Chidichimo, S. Tripi, E. Perrotta, Transmission elecrron microscopy study of the effects
produced by wide-band low-power millimeter waves on MCF7 human breast cancer cells in culture.
Anticancer Res. 25 (2005) 1009-1013.
53. I.A. Titushkin, V.S. Rao, W.F. Pickard, E.G. Moros, G. Shafirstein and M.R. Cho, Altered calcium
dynamics mediates P19-derived neuron-like cell responses to millimeter-wave radiation. Rad. Res. 172
(2009) 725-736.
54. A. Ramundo-Orlando, G. Longo, M. Cappelli, M. Girasole, L. Tarricone, A. Beneduci, R. Massa, The
response of giant phospholipids vesicles to millimeter wave radiations. BBA Biomembranes 1788
(2009) 1497-1507.
J Infrared Milli Terahz Waves (2010) 31:14001411 1411
Author's personal copy
... Different parts of solar electromagnetic radiation affect the metabolism and the vitality of various organisms [1][2][3][4]. Currently there are many researchers conducting experiments to explain the biological effects of different types of electromagnetic irradiation (EMI) of extremely high frequency or millimeter waves (MMW) on various organisms [3][4][5]. Key cellular targets are water molecules, membrane and genome [3][4][5]. ...
... Currently there are many researchers conducting experiments to explain the biological effects of different types of electromagnetic irradiation (EMI) of extremely high frequency or millimeter waves (MMW) on various organisms [3][4][5]. Key cellular targets are water molecules, membrane and genome [3][4][5]. ...
... MMW are a new and widespread environmental factor, which level is rising every year due to technological advancement [1][2][3]. The effects of EMI depend on diverse conditions, such as radiation intensity and frequency, duration of irradiation, growth conditions, etc. [3][4][5]. ...
The current research reports the effects of low-intensity extremely high frequency electromagnetic irradiation (EMI) of 51.8 GHz and 53.0 GHz on green microalga Parachlorella kessleri RA-002 isolated in Armenia. EMI demonstrated different effects on the growth properties of microalgae under various conditions. Under aerobic conditions a positive effect of EMI on the growth rate of P. kessleri and the content of photosynthetic pigments were observed. The data obtained indicates a significant role of O 2 , since the enhancing effect of EMI was determined only under aerobic conditions. Meanwhile under anaerobic conditions EMI with both frequencies caused inhibition of algal growth and a decrease in the amount of photosynthetic pigments. EMI also inhibited the yield of H 2 production in P. kessleri, which was partially restored after 5-day cultivation due to the existence of protective mechanisms in this alga. The results might indicate membrane-bound mechanisms of EMI action on algae, which can be associated with the effects on photosynthetic pigments and membrane-associated enzymes responsible for H 2 production. The results are useful for the development of algae biotechnology and the possibility of using EMI as a factor which regulates the production of biomass and biohydrogen by green microalgae.
... Due to the characteristics of millimeter-wave irradiation, it is an environmen compatible technology with minimal risks to human health, which is important for tainable development and deserves research on its impact [17]. The effective mechan of millimeter waves was the induction of thermal energy into the biological sys through incident irradiation, resulting in localized heating of water molecules on the face of cell membranes [18]. Additionally, several non-thermal effects of millimeter-w irradiation were discovered, revealing that optimum millimeter-wave irradiation sti lated cell division, enzyme synthesis, growth rate, and biomass yield of a variety of mi organisms [19]. ...
... Due to the characteristics of millimeter-wave irradiation, it is an environmentally compatible technology with minimal risks to human health, which is important for sustainable development and deserves research on its impact [17]. The effective mechanism of millimeter waves was the induction of thermal energy into the biological system through incident irradiation, resulting in localized heating of water molecules on the surface of cell membranes [18]. Additionally, several non-thermal effects of millimeter-wave irradiation were discovered, revealing that optimum millimeter-wave irradiation stimulated cell division, enzyme synthesis, growth rate, and biomass yield of a variety of microorganisms [19]. ...
