Genotoxic Effects of Radiofrequency-Electromagnetic Fields

O. Demirhan
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However, man's magnetic field is also under the influence of other natural and artificial magnetic fields around him. In particular, by ionizing radiation, which carries enough energy to break down the genetic material, die cells as a result of DNA damaging, and other diseases, especially cancer, can develop as a result of tissue damage. \nElectromagnetic Fields in Our LivesToday, apart from natural geomagnetic fields, radiation is emitted from many technological devices. The spectrum of these fields includes many different types of radiation, from subatomic radiation such as gamma and X-rays to radio waves, depending on their wavelengths. Though, as a result of the rapid increase of technological growth, the duration and amount of exposure to EMF is also steadily increasing. On the other hand, wireless gadgets such as computers, smartphones and medical radiological devices have become a necessity for humans. Almost everyone is exposed to radiofrequency electromagnetic fields (RF-EMF) from cell phone and base station antennas or other sources. Thus, the damage caused by the radiation to the environment affects living organisms even many kilometres away unlimitedly. All organisms in the world live under the influence of these negative environmental changes and a large part of the world population is exposed to radiofrequency (RF) radiation for a long time in their daily lives. So, though we are not aware of it, our organs and tissues are constantly exposed to radiation. Therefore, radiation adversely affects human, animal and plant health and disrupts the environment and ecological balance. An example of negative effects, radiation can cause genetic changes in the body (Figure 1). \nRadiation is divided into ionizing and non-ionizing. Ionizing radiations cause electron loss or gain in an atom or group of atoms in the medium they pass through. Thus, positively or negatively charged ions are formed. High energy X, gamma, ultraviolet and some visible rays in the ionized region of the electromagnetic spectrum can be counted. Since gamma rays, X rays and ultraviolet rays can ionize the molecules in living things more, they can easily disrupt the chemical structure of tissues, cells and DNA molecules in living organisms. Therefore, they can be very dangerous and deadly to living things. The energy of the waves in the non-ionizing region of the electromagnetic spectrum is low and the energy levels are insufficient for the ionization of molecules. Electricity, radio and TV waves, microwaves, and infrared rays are not ionizing because they have low energy. Waves emitted from electronic devices (cell phones, computers, microwave ovens, etc.) are absorbed by the human and animal body. The amount of energy absorbed by the unit biological tissue mass per unit time is called the specific absorption rate (SAR), and its unit is W/kg. \nRisks of Electromagnetic Fields on Living ThingsDepending on the structure of the tissues and organs, the radiation must reach a certain threshold dose for the effect to occur. Radiation levels below the threshold dose are not effective. Depending on the structure of the tissues and organs, the radiation must reach a certain threshold dose. The effects of small doses of waves are negligible. However, the clinical effects of waves above a certain threshold may increase. High dose waves can cause cell death in tissues. Damages in the cell may increase the risk of cancer and hereditary damage after a while, and somatic effects in people exposed to radiation may cause cancer to appear years later. There is much research on the effects of RF fields. In vitro