I. Effects On Fetal And Newborn Development

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Ultra High Frequency-Electromagnetic Field Irradiation During Pregnancy Leads to an Increase in Erythrocytes Micronuclei Incidence in Rat Offspring. Ferreira, Knakievicz, et al. Life Sciences 80(1):43-50 (2006).

Exposure to Cell Phone Radiation Up-Regulates Apoptosis Genes in Primary Cultures of Neurons and Astrocytes. Zhao, et al. Science Digest 412: 34–38 (2007).

Effects of Prenatal Exposure to a 900 MHz Electromagnetic Field on the Dentate Gyrus of Rats: A Stereological and Histopathological Study. Odaci, et al. Brain Research 1238: 224–229 (2008).

Maternal Occupational Exposure to Extremely Low Frequency Magnetic Fields and the Risk of Brain Cancer in the Offspring. Li, Mclaughlin, et al. Cancer Causes & Control 20(6):945-55 (2009).

Stress Signalling Pathways that Impair Prefrontal Cortex Structure and Function. Arnsten, A. F. National Review of Neuroscience 10, 410–22 (2009).

Dysbindin Modulates Prefrontal Cortical Glutamatergic Circuits and Working Memory Function in Mice. Jentsch, et al Neuropsychopharmacology 34, 2601–8 (2009).

Cranial and Postcranial Skeletal Variations Induced in Mouse Embryos by Mobile Phone Radiation. Fragopoulou, Koussoulakos, et al. Pathophysiology 17(3):169-77 (2010).

The Effects of 900 Megahertz Electromagnetic Field Applied in the Prenatal Period on Spinal Cord Morphology and Motor Behavior in Female Rat Pups. Odaci, et al. NeuroQuantology Volume 11, Issue 4: 573-581 (2013).

Pyramidal Cell Loss in the Cornu Ammonis of 32-day-old Female Rats Following Exposure to a 900 Megahertz Electromagnetic Field During Prenatal Days 13–21. Bas, et al. NeuroQuantology Volume 11, Issue 4: 591-599 (2013).

Influence of Pregnancy Stage and Fetus Position on the Whole-Body and Local Exposure of the Fetus to RF-EMF. Varsier, et al. Physics in Medicine and Biology 59(17):4913-26 (2014).

Dosimetric Study of Fetal Exposure to Uniform Magnetic Fields at 50 Hz. Liorni, et al. Bioelectromagnetics 35(8):580-97 (2014).

Effects of Prenatal 900 MHz Electromagnetic Field Exposures on the Histology of Rat Kidney. Ulubay, et al. International Journal of Radiation Biology 91(1):35-41 (2015).

Oxidative Mechanisms of Biological Activity of Low-Intensity Radiofrequency Radiation. Yakymenko, et al. Electromagnetic Biology and Medicine 34(3):1-16 (2015).

Use of Mobile Phone During Pregnancy and the Risk of Spontaneous Abortion. Mahmoudabadi, Ziaei, et al. Journal of Environmental Health Science and Engineering 13:34 (2015).

Different Periods of Intrauterine Exposure to Electromagnetic Field: Influence on Female Rats' Fertility, Prenatal and Postnatal Development. Alchalabi, Aklilu, et al. Asian Pacific Journal of Reproduction 5(1):14-23 (2015).

Maternal Exposure to a Continuous 900-MHz Electromagnetic Field Provokes Neuronal Loss and Pathological Changes in Cerebellum of 32-Day-Old Female Rat Offspring. Odaci, Ersan, et al. Journal of Chemical Neuroanatomy 75(B):105-110 (2015).

Genotoxicity Induced by Foetal and Infant Exposure to Magnetic Fields and Modulation of Ionising Radiation Effects. Udroiu, Antoccia, et al. PLoS One (2015).

A Review on Electromagnetic Fields (EMFs) and the Reproductive System. Asghari, Khaki, et al. Electronic Physician 8(7):2655-2662 (2016).

The Use of Signal-Transduction and Metabolic Pathways to Predict Human Disease Targets from Electric and Magnetic Fields Using in vitro Data in Human Cell Lines. Parham, Portier, et al. Frontiers in Public Health (2016).