Full-text available
Flooding impairs wheat growth and considerably affects yield productivity worldwide. On the other hand, irradiation with millimeter waves enhanced the growth of chickpea and soybean under flooding stress. In the current work, millimeter-wave irradiation notably enhanced wheat growth, even under flooding stress. To explore the protective mechanisms of millimeter-wave irradiation on wheat under flooding, quantitative proteomics was performed. According to functional categorization, proteins whose abundances were changed significantly with and without irradiation under flooding stress were correlated to glycolysis, reactive-oxygen species scavenging, cell organization, and hormonal metabolism. Immunoblot analysis confirmed that fructose-bisphosphate aldolase and β tubulin accumulated in root and leaf under flooding; however, even in such condition, their accumulations were recovered to the control level in irradiated wheat. The abundance of ascorbate peroxidase increased in leaf under flooding and recovered to the control level in irradiated wheat. Because the abundance of auxin-related proteins changed with millimeter-wave irradiation, auxin was applied to wheat under flooding, resulting in the application of auxin improving its growth, even in such condition. These results suggest that millimeter-wave irradiation on wheat seeds improves the recovery of plant growth from flooding via the regulation of glycolysis, reactive-oxygen species scavenging, and cell organization. Additionally, millimeter-wave irradiation could promote tolerance against flooding through the regulation of auxin contents in wheat.
... The lack of planetary sources and attenuation of astronomical radiation by the atmosphere has historically limited human exposure to MMWs, and the biological effects are not well characterised [10,11]. Recently, it has been demonstrated that MMWs can induce numerous effects on a cellular level, including to neuronal action potentials [12], membrane properties [13,14], and gene expression [15][16][17][18][19]. Initially, modified gene expression was attributed to the heat shock response of cells to the heating associated with absorption of the MMWs, however it has been shown these modifications are not solely due to thermal effects and the interaction mechanisms driving this altered transcriptomic profile remain an area of interest [15]. ...
... In this work we have correlated altered gene expression with genomic modifications and collagen production, describing a potential MMW interaction mechanism not associated with the typical cellular thermal response and the downstream effects. Previously, MMWs have been shown to induce a range of biological effects at the cellular level, including alterations to neuronal action potentials [12], membrane properties [13,14], and gene expression [15][16][17][18][19]. Of studies investigating the effects of MMWs on gene expression, most use either low power exposures and find minimal alterations [16][17][18], or very high powers, inducing significant heating and alterations of heat-shock related genes [15,19]. ...
As millimetre wave (MMW) frequencies of the electromagnetic spectrum are increasingly adopted in modern technologies such as mobile communications and networking, characterising the biological effects is critical in determining safe exposure levels. We study the exposure of primary human dermal fibroblasts to MMWs, finding MMWs trigger genomic and transcriptomic alterations. In particular, repeated 60 GHz, 2.6 mW cm-2, 46.8 J cm-2 d-1 MMW doses induce a unique physiological response after 2 and 4 days exposure. We show that high dose MMWs induce simultaneous non-thermal alterations to the transcriptome and DNA structural dynamics, including formation of G-quadruplex and i-motif secondary structures, but not DNA damage.
... Many studies have shown that biological systems exposed to extremely high frequency microwaves may suffer significant effects via non-thermal mechanisms primarily involving the interaction of microwaves with phospholipid membrane structures. Biological membranes are likely to be highly sensitive to frequencies in the 1-80 GHz range (14) . Zhadobov et al. (15) found that membrane system exposure at 60 GHz significantly increased the lateral pressure of phospholipid monolayer films at power densities as low as 9 μW/cm 2 , although there was no statistically significant phospholipid microdomain reorganization. ...
... [ DOI: 10.52547/ijrr.19.3.483 ] [ Downloaded from on 2021-[12][13][14] ...
... Owing to the characteristics, millimeter-wave irradiation is an environmentally appropriate technology with small threats to human health, which is important for sustainable development and worthy for research on their effects. First of all is the induction of thermal energy into the biological system via incident irradiation, which resulted in local heating of water molecules in surface cell membranes [39]. Moreover, many non-thermal effects of millimeter-wave irradiation were discovered. ...
Full-text available
Electromagnetic energy is the backbone of wireless communication systems, and its progressive use has resulted in impacts on a wide range of biological systems. The consequences of electromagnetic energy absorption on plants are insufficiently addressed. In the agricultural area, electromagnetic-wave irradiation has been used to develop crop varieties, manage insect pests, monitor fertilizer efficiency, and preserve agricultural produce. According to different frequencies and wavelengths, electromagnetic waves are typically divided into eight spectral bands, including audio waves, radio waves, microwaves, infrared, visible light, ultraviolet, X-rays, and gamma rays. In this review, among these electromagnetic waves, effects of millimeter waves, ultraviolet, and gamma rays on plants are outlined, and their response mechanisms in plants through proteomic approaches are summarized. Furthermore, remarkable advancements of irradiating plants with electromagnetic waves, especially ultraviolet, are addressed, which shed light on future research in the electromagnetic field.