and in vivo studies on rats, plants and different tissues of humans; suggests that the RF fields are not genotoxic and the fact that harmful effect is due to the heat effect. The contradictory results on this issue have brought about discussions. Therefore, there are still concerns about the potential adverse effects of RFR on human health. A good understanding of the biological effects of RF radiation will protect against potential damages. Due to these uncertainties, with the electromagnetic field project of the World Health Organization, experimental and modelling studies on the biological effects of RF radiation have been accelerated. In 2011, the International Agency for Research on Cancer decided that RF-EMR waves could be potentially carcinogenic to humans (2). Considering that almost everyone, including young children, uses mobile phones in addition to other technological devices, the danger of electromagnetic waves has increased social interest. \nGenotoxic Effects of EMFIn addition to stimulating apoptosis and changes in ion channels, RF-EMF waves also have a potential effect on genetic material. The radiation absorbed by organisms causes the ionization of target molecules. In particular, biological damage may occur as a result of stimulation/ionization of atoms and disruption of molecular structures while ionizing radiation passes through tissue. As a result of ionization in the cell, electron increases and free electrons cause damage, especially in macromolecules and DNA. Free electrons move directly or indirectly. Free electrons directly affect the phosphodiester or H-bonds of DNA. As a result, the phosphodiester bonds of DNA in the cell are broken, single or double-stranded breakages and chemical toxins increase.  DNA double-strand breaks are the most relevant biologic damage induced by ionizing radiation (3,4). \nThere are no cells that are resistant to radiation. The nucleus of the cell and especially the chromosomes in dividing cells are very sensitive to radiation. One of the most important effects of radiation on the cell is to suppress cell growth. In particular, growth is impaired in cells exposed to radiation during cell division (mitosis). Consequently, cells with a high division rate are more sensitive to radiation. DNA damage in somatic cells can lead to cancer development or cell death. Cell death can occur as a result of breaking down DNA because ionizing radiation has enough energy to break down the cell's genetic material. Thus, tissues are damaged and cancer development may be triggered. DNA damage caused by radiation in cells is repaired by metabolic repair processes. If the breaks in DNA as a result of DNA damage caused by radiation in cells are not too large, they can be repaired by metabolic repair processes. Still, errors may occur during this repair. Chromosomes containing different genetic codes and information may also occur. In the cell, the released electrons interact with water molecules, indirectly causing the water to be reactively divided into two parts. Free radicals carry an electron that is not electrically shared in their orbits. Free radicals can cause genetic damage in DNA such as nucleotide changes, double and single-strand breaks. Radiation can cause chromosomes to break, stick together and rearrange. All these changes can lead to mutations or even further, the death of the cell. However, in addition to ionizing radiation, extracellular genotoxic chemicals and intracellular oxidative metabolic residues can also create stress in cells during DNA replication and cell division. Damage may occur during DNA replication under such environmental stress conditions. \nTo date, conflicting results have been reported regarding the genotoxic effects