Multiple Assessment Methods of Prenatal Exposure to Radio Frequency Radiation from Telecommunication in the Mothers and Children’s Environmental Health (MOCEH) Study. Choi, Ha, et al. International Journal of Occupational Medicine and Environmental Health 29(6):959-972 (2016).

Lasting Hepatotoxic Effects of Prenatal Mobile Phone Exposure. Yilmaz, A., et al. The Journal of Maternal-Fetal & Neonatal Medicine 30(11): 1355-1359 (2017).

Postnatal Development and Behavior Effects of In-Utero Exposure of Rats to Radiofrequency Waves Emitted From Conventional WiFi Devices. Othman, H., et al. Environmental Toxicology and Pharmacology 52:239-247 (2017).

The Effects of Radio Frequency Radiation on Mice Fetus Weight, Length and Tissues. Alimohammadi, I., et al. Data in Brief 19:2189-2194 (2018).

Prenatal Exposure to Extremely Low Frequency Magnetic Field and Its Impact on Fetal Growth. Ren, Y., et al. Environmental Health (2019).

Mother’s Exposure to Electromagnetic Fields Before and During Pregnancy is Associated with Risk of Speech Problems in Offspring. Zarei, S., et al. Journal of Biomedical Physics and Engineering 9(1):61-68 (2019).



II. Effects On Young Children



The Sensitivity of Children to Electromagnetic Fields. Repacholi, et al. Deventer. Journal of Pediatrics 116(2):303-313 (2005).

Exposure to Radio-Frequency Electromagnetic Fields and Behavioral Problems in Bavarian Children and Adolescents. Thomas, Silke, et al. European Journal of Epidemiology 25(2):135-41 (2009).

Mobile Phones, Radiofrequency Fields, and Health Effects in Children-Epidemiological Studies. Feychting, Maria. Progress in Biophysics and Molecular Biology 107(3):343-348 (2010).

Cell Phone Use and Behavioural Problems in Young Children. Divan, Kheifets, et al. Journal of Epidemiol Community Health 66(6):524-9 (2010).

Exposure to Extremely Low-Frequency Magnetic Fields and the Risk of Childhood Cancer: Update of the Epidemiological evidence. Schüz and Joachim. Progress in Biophysics and Molecular Biology 107(3):339-42 (2011).

A Prospective Study of In-Utero Exposure to Magnetic Fields and the Risk of Childhood Obesity. Li, De-Kun, et al. Scientific Reports 2.540 (2012).

Epidemiological Characteristics of Mobile Phone Ownership and Use in Korean Children and Adolescents. Byun, Yoon-Hwan, et al. Environmental Health and Toxicology 28 (2013).

Why Children Absorb More Microwave Radiation than Adults: The Consequences. Morgan, Kesari, et al. Journal of Microscopy and Ultrastructure 2(4):196-204 (2014).

Prospective Cohort Analysis of Cellphone Use and Emotional and Behavioural Difficulties in Children. Sudan, M, et al. Journal of Epidemiology and Community Health (2016).



III. Brain Tumors



Mobile Phone Use and the Risk of Acoustic Neuroma. Lonn, Ahlbom, et al. Epidemiology 15(6):653-659 (2004).

Histopathological Examinations of Rat Brains After Long-Term Exposure to GSM Mobile Phone Radiation. Grafström, Gustav, et al. Brain Research Bulletin 77(5):257-63 (2008).

Epidemiological Evidence for an Association Between Use of Wireless Phones and Tumor Diseases. Hardell, Carlberg, et al. PathoPhysiology 16(2-3):113-122 (2009).

Indications of Possible Brain Tumour Risk in Mobile-Phone Studies: Should We Be Concerned? Cardis and Sadetzki. Occupational & Environmental Medicine 68:169-171 (2011).

Mobile Phones and Head Tumours: A Critical Analysis of Case-Control Epidemiological Studies. Levis, Minicuci, et al. Open Environmental Sciences 6(1):1-12 (2012).

Use of Mobile Phones and Cordless Phones is Associated with Increased Risk for Glioma and Acoustic Neuroma. Hardell, Carberg, et al. PathoPhysiology 20(2):85-110 (2013).