... However, their probably adverse effects on human body tissues from such electromagnetic sources should appraise to ensure safety of human body. Some biological effects of electromagnetic fields such as cancer, blood brain barrier, the brain tumor, Cataract, skin disease, sleep disorder have been reported [24][25][26][27] . The other effects of mmW frequency are genotoxicity (DNA damage), cell proliferation, gene expression, cell signaling, electrical activity, and membrane effects have been briefed in 28 . ...
Full-text available
In this paper three different multi stub antenna arrays at 27–29.5 GHz are designed. The proposed antenna arrays consist of eight single elements. The structure of feeding parts is the same but the radiation elements are different. The feeding network for array is an eight way Wilkinson power divider (WPD). To guarantee the simulation results, one of the proposed structures is fabricated and measured (namely the characteristics of S 11 , E-, and H-plane patterns) which shows acceptable consistency with measurement results. The simulation results by CST and HFSS show reasonable agreement for reflection coefficient and radiation patterns in the E- and H- planes. The overall size of the proposed antenna in maximum case is 29.5 mm × 52 mm × 0.38 mm (2.8 $${{\varvec{\lambda}}}_{0}$$ λ 0 × 4.86 $${{\varvec{\lambda}}}_{0}$$ λ 0 × 0.036 $${{\varvec{\lambda}}}_{0}$$ λ 0 ). Moreover, for Specific Absorption Rate (SAR) estimation, a three-layer spherical human head model (skin, skull, and the brain) is placed next to the arrays as the exposure source. The simulation results show that the performance of proposed antennas as low-SAR sources makes them ideal candidates for the safe usage and lack of impact of millimeter waves (mmW) on the human health. In all three cases of SAR simulations the value of SAR 1g and SAR 10g are below the standard limitations.
... There are more updated reviews of the MMW frequency range [273,325] with the most recent from Simko and Mattson [326] and Alekseev and Ziskin [327]. ...
Ambient levels of electromagnetic fields (EMF) have risen sharply in the last 80 years, creating a novel energetic exposure that previously did not exist. Most recent decades have seen exponential increases in nearly all environments, including rural/remote areas and lower atmospheric regions. Because of unique physiologies, some species of flora and fauna are sensitive to exogenous EMF in ways that may surpass human reactivity. There is limited, but comprehensive, baseline data in the U.S. from the 1980s against which to compare significant new surveys from different countries. This now provides broader and more precise data on potential transient and chronic exposures to wildlife and habitats. Biological effects have been seen broadly across all taxa and frequencies at vanishingly low intensities comparable to today’s ambient exposures. Broad wildlife effects have been seen on orientation and migration, food finding, reproduction, mating, nest and den building, territorial maintenance and defense, and longevity and survivorship. Cyto- and geno-toxic effects have been observed. The above issues are explored in three consecutive parts: Part 1 questions today’s ambient EMF capabilities to adversely affect wildlife, with more urgency regarding 5G technologies. Part 2 explores natural and man-made fields, animal magnetoreception mechanisms, and pertinent studies to all wildlife kingdoms. Part 3 examines current exposure standards, applicable laws, and future directions. It is time to recognize ambient EMF as a novel form of pollution and develop rules at regulatory agencies that designate air as ‘habitat’ so EMF can be regulated like other pollutants. Wildlife loss is often unseen and undocumented until tipping points are reached. Long-term chronic low-level EMF exposure standards, which do not now exist, should be set accordingly for wildlife, and environmental laws should be strictly enforced.
... MMW irradiation is reported to interact with cell compartments such as membranes, cytoskeletons, chromosomes, and nuclei [30][31][32][33]. Biological membranes are suggested to be the main target of MMW irradiation within 1-80 GHz [34,35]. 50 GHz MMW exposure at 10 mW/cm 2 for 2 min resulted in a transient membrane permeability change in immortalized epithelial H1299 cells [36]. ...
Full-text available
Therapeutically effective treatments of cancer are limited. To calibrate the efficiency of the novel technique we recently discovered to modulate cancer cell viability using tuned electromagnetic fields; H1299 human lung cancer cells were irradiated in a sweeping regime of W-band (75-105 GHz) millimeter waves (MMW) at 0.2 mW/cm 2 (2 W/m 2). Effects on cell morphology, cell death and senescence were examined and compared to that of non-tumorigenic MCF-10A human epithelial cells. MMW irradiation led to alterations of cell and nucleus morphology of H1299 cells, significantly increasing mortality and senescence over 14 days of observation. Extended irradiation of 10 min duration resulted in complete death of exposed H1299 cell population within two days, while healthy MCF-10A cells remained unaffected even after 16 min of irradiation under the same conditions. Irradiation effects were observed to be specific to MMW treated H1299 cells and absent in the control group of non-irradiated cells. MMW irradiation affected nuclear morphology of H1299 cells only and not of the immortalized MCF-10A cells. Irradiation with low intensity MMW shows an antitumor effect on H1299 lung cancer cells. This method provides a novel treatment modality enabling targeted specificity for various types of cancers.