of RF-EMF waves on genetic material. It has been reported that the energy of low EM fields is not sufficient to break the chemical bonds of DNA, but the increase in exposure time is effective on the formation of oxygen radicals and the disruptions in the DNA repair process. The absorption of microwaves can cause significant local warming in cells. For example, an increase in temperature has been observed in cells in culture media exposed to waves of high SAR levels. However, there is evidence that reactive oxygen species are formed in cells indirectly and experimentally exposed to RF-EMF waves. Free oxygen radicals can create nucleotide entries in DNA as well as bind cellular components to DNA bases (5). The frequency of polymorphisms observed in DNA repair mechanism genes in children with acute leukaemia living close to high energy lines reveals the effect of this energy on the repair process.  Significant evidence has been reported that genotoxic effects occur in various cell types when exposed to RF-EMF waves (6-10). Here, it has been reported that cells exposed to RF-EMF waves (1.800 MHz, SAR 2 W/kg) cause oxidative damage in mitochondrial DNA, DNA breaks in neurons and DNA breaks in amniotic cells (6,10). Similarly, the damage has been reported in lymphocytes exposed to various RF-EMF waves (8). However, exposure to RF-EMF waves is known to cause chromosome imbalance, changes in gene expression, and gene mutations. Such deleterious genetic effects have also been reported in neurons, blood lymphocytes, sperm, red blood cells, epithelial cells, hematopoietic tissue, lung cells, and bone marrow (1,11,12). It has been found that exposure to RF-EMF radiation also increases chromosome numerical aberrations (6,13). It has also been reported that increased chromosome separation in mouse oocyte","PeriodicalId":17507,"journal":{"name":"Journal of Toxicology and Environmental Health Sciences","volume":"10 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2021-06-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Toxicology and Environmental Health Sciences","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.55124/jtes.v1i1.50","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0

Abstract

Genotoxic Effects of Radiofrequency-Electromagnetic Fields. IntroductionRadiation is energy emission in the form of electromagnetic waves emitted from the solar system and natural resources on earth. The currents produced by the elementary particles formed by the electric current create the magnetic field. Earth's surface is under the influence of the geomagnetic field emanating from the sun. However, the outer liquid also has a magnetic field created as a result of heat transfer in the core. Therefore, all living organisms on earth live under the influence of electromagnetic fields (EMF). Today, besides these natural energy resources, rapidly developing technological developments provide most of the convenience in our lives and expose people to artificial electromagnetic fields. However, man's magnetic field is also under the influence of other natural and artificial magnetic fields around him. In particular, by ionizing radiation, which carries enough energy to break down the genetic material, die cells as a result of DNA damaging, and other diseases, especially cancer, can develop as a result of tissue damage. Electromagnetic Fields in Our LivesToday, apart from natural geomagnetic fields, radiation is emitted from many technological devices. The spectrum of these fields includes many different types of radiation, from subatomic radiation such as gamma and X-rays to radio waves, depending on their wavelengths. Though, as a result of the rapid increase of technological growth, the duration and