Mobile Phone Use and Brain Tumours in the CERENAT Case-Control Study. Coureau, Bouvier, et al. Occupational & Environmental Medicine 71(7):514-22 (2014).

Mobile Phone Radiation Causes Brain Tumors and Should Be Classified as a Probable Human Carcinogen. Morgan, Miller, et al. International Journal of Oncology 46:1865-1871 (2015).

The 2100 MHz Radiofrequency Radiation of a 3G-Mobile Phone and the DNA Oxidative Damage in Brain. Sahin, Ozgur, et al. Journal of Chemical Neuroanatomy 75(B):94-98 (2016).

Brain Tumours: Rise in Glioblastoma Multiforme Incidence in England 1995-2015 Suggests an Adverse Environmental or Lifestyle Factor. Philips, A., et al. Journal of Environmental and Public Health (2018).

Exposure to Cell Phone Radiofrequency Changes Corticotrophin Hormone Levels and Histology of The Brain and Adrenal Glands in Male Wistar Rat. Shahabi, S., et al. Iranian Journal of Basic Medical Sciences 21:1269-1274 (2018).

Simulation of The Incidence of Malignant Brain Tumors in Birth Cohorts That Started Using Mobile Phones When They First Became Popular in Japan. Sato, Y., Kojimahara, N., and Yamaguchi, N. Bioelectromagnetics 40(3): 143-149 (2019).



IV. Parotid Gland Tumors



Cell Phone Use and Risk of Benign and Malignant Parotid Gland Tumors - A Nationwide Case- Control Study. Sadetzki, Chetrit, et al. American Journal of Epidemiology 167(4):457-467 (2008).

Epidemiological Evidence for an Association Between use of Wireless Phones and Tumor Diseases. Hardell, Carlberg, et al. PathoPhysiology 16(2-3):113-122 (2009).

Public Health Implications of Wireless Technologies. Sage and Carpenter. PathoPhysiology 16(2-3):233-46 (2009).

Mobile Phone, Cordless Phones and the Risk for Brain Tumours. Hardell and Carlberg. International Journal of Oncology 35(1):5-17 (2009).

Mobile Phones Use and Risk of Tumors: A Meta-Analysis. Mynf, Ju, et al. Journal of Clinical Oncology 27(33):5565-72 (2009).

Correlation Between Cellular Phone Use and Epithelial Parotid Gland Malignancies. Duan, Zhang, et al. Clinical Paper Head and Oncology 40(9):966-7 (2011).

Using the Hill Viewpoints from 1965 for Evaluating Strengths of Evidence of the Risk for Brain Tumors Associated with use of Mobile and Cordless Phones. Hardell and Carlberg. Reviews on Environmental Health 28(2-3):97-106 (2013).

Pooled Analysis of Case-Control Studies on Acoustic Neuroma Diagnosed 1997-2003 and 2007- 2009 and Use of Mobile and Cordless Phones. Hardell, Carlberg, et al. International Journal of Oncology 43(4):1036-144 (2015).

Does Cell Phone Use Increase the Chances of Parotid Gland Tumor Development? A Systematic Review and Meta-Analysis. De Siqueira, de Souza, et al. Journal of Oral Pathology and Medicine 45(11) (2016).

Influence of Handheld Mobiles on Parotid: A Cohort Study. Ranjitha, G., et al. Journal of Indian Academy of Oral Medicine & Radiology 29:254-258 (2017).



V. Other Malignancies



Epidemiological Evidence for an Association Between Use of Wireless Phones and Tumor Diseases. Hardell, Carlberg, et al. PathoPhysiology 16(2-3):113-122 (2009).

Multifocal Breast Cancer in Young Women with Prolonged Contact Between Their Breasts and Their Cellular Phones. West, Kapoor, et al. Case Reports in Medicine (2013).

Swedish Review Strengthen Grounds for Concluding that Radiation from Cellular and Cordless Phones is a Probable Human Carcinogen. Davis, Kesari, et al. Pathophysiology 20(2):123-129 (2013).

Tumor Promotion by Exposure to Radiofrequency Electromagnetic Fields Below Exposure Limits for Humans. Lerchl, Klose, et al. Biochemical and Biophysical Research Communications 459(4):585-590 (2015).