Zygosaccharomyces rouxii is an osmotolerant yeast that is responsible for the spoilage of high sugar content foods. Microwave heating technology is used as an alternative to conventional pasteurization. Main purpose of this research was to determine the thermal resistance of Z. rouxii in organic intermediate moisture content (IMC) fruits (apricot and fig) during the microwave pasteurization process and comparing the D, z and F values with the conventional method. F85 values were calculated both theoretically and experimentally. Additionally, the effects of the pasteurization methods on the quality properties (total soluble solid, pH, acidity, water activity, moisture content, rehydration capacity, weight loss, hydroxymethylfurfural (HMF) and color) of the samples were investigated. The results show that come up time (CUT) and D values were significantly reduced by microwave treatment. The yeast reached a five log10 reduction by the microwave heating method with the F8533.8 value of 3.6 min for apricot and F8532.15 value of 3.35 min for fig. Total soluble solids, weight loss, and color values were preserved better in microwave pasteurization than the conventional method in both samples. Hydroxymethylfurfural content of the microwave pasteurized samples was 23.5% and 32% less than the samples pasteurized conventionally for apricot and fig samples, respectively.
Full-text available
The study presents the 5g deployment and health implication: a review. The study entails holistic research into various studies involving 5g deployment and health implication. The new parameters of 5g were highlighted; they include Millimeter Wave (mmWave), beamforming, massive MIMO and micro Cell Network. This range of frequency deployed is Non-Ionizing Radiation (NIR), which implies that it does not change the human body chemistry, but it can increase the thermal effect. The Millimeter waves are affected by tall buildings and foliage and it required a series of closely place base station, called micro-cell and with an increase in rooftop antennas. Based on different studies reviewed, it is observed that 5g does not cause immediate health damage to the human body. However, the thermal effect could be associated with millimetre-wave frequency radiation, especially with prolong calls and usage of mobile devices. Finally, the effect of millimetre-wave frequency radiation for 5g has not been ascertained.
Full-text available
The comparative study of the effects of weak intensity specific absorption rate (SAR = 1.8 mW/g) of 4Hz modulated 160 GHz millimeter wave (MMW) and near Infrared (IR) irradiation on thermodynamic properties, specific electrical conductivity (SEC) of physiological solution (PS) and hydrogen peroxide (H 2 O 2) formation in it as well as the effect of MMW-treated PS on heart muscle contractility, 45 Ca uptake was performed. The heat fusion capacity of MMW-pretreated PS after freezing by liquid nitrogen (N 2) is significantly less than the heat fusion capacity of sham and IR-treated PS. MMW unlike IR, has time-dependent elevation effect on water SEC and SAR, which is accompanied by the increase of H 2 O 2 formation in it. The direct MMW radiation, MMW-pretreated PS and H 2 O 2 -containing PS have increasing effect on heart muscle contractility. The MMW-pretreated PS and the H 2 O 2 –containing PS have activation effect on 45 Ca uptake and dehydration effect on heart muscle contractility. Thus, the obtained data allow us to consider water dissociation as a main target through which the non-thermal effect of MMW on physicochemical properties of water is realized, while the MMW-induced formation of H 2 O 2 in cell bathing medium serves as a messenger through which the modulation of intracellular metabolism takes place.
AIM: To evaluate the curative effect of the IZL-2003 immunotherapeutic system in patients with liver cancer. METHODS: Sixty-one patients with liver cancer were divided into treatment group (n = 40) and control group (n = 21). The patients in the treatment group were treated with liver-protecting drugs in combination with 35-42.8-GHz millimeter wave. The patients in the control group were treated only with liver-protecting drugs. Routine blood tests and liver function tests were performed within two weeks before treatment. T-cell subgroup detection, B-mode ultrasonic scan or computed tomography (CT) were performed within one month before treatment. Routine blood tests were performed again within two weeks after treatment, and T-cell subgroups were retested within three months after treatment. RESULTS: Millimeter-wave radiation significantly increased white cell count and hemoglobin level in patients with decreased white cell count (P = 0.028 and 0.017, respectively), but had no significant impact on blood platelet count. The counts of CD4+ and CD8+ T cells in patients with liver cancer were less than normal level (486.45 ± 255.35 and 350.05 ± 246.26 cells/μL, respectively). Millimeter-wave radiation significantly increased the counts of CD4+ and CD8 + T cells. In patients with CD4+ cell count less than 400 cells/μL, both the counts of CD4+ and CD8+ cells significantly increased after millimeterwave radiation (P = 0.03 and 0.067, respectively). Millimeter-wave radiation could effectively improve the symptoms in patients with liver cancer, and the effective rate was above 80% (P < 0.05). Millimeter-wave radiation could also improve Karnofsky performance scale (KPS) score and life quality in liver cancer patients. CONCLUSION: Millimeter-wave radiation used in the IZL-2003 immunotherapeutic system can enhance immunity, increase white cell count and hemoglobin level, improve life quality, and prevent tumor recurrence and metastasis in patients with liver cancer.