amount of exposure to EMF is also steadily increasing. On the other hand, wireless gadgets such as computers, smartphones and medical radiological devices have become a necessity for humans. Almost everyone is exposed to radiofrequency electromagnetic fields (RF-EMF) from cell phone and base station antennas or other sources. Thus, the damage caused by the radiation to the environment affects living organisms even many kilometres away unlimitedly. All organisms in the world live under the influence of these negative environmental changes and a large part of the world population is exposed to radiofrequency (RF) radiation for a long time in their daily lives. So, though we are not aware of it, our organs and tissues are constantly exposed to radiation. Therefore, radiation adversely affects human, animal and plant health and disrupts the environment and ecological balance. An example of negative effects, radiation can cause genetic changes in the body (Figure 1). Radiation is divided into ionizing and non-ionizing. Ionizing radiations cause electron loss or gain in an atom or group of atoms in the medium they pass through. Thus, positively or negatively charged ions are formed. High energy X, gamma, ultraviolet and some visible rays in the ionized region of the electromagnetic spectrum can be counted. Since gamma rays, X rays and ultraviolet rays can ionize the molecules in living things more, they can easily disrupt the chemical structure of tissues, cells and DNA molecules in living organisms. Therefore, they can be very dangerous and deadly to living things. The energy of the waves in the non-ionizing region of the electromagnetic spectrum is low and the energy levels are insufficient for the ionization of molecules. Electricity, radio and TV waves, microwaves, and infrared rays are not ionizing because they have low energy. Waves emitted from electronic devices (cell phones, computers, microwave ovens, etc.) are absorbed by the human and animal body. The amount of energy absorbed by the unit biological tissue mass per unit time is called the specific absorption rate (SAR), and its unit is W/kg. Risks of Electromagnetic Fields on Living ThingsDepending on the structure of the tissues and organs, the radiation must reach a certain threshold dose for the effect to occur. Radiation levels below the threshold dose are not effective. Depending on the structure of the tissues and organs, the radiation must reach a certain threshold dose. The effects of small doses of waves are negligible. However, the clinical effects of waves above a certain threshold may increase. High dose waves can cause cell death in tissues. Damages in the cell may increase the risk of cancer and hereditary damage after a while, and somatic effects in people exposed to radiation may cause cancer to appear years later. There is much research on the effects of RF fields. In vitro and in vivo studies on rats, plants and different tissues of humans; suggests that the RF fields are not genotoxic and the fact that harmful effect is due to the heat effect. The contradictory results on this issue have brought about discussions. Therefore, there are still concerns about the potential adverse effects of RFR on human health. A good understanding of the biological effects of RF radiation will protect against potential damages. Due to these uncertainties, with the electromagnetic field project of the World Health Organization, experimental and modelling studies on the biological effects of RF radiation have been accelerated. In 2011, the International Agency for Research on Cancer decided that RF-EMR waves could be potentially carcinogenic to humans (2). Considering that almost everyone, including young children, uses mobile phones in