VI. Effects On DNA



DNA Damage in Molt-4 T-lymphoblastoid Cells Exposed to Cellular Telephone Radiofrequency Fields in Vitro. Philips, Ivaschuk, et al. Bioelectrochemistry and Bioenergetics 45(1):103-110 (1998).

Gene Expression Changes in the Skin of Rats Induced by Prolonged 35 GHz Millimeter-Wave Exposure. Millenbaugh, Roth, et al. Radiation Research 169(3):288-300 (2008).

Gene and Protein Expression Following Exposure to Radiofrequency Fields from Mobile Phones. Vanderstraeten and Verschaeve. Environmental Health Perspectives 116(9):1131-5 (2008).

Radiofrequency Radiation and Gene/Protein Expression: A Review. McNamee and Chauhan. Radiation Research 172(3):265-287 (2009).

Microwaves from Mobile Phones Inhibit 53BP1 Focus Formation in Human Stem Cells More Strongly Than in Differentiated Cells: Possible Mechanistic Link to Cancer Risk. Markova, Malmgren, et al. Environmental Health Perspectives 118(3):394-399 (2010).



VII. Neurological/Cognitive Effects



Neurological Effects of Radiofrequency Electromagnetic Radiation. Lai, Henry. Advances in Electromagnetic Fields in Living Systems1:27-80 (1994).

Effects of GSM 1800 MHz on Dendritic Development of Cultured Hippocampal Neurons. Ning, Xu, et al. Acta Pharmacol Sin28(12):1873-1880 (2007).

Use of Mobile Phones and Changes in Cognitive Function in Adolescents. Thomas, Benke, et al. Occupational Environmental Medicine 67(12):861-866 (2010).

Effects of 3 Hz and 60Hz Extremely Low Frequency Electromagnetic Fields on Anxiety-Like Behaviors, Memory Retention of Passive Avoidance and ElectroPhysiological Properties of Male Rats. Rostami, Shahani, et al. J Lasers Medical Science 7(2):120-125 (2016).

Effect of Mobile Phone Radiation on Pentylenetetrazole-Induced Seizure Threshold in Mice. Kouchaki, Motaghedifard, et al. Iranian Journal of Basic Medical Sciences 19(7):800-3 (2016).

Effects of Short and Long Term Electromagnetic Fields Exposure on the Human Hippocampus. Deniz, O.G., et al. Journal of Microscopy and Ultrastructure 5(4):191-197 (2017).

The Effect of Wi-Fi Electromagnetic Waves in Unimodal and Multimodal Object Recognition Tasks in Male Rats. Hassanshahi, A., et al. Neurological Sciences 38(6):1069-1076 (2017).

Electromagnetic Radiation 2450 MHz Exposure Causes Cognition Deficit with Mitochondrial Dysfunction and Activation of Intrinsic Pathway of Apoptosis in Rats. Gupta, S.K., Mesharam, M.K., and Krishnamurthy, S. Journal of Biosciences 43(2) 263-276 (2018).

A Prospective Cohort Study of Adolescents’ Memory Performance and Individual Brain Dose of Microwave Radiation from Wireless Communication. Foerster, M., et al. Environmental Health Perspectives 126(7) (2018).

Mobile Phone Distance From Head and Temperature Changes of Radio Frequency Waves on Brain Tissue. Forouharmajd, F., Ebrahimi, H. and Pourabdian, S. International Journal of Preventative Medicine (2018).

2.45 GHz Microwave Radiation Impairs Learning, Memory, and Hippocampal Synaptic Plasticity in The Rat. Karimi, N., et al. Toxicology and Industrial Health 34(12): 873-883 (2018).

Effect of 1800-2100 MHz Electromagnetic Radiation on Learning-Memory and Hippocampal Morphology in Swiss Albino Mice. Kishore, G., Venkatashu, K., and Sridevi, N. Jorunal of Clincal and Diagnostic Research 12(2): 14-17 (2019).

Early-Life Exposure to Pulsed LTE Radiofrequency Fields Causes Persistent Changes in Activity and Behavior in C57BL/6 J Mice. Broom, K., et al. Bio Electro Magnetics 40(7):498-511 (2019).



