Effect of Nonionizing Radiation on Progesterone Treatment in Endometrial Hyperplasia: An Experimental Rat Study

<b><i>Objectives:</i></b> The aim of the study was to evaluate the negative effect of nonionizing radiation on the treatment of endometrial hyperplasia (EH) with oral progesterone. <b><i>Design:</i></b> Forty oophorectomized Wistar Albino female rats were included in this experimental rat study. <b><i>Materials and Methods:</i></b> The 4 groups were planned as follows: Group A; sham group; Group B; group receiving oral estradiol hemihydrate 4 mg/kg/day; Group C; 4 mg/kg/day oral estradiol hemihydrate followed with 1 mg/day medroxy progesterone acetate (MPA) and Group D; 4 mg/kg/day oral estradiol hemihydrate followed with 1 mg/day MPA with exposure to nonionizing radiation at 1800 mHz/3 h/day. After the experimental model, uterine horns were sampled and the preparations were evaluated for pathological parameters (glandular density, epithelial cell length, and luminal epithelial cell length) via light microscopy. Nonionizing radiation was created by a signal generator and a compatible mobile phone. <b><i>Results:</i></b> Estrogen was found to increase all parameters related to EH (<i>p</i> &#x3c; 0.05). Progesterone treatment was found to decrease parameters related to EH (Group B vs. C; luminal epithelial cell length, glandular density, and epithelial length; 11.2 vs. 13.2 μm <i>p</i> = 0.007; 32.5 vs. 35.5, <i>p</i> = 0.068; and 219.9 μm vs. 285 µm, <i>p</i> &#x3c; 0.001, respectively). Final analyses revealed reduced effectiveness of progesterone treatment in the rats exposed to nonionizing radiation (Group C vs. D); luminal epithelial cell length, glandular density, and epithelial length (11.2 μm vs. 13.5 μm, <i>p</i> = 0.179; 32.5 vs. 52, <i>p</i> &#x3c; 0.001; and 219.9 μm vs. 374.1 μm, <i>p</i> = 0.001, respectively). <b><i>Limitations:</i></b> The limitations of our study are that the results of animal experiments may not be appropriate for direct adaptation to humans and the relatively low number of rats included in the study. <b><i>Conclusion:</i></b> Nonionizing radiation reduces the effect of progesterone in patients receiving treatment for EH.

Insights into Terminal Sterilization Processes of Nanoparticles for Biomedical Applications

Nanoparticles possess a huge potential to be employed in numerous biomedical purposes; their applications may include drug delivery systems, gene therapy, and tissue engineering. However, the in vivo use in biomedical applications requires that nanoparticles exhibit sterility. Thus, diverse sterilization techniques have been developed to remove or destroy microbial contamination. The main sterilization methods include sterile filtration, autoclaving, ionizing radiation, and nonionizing radiation. Nonetheless, the sterilization processes can alter the stability, zeta potential, average particle size, and polydispersity index of diverse types of nanoparticles, depending on their composition. Thus, these methods may produce unwanted effects on the nanoparticles’ characteristics, affecting their safety and efficacy. Moreover, each sterilization method possesses advantages and drawbacks; thus, the suitable method’s choice depends on diverse factors such as the formulation’s characteristics, batch volume, available methods, and desired application. In this article, we describe the current sterilization methods of nanoparticles. Moreover, we discuss the advantages and drawbacks of these methods, pointing out the changes in nanoparticles’ biological and physicochemical characteristics after sterilization. Our main objective was to offer a comprehensive overview of terminal sterilization processes of nanoparticles for biomedical applications.

Burns by Ionizing and Non-Ionizing Radiation

This article consists of the study and investigative analysis of the effects of burns by radiation in humans. Cases of nuclear accidents, such as Chernobyl (ionizing radiation) and the effects of non-ionizing radiation such as infrared and microwave radiation are detailed. It is examined cases of injuries and burns by ionizing radiation due to irradiation (diagnostic equipment and medical treatment: X-rays, radiotherapy) or contamination (nuclear accidents, wars). Injuries and burns are also caused by nonionizing radiation, such as visible light (laser), ultraviolet, radiofrequency. There are numerous biological issues in the case of tissues, the ionizing radiation (ionizing particles and electromagnetic radiation: X-rays, gamma rays and high energy ultraviolet) can cause damage mainly in the DNA. This can cause mutations in its genetic code and cancer 5. In addition, damage to other tissues and organs can occur, as well as burns, erythema and lesions. The biological effects of nonionizing radiation are currently under investigation. Burns, erythema and lesions can also occur due to the following types of radiation: low energy ultraviolet, visible light, infrared, microwave, radiofrequency, electromagnetic fields. The purpose of this article is to provide an exhaustive analysis of all types of both ionizing and non-ionizing radiation and their effects on living beings. Finally, it is important to follow all safety and radiation protections against both ionizing and non-ionizing radiation.

Radiofrequency electromagnetic radiation from Wi-fi and its effects on human health, in particular children and adolescents. Review

Radiofrequency electromagnetic radiation emitted from Wi-Fi devices is nonionizing radiation. The frequencies used in wireless technology are similar to those applied in mobile telephony. Due to the much lower output power of devices using Wi-Fi compared to mobile phones, the degree of exposure to radiation is also lower. Most of the research on Wi-Fi has been carried out in less favorable or adverse conditions, involving higher power values of devices (peak values instead of average values) and smaller distances of working devices from measuring points. None of the studies conducted so far have indicated that there were the exceedances of the permissible values of radiofrequency electromagnetic radiation contained in the Polish and global legal regulations. Similar to the research related to the impact of mobile telephony on human health, the studies conducted until now focusing on exposure to Wi-Fi are considered ambiguous as they do not give a definitive answer on the possible negative (including carcinogenic) effects on human health. Because of the continuous development of wireless networks, there is a need for further research on this topic. Moreover, due to the high popularity of devices using Wi-Fi among children and adolescents, whose period of exposure to electromagnetic radiation is longer compared to adults, it is necessary to continuously observe these populations and subject them to careful analysis.