addition to other technological devices, the danger of electromagnetic waves has increased social interest. Genotoxic Effects of EMFIn addition to stimulating apoptosis and changes in ion channels, RF-EMF waves also have a potential effect on genetic material. The radiation absorbed by organisms causes the ionization of target molecules. In particular, biological damage may occur as a result of stimulation/ionization of atoms and disruption of molecular structures while ionizing radiation passes through tissue. As a result of ionization in the cell, electron increases and free electrons cause damage, especially in macromolecules and DNA. Free electrons move directly or indirectly. Free electrons directly affect the phosphodiester or H-bonds of DNA. As a result, the phosphodiester bonds of DNA in the cell are broken, single or double-stranded breakages and chemical toxins increase.  DNA double-strand breaks are the most relevant biologic damage induced by ionizing radiation (3,4). There are no cells that are resistant to radiation. The nucleus of the cell and especially the chromosomes in dividing cells are very sensitive to radiation. One of the most important effects of radiation on the cell is to suppress cell growth. In particular, growth is impaired in cells exposed to radiation during cell division (mitosis). Consequently, cells with a high division rate are more sensitive to radiation. DNA damage in somatic cells can lead to cancer development or cell death. Cell death can occur as a result of breaking down DNA because ionizing radiation has enough energy to break down the cell's genetic material. Thus, tissues are damaged and cancer development may be triggered. DNA damage caused by radiation in cells is repaired by metabolic repair processes. If the breaks in DNA as a result of DNA damage caused by radiation in cells are not too large, they can be repaired by metabolic repair processes. Still, errors may occur during this repair. Chromosomes containing different genetic codes and information may also occur. In the cell, the released electrons interact with water molecules, indirectly causing the water to be reactively divided into two parts. Free radicals carry an electron that is not electrically shared in their orbits. Free radicals can cause genetic damage in DNA such as nucleotide changes, double and single-strand breaks. Radiation can cause chromosomes to break, stick together and rearrange. All these changes can lead to mutations or even further, the death of the cell. However, in addition to ionizing radiation, extracellular genotoxic chemicals and intracellular oxidative metabolic residues can also create stress in cells during DNA replication and cell division. Damage may occur during DNA replication under such environmental stress conditions. To date, conflicting results have been reported regarding the genotoxic effects of RF-EMF waves on genetic material. It has been reported that the energy of low EM fields is not sufficient to break the chemical bonds of DNA, but the increase in exposure time is effective on the formation of oxygen radicals and the disruptions in the DNA repair process. The absorption of microwaves can cause significant local warming in cells. For example, an increase in temperature has been observed in cells in culture media exposed to waves of high SAR levels. However, there is evidence that reactive oxygen species are formed in cells indirectly and experimentally exposed to RF-EMF waves. Free oxygen radicals can create nucleotide entries in DNA as well as bind cellular components to DNA bases (5). The frequency of polymorphisms observed in DNA repair mechanism genes in children with acute leukaemia living close to high energy lines reveals the effect of this energy on the repair process.  Significant evidence has been reported that genotoxic effects occur in various cell types when exposed to RF-EMF waves (6-10). Here, it has been reported that cells exposed to RF-EMF waves (1.800 MHz, SAR 2 W/kg) cause oxidative damage in mitochondrial DNA, DNA breaks in neurons and DNA breaks in amniotic cells (6,10). Similarly, the damage has been reported in lymphocytes exposed to various RF-EMF waves (8). However, exposure to RF-EMF waves is known to cause chromosome imbalance, changes in gene expression, and gene mutations. Such deleterious genetic effects have also been reported in neurons, blood lymphocytes, sperm, red blood cells, epithelial cells, hematopoietic tissue, lung cells, and bone marrow (1,11,12). It has been found that exposure to RF-EMF radiation also increases chromosome numerical aberrations (6,13). It has also been reported that increased chromosome separation in mouse oocyte
射频电磁场的基因毒性效应
射频电磁场的基因毒性效应。辐射是以电磁波的形式从太阳系和地球上的自然资源中发射出来的能量。由电流形成的基本粒子产生的电流产生磁场。地球表面受到太阳发出的地磁场的影响。然而,外层液体也有一个磁场,这是由于核心的热传递而产生的。因此,地球上的所有生物都生活在电磁场(EMF)的影响下。今天,除了这些自然能源,快速发展的技术发展为我们的生活提供了大部分的便利,并使人们暴露在人工电磁场中。然而,人的磁场也受到周围其他自然和人工磁场的影响。特别是电离辐射,它携带足够的能量来分解遗传物质,由于DNA损伤而导致死亡细胞,以及其他疾病,特别是癌症,可能由于组织损伤而发展。今天,除了自然地磁场外,许多科技设备也会发出辐射。这些场的光谱包括许多不同类型的辐射,从亚原子辐射,如伽马射线和x射线到无线电波,取决于它们的波长。虽然,由于技术的迅速发展,接触电磁场的时间和数量也在稳步增加。另一方面,诸如电脑、智能手机和医疗放射设备等无线设备已成为人类的必需品。几乎每个人都暴露在来自手机和基站天线或其他来源的射频电磁场(RF-EMF)中。因此,辐射对环境造成的损害甚至无限地影响许多公里外的生物。世界上所有生物都生活在这些负面环境变化的影响下,世界上很大一部分人口在日常生活中长时间暴露在射频辐射下。所以,虽然我们没有意识到,但我们的器官和组织一直暴露在辐射中。因此,辐射对人类、动物和植物的健康产生不利影响,破坏环境和生态平衡。作为负面影响的一个例子,辐射可引起体内的遗传变化(图1)。辐射分为电离和非电离。电离辐射在其所通过的介质中引起原子或原子群的电子损失或获得。因此,形成带正电或负电的离子。可以计算出电磁波谱电离区的高能X射线、伽马射线、紫外线和一些可见光。由于伽马射线、X射线和紫外线更能电离生物体内的分子,它们很容易破坏生物体内组织、细胞和DNA分子的化学结构。因此,它们对生物来说是非常危险和致命的。在电磁波谱的非电离区,波的能量很低,能级不足以使分子电离。电、无线电和电视电波、微波和红外线不会电离,因为它们的能量很低。电子设备(手机、电脑、微波炉等)发出的电波会被人体和动物吸收。单位生物组织质量在单位时间内吸收的能量称为比吸收率(SAR),其单位为W/kg。电磁场对生物的危害根据组织和器官的结构,辐射必须达到一定的阈值剂量才能产生影响。低于阈值剂量的辐射水平是无效的。根据组织和器官的结构,辐射必须达到一定的阈值剂量。小剂量的波的影响可以忽略不计。然而,超过一定阈值的波的临床效果可能会增加。高剂量波可导致组织细胞死亡。细胞的损伤可能会在一段时间后增加患癌症和遗传性损伤的风险,而暴露于辐射的人的身体效应可能会导致癌症在数年后出现。关于射频场的影响有很多研究。大鼠、植物及人体不同组织的体内外实验研究;表明射频场不具有遗传毒性,有害效应是由于热效应。在这个问题上,矛盾的结果引起了讨论。因此,人们仍然担心RFR对人体健康的潜在不利影响。充分了解射频辐射的生物效应可以防止潜在的损害。 由于这些不确定因素,世界卫生组织的电磁场项目加快了对射频辐射生物效应的实验和模拟研究。2011年,国际癌症研究机构(International Agency for Research on Cancer)认定射频emr波可能对人类具有潜在的致癌作用(2)。考虑到几乎每个人,包括幼儿,除了使用其他科技设备外,还使用手机,电磁波的危险已经引起了社会的关注。除了刺激细胞凋亡和改变离子通道外,RF-EMF波对遗传物质也有潜在的影响。生物体吸收的辐射引起目标分子的电离。特别是,当电离辐射穿过组织时,原子的刺激/电离和分子结构的破坏可能导致生物损伤。由于细胞内电离,电子增加,自由电子造成损害,特别是在大分子和DNA中。自由电子直接或间接地运动。自由电子直接影响DNA的磷酸二酯或氢键。结果,细胞内DNA的磷酸二酯键断裂,单链或双链断裂,化学毒素增加。DNA双链断裂是电离辐射引起的最相关的生物损伤(3,4)。没有细胞能抵抗辐射。细胞核,特别是分裂细胞中的染色体对辐射非常敏感。辐射对细胞最重要的影响之一是抑制细胞生长。特别是,在细胞分裂(有丝分裂)期间暴露于辐射的细胞的生长受到损害。因此,高分裂率的细胞对辐射更敏感。体细胞DNA损伤可导致癌症发展或细胞死亡。细胞死亡是DNA分解的结果,因为电离辐射有足够的能量来分解细胞的遗传物质。因此,组织受损,可能引发癌症的发展。细胞中辐射引起的DNA损伤可通过代谢修复过程修复。如果细胞内辐射造成的DNA损伤造成的DNA断裂不是太大,它们可以通过代谢修复过程修复。但是,在此修复过程中可能会发生错误。含有不同遗传密码和信息的染色体也可能出现。在细胞中,释放的电子与水分子相互作用,间接地使水被反应分为两部分。自由基携带一个电子,这个电子在它们的轨道上没有电共享。自由基会导致DNA的遗传损伤,如核苷酸变化、双链和单链断裂。辐射会导致染色体断裂,粘在一起并重新排列。所有这些变化都可能导致突变,甚至进一步导致细胞死亡。然而,除了电离辐射外,细胞外的遗传毒性化学物质和细胞内的氧化代谢残基也可以在DNA复制和细胞分裂过程中对细胞产生应激。在这种环境胁迫条件下,DNA复制过程中可能发生损伤。迄今为止,关于RF-EMF波对遗传物质的遗传毒性作用的报道结果相互矛盾。据报道,低电磁场的能量不足以破坏DNA的化学键,但暴露时间的增加对氧自由基的形成和DNA修复过程的破坏是有效的。微波的吸收会引起细胞内明显的局部变暖。例如,在暴露于高SAR水平波的培养基中,已观察到细胞温度升高。然而,有证据表明,细胞中的活性氧是间接和实验暴露于RF-EMF波中形成的。自由基可以在DNA中产生核苷酸入口,并将细胞成分与DNA碱基结合(5)。在居住在高能量线附近的急性白血病儿童中,DNA修复机制基因中观察到的多态性频率揭示了这种能量对修复过程的影响。据报道,有重要证据表明,暴露于RF-EMF波时,各种细胞类型都会发生遗传毒性效应(6-10)。在这里,有报道称,暴露于RF-EMF波(1.800 MHz, SAR 2 W/kg)的细胞会导致线粒体DNA氧化损伤,神经元DNA断裂和羊膜细胞DNA断裂(6,10)。同样,有报道称,暴露于各种RF-EMF波的淋巴细胞也会受到损伤(8)。然而,已知暴露于RF-EMF波会导致染色体失衡、基因表达改变和基因突变。这种有害的遗传效应在神经元、血淋巴细胞、精子、红细胞、上皮细胞、造血组织、肺细胞和骨髓中也有报道(1,11,12)。 研究发现,暴露于RF-EMF辐射也会增加染色体数量畸变(6,13)。也有报道称小鼠卵母细胞中染色体分离增加
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