VIII. Effects On Male Fertility



Effect of Cell Phone Usage on Semen Analysis in Men Attending Infertility Clinic: An Observational Study. Agarwal, Deepinder, et al. American Society for Reproductive Medicine 89(1):124-8 (2008).

Evaluation of the Effect of Using Mobile Phones on Male Fertility. Wdowiak, Wiktor, et al. Annals of Agricultural and Medicine14(1):169-172 (2007).

Cell Phones and Male Infertility: Dissecting the Relationship. Deepinder, Makker, et al. Reproductive BioMedicine Online 15(3):266-270 (2007).

Radio Frequency Electromagnetic Radiation (Rf-EMR) from GSM Mobile Phones Induces Oxidative Stress and Reduces Sperm Motility in Rats. Mailankot, Kunnath, et al. Clinical Science 64(6):561-5 (2009).

Mobile Phone Radiation Induces Reactive Oxygen Species Production and DNA Damage in Human Spermatozoa In Vitro. Luliis, Newey, et al. PLoS ONE 4(7) (2009).

Exposure to Magnetic fields and the Risk of Poor Sperm Quality. Li, Yan, et al. Journal of Reproductive Toxicology 29(1):86-92 (2010).

Effects of the Exposure of Mobile Phones on Male Reproduction: A Review of the Literature. Vignera, Condorelli, et al. Journal of Andrology 33(3):350-356 (2012).

Effect of Electromagnetic Field Exposure on the Reproductive System. Gye and Park. Journal of Clinical and Experimental Reproductive Medicine 39(1):1-19 (2012).

In Vitro Effect of Cell Phone Radiation on Motility, DNA Fragmentation and Clusterin Gene Expression in Human Sperm. Zalata, El-Samanoudy, et al. International Journal of Fertility and Sterility 9(1):129-136 (2014).

Extremely Low frequency Magnetic Fields Induce Spermatogenic Germ Cell Apoptosis: Possible Mechanism. Lee, Park, et al. BioMed Research International (2014).

Habits of Cell Phone usage and Sperm Quality - Does It Warrant Attention? Zilverlight, Wiener-Megnazi, et al. Reproductive BioMedicine Online 31(3):421-426 (2015).

Sperm DNA Damage – The Effect of Stress and Everyday Life Factors. Radwan, M, et al. International Journal of Impotence Research 28, 148-154 (2016).

Male Fertility and its Association with Occupational and Mobile Phone Tower Hazards: An Analytical Study. Al-Quzwini, Al-Taee, et al. Middle East Fertility Society Journal (2016).

The Effects of Radiofrequency Electromagnetic Radiation on Sperm Function. Houston, Nixon, et al. Reproduction (2016)

Radiofrequency Radiation (900 MHz)-Induced DNA Damage and Cell Cycle Arrest in Testicular Germ Cells in Swiss Albino Mice. Pandey, N., et al. Toxicology and Industrial Health 33(4) 373-384 (2017).

Aloe Arborescens Juice Prevents EMF-Induced Oxidative Stress and Thus Protects from Pathophysiology in the Male Reproductive System In Vitro. Solek, P., Majchrowics, L., and Koziorowski, M. Environmental Research 166:141-149 (2018).

Modulatory Effect of 900 MHz Radiation on Biochemical and Reproductive Parameters in Rats. Narayana, SN., et al. Bratislava Medical Journal119(9):581-587 (2018).

Radiations and Male Fertility. Kesari, K., Agarwal, A. and Henkel, R. Reproductive Biology and Endocrinology 16(118) (2018).

Long-Term Exposure to 4G Smartphone Radiofrequency Electromagnetic Radiation Diminished Male Reproductive Portential by Directly Disrupting Spck3-MMP2-BTB Axis in the Testes of Adult Rats. Yu, G., et al. Science of The Total Environment 698 (2020).



IX. Electromagnetic Sensitivity



Electric Hypersensitivity and Neurophysical Effects of Cellular Phones - Facts or Needless Anxiety? Harma, Mikko Ilmari. Scandinavian Journal of Work, the Environment and Health 26(2):85-86 (2000).