Aim: Millimeter wave is a frequency range with short wave-length and high frequency in radio wave. It has been used in the treatment of malignant tumor recently. This study was to evaluate the efficacy of millimeter wave in the treatment of acute radiation-induced cervical skin ulcers and observe the adverse events. Methods: Fifty-four patients with acute radiation-induced cervical skin ulcers after radiotherapy of nasopharyngeal cancer were enrolled at the Department of Oncology, Xiangya Hospital, Central South University from June 2004 to January 2007. All patients were assessed as II - IV degree according to the grading standards of Radiation Therapy Oncology Group. The patients were randomly divided into 2 groups. 1 Twenty-eight patients in a millimeter wave group received millimeter wave and routine therapy. MMW-1 millimeter wave therapy apparatus was produced by Beijing Zhongcheng Kangfu Technology Co., Ltd. The parameters of the apparatus were frequency 36 GHz (corresponding 8.3 mm) and output power 50 mW, once 0.78 J/cm2, once a day, nearby skin, once for 30 minutes, 10 days as a course. An additioned course could be performed depending on the dermatitis healing. 2 Twenty-six patients in the control group received placebo millimeter wave therapy and routine therapy. Detecting head of millimeter wave was located at the same place of millimeter wave therapy, but did not output, with the same therapeutic time and frequency. Ulcer healing and healing time were compared between the two groups in the 2-month follow-up. Results: Fifty-four patients were involved in the result analysis. The effective rate 93% (26/28) in the millimeter wave group was higher than that in the control group 65% (17/26) (P < 0.05). The healing time of the acute radiation-induced skin ulcers was shorter in the millimeter wave group than in the control group [(14.30±2.41), (25.33±2.00)d, P <0.01]. There was no significant difference in adverse effects between the two groups. Conclusion: Millimeter wave irradiation effectively quickens the wound healing of acute radiation-induced skin ulcers, and shortens the healing time.
A critical event during programmed cell death (PCD) appears to be the acquisition of plasma membrane (PM) changes that allows phagocytes to recognize and engulf these cells before they rupture. The majority of PCD seen in higher organisms exhibits strikingly similar morphological features, and this form of PCD has been termed apoptosis. The nature of the PM changes that occur on apoptotic cells remains poorly defined. In this study, we have used a phosphatidylserine (PS)-binding protein (annexin V) as a specific probe to detect redistribution of this phospholipid, which is normally confined to the inner PM leaflet, during apoptosis. Here we show that PS externalization is an early and widespread event during apoptosis of a variety of murine and human cell types, regardless of the initiating stimulus, and precedes several other events normally associated with this mode of cell death. We also report that, under conditions in which the morphological features of apoptosis were prevented (macromolecular synthesis inhibition, overexpression of Bcl-2 or Abl), the appearance of PS on the external leaflet of the PM was similarly prevented. These data are compatible with the notion that activation of an inside-outside PS translocase is an early and widespread event during apoptosis.
This book presents current knowledge about the effects of electromagnetic fields on living matter. The three-part format covers: dielectric permittivity and electrical conductivity of biological materials; effects of direct current and low frequency fields; and effects of radio frequency (including microwave) fields. The parts are designed to be consulted independently or in sequence, depending upon the needs of the reader. Useful appendixes on measurement units and safety standards are also included.
The authors have carried out millimeter-wave therapy (MMWT) using a frequency-modulated carrier of 42.25 GHz (λ=7.1 mm) with a deviation 200 MHz. Power flow density was 20 μW/cm2. The treatment was carried out by means of the therapeutic apparatus "ARIA-SC". The generating module with an emitter-horn antenna was installed on a support for exposure of defined zones of the bodies of patients. Originally "ARIA-SC" was intended only for treatment by a method of Sitko's wave resonance therapy. The apparatus was modified, in particular by supplementation by a series of generating modules, ensuring a realization of other techniques of MMWT. The comparative evaluation of outcomes of treatment of groups of patients has shown the great effectiveness of treatment using MMWT