The Interaction of Radio-Frequency Fields with Dielectric Materials at Macroscopic to Mesoscopic Scales

Baker–Jarvis, James R.; Kim, Sung Hoon

doi:10.6028/jres.117.001

Cited by 76 publications

(60 citation statements)

References 194 publications

(310 reference statements)

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“…Non-thermal effects of electromagnetic waves are the most difficult to identify due to the low exposure energies. Interaction of EMFs with matter can be modeled from the microscopic level to the macroscopic level (Baker-Jarvis and Sung, 2012). In theory, the electromagnetic field interactions with biological matter may be modeled on a microscopic scale by applying quantum mechanics and by using Maxwell's equations at macroscopic level.…”

Section: Introductionmentioning

confidence: 99%

Hydraulic continuity and biological effects of low strength very low frequency electromagnetic waves: Case of microbial biofilm growth in water treatment

et al. 2015

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Section: Introductionmentioning

confidence: 99%

Hydraulic continuity and biological effects of low strength very low frequency electromagnetic waves: Case of microbial biofilm growth in water treatment

et al. 2015

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“…Application of RF for medical use generates an electrical field that results is an oscillating electrical current, which in turn, induces translational motion of charged atoms and molecules and hinders rotation of polar molecules [4]. This molecular motion, largely responsible for the heat capacity, results in a local temperature increase.…”

Section: Introductionmentioning

confidence: 99%

The Effects of Heat Exposure on Vaginal Smooth Muscle Cells: Elastin and Collagen Production

Kozma

Candiotti

Póka

et al. 2018

Gynecol Obstet Invest

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Aims: To evaluate smooth muscle cells (SMCs) proliferation and elastin and collagen production after heat exposure (65°C). Methods: Samples were taken from the anterior vaginal wall, SMCs were cultured, and heated to 65°C for 30 and 60 s. Cell proliferation was assessed; tropoelastin and collagen production was measured. Results: Heat does not affect SMC proliferation at 65°C neither at 30 nor at 60 s. Surface-deposited elastin level was significantly increased after heat exposure (mean ± SD, 30 s 155 ± 5% of control [p < 0.01] and 60 s 516 ± 40% of control [p < 0.01]). Tropoelastin levels in the culture media were significantly lower after 60 s of heat exposure (mean ± SD, 30 s 102 ± 5% of control [p = ns] and 60 s 70 ± 2% of control [p = 0.04]). Significant increase in surface-deposited collagen production was found (mean ± SD, 30 s 170 ± 6% of control [p < 0.01] and 60 s 123 ± 6% of control [p < 0.01]), but no such elevation was measured in the media after heat exposure (mean ± SD, 30 s 120 ± 20% of control [p = ns] and 60 s 100 ± 20% of control [p = ns]). Conclusion: When SMCs are exposed to heat there is significant elevation in collagen and elastin production. Changes in the composition of the extracellular matrix after heat exposure may contribute to vaginal wall remodeling.

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“…In particular, biological tissues are an important class of dispersive media especially taking into account that their interaction with the electromagnetic fields has a great influence on the behavior of living systems. In fact, the increasing number of power and telecommunication systems leads to human exposure to non-ionizing radiation, causing an increased public concern about the potential health hazards [8][9][10]. On the other hand, biological tissues are involved in a variety of therapeutic and diagnostic applications of electromagnetic fields such as hyperthermia, electroporation and the treatment of specific diseases [11][12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Fractional Calculus Based FDTD Modeling of Layered Biological Media Exposure to Wideband Electromagnetic Pulses

Mescia

Bia²,

Chiapperino

et al. 2017

Electronics

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Electromagnetic fields are involved in several therapeutic and diagnostic applications such as hyperthermia and electroporation. For these applications, pulsed electric fields (PEFs) and transient phenomena are playing a key role for understanding the biological response due to the exposure to non-ionizing wideband pulses. To this end, the PEF propagation in the six-layered planar structure modeling the human head has been studied. The electromagnetic field and the specific absorption rate (SAR) have been calculated through an accurate finite-difference time-domain (FDTD) dispersive modeling based on the fractional derivative operator. The temperature rise inside the tissues due to the electromagnetic field exposure has been evaluated using both the non-thermoregulated and thermoregulated Gagge's two-node models. Moreover, additional parametric studies have been carried out with the aim to investigate the thermal response by changing the amplitude and duration of the electric pulses.

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The Interaction of Radio-Frequency Fields with Dielectric Materials at Macroscopic to Mesoscopic Scales

Cited by 76 publications

References 194 publications

Hydraulic continuity and biological effects of low strength very low frequency electromagnetic waves: Case of microbial biofilm growth in water treatment

Hydraulic continuity and biological effects of low strength very low frequency electromagnetic waves: Case of microbial biofilm growth in water treatment

The Effects of Heat Exposure on Vaginal Smooth Muscle Cells: Elastin and Collagen Production

Fractional Calculus Based FDTD Modeling of Layered Biological Media Exposure to Wideband Electromagnetic Pulses

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