Establishing the Health Risks of Exposure to Radiofrequency Fields Requires Multidisciplinary Research. Hietanen, Maila. Scandinavian Journal of Work, the Environment, and Health 32(3):169-170 (2006).

Electromagnetic Hypersensitivity: Biological Effects of Dirty Electricity With Emphasis on Diabetes and Multiple Sclerosis. Havas, M. Electromagnetic Biology and Medicine 25(4): 259-268 (2006).

Electrohypersensitivity: Sate-Of-The-Art of A Functional Impairment. Johansson, O. Electromagnetic Biology and Medicine 25(4): 245-258 (2006).

Radiofrequency (RF) Sickness in the Lilienfeld Study: An Effect of Modulated Microwaves? Liakouris, A. Archives of Environmental Health 236-238 (2010).

Electromagnetic Hypersensitivity: Fact or Fiction? Genius and Lipp. Science of the Total Environment 414(1):103-112 (2012).

Green Communication- A Stipulation to Reduce Electromagnetic Hypersensitivity from Cellular Phones. Kumar, Khan, et al. Procedia Technology 4:682-686 (2012).

Tinnitus and Cell Phones: The Role of Electromagnetic Radiofrequency Radiation. Medeiros and Sanchez. Brazilian Journal of Otorhinolaryngology 82(1):97-104 (2016).

Hot Nano Spots" as an Interpretation of So-Called Non-Thermal Biological Mobile Phone Effects. Pfutzner, Helmut. Journal of Electromagnetic Analysis and Applications 8(3):62-69 (2016).

Functional Brain MRI in Patients Complaining of Electrohypersensitivity After Long Term Exposure to Electromagnectic Fields. Heuser, G. & Heuser, S. Reviews on Environmental Health 32(3):291-299 (2016).



X. Effects On Implanted Medical Devices



Cellular Telephones and Pacemakers: Urgent Call or Wrong Number? Ellenbogen and Wood. Journal of the American College of Cardiology 27(6):1478-9 (1996).

Radiofrequency Interference with Medical Devices. A Technical Information Statement. IEEE Committee on Man and Radiation, Institute of Electrical and Electronics Engineers 17(3):111-4 (1998).

Electromagnetic Interference in Patients with Implanted Cardioverter-Defibrillators and Implantable Loop Recorders. Sousa, Klein, et al. Indian Pacing and Electrophysiology Journal 2(3):79-84 (2002).

Electromagnetic Interference on Pacemakers. Erdogan, Okan. Indian Pacing and Electrophysiology Journal 2(3):74-78 (2002).

Interference Between Mobile Phones and Pacemakers: A Look Inside. Censi, Calcagnini, et al. Annali dell'Istituto superiore di sanità 43(3):254-259 (2007).

Electromagnetic Interference of Pacemakers. Lakshmanadoss, Chinnachamy, et al. Interchopen 229-252 (2011).



XI. 5G Effects



Human Skin as Arrays of Helical Antennas in Millimeter and Submillimeter Wave Range. Feldman, Y., et al. The American Physical Society (2008).

Effects of millimeter waves radiation on cell membrane-A brief review. Ramundo-Orlando, Alfonsina. Journal of Infrared, Millimeter, and Terahertz Waves 31(12): 1400-1411 (2010).

State of Knowledge on Biological Effects at 40-60 GHz. Drean, Y., et al. Comptes Rendus Physique (2013).

The Human body and Millimeter-Wave Wireless Communication Systems: Interactions and Implications. Wu, T., Rappaport, T., and Collins, C. IEEE International Conference on Communications (2015).

Human Exposure to RF Fields in 5G Downlink. Nasim, I. and Kim, S. Georgia Southern University (2017).

The Modeling of the Absorbance of Sun-THz Radiation by Human Skin. Betzalel, N., Feldman, Y., and Ishai, P.B. IEEE Transactions on Terahertz Science and Technology 7(5):521-528 (2017).

Towards 5G Communication Systems: Are There Health Implications? Ciaula, AD. International Journal of Hygiene and Environmental Health 367-375 (2018).

Systematic Derivation of Safety Limits for Time-Varying 5G Radiofrequency Exposure Based on Analytical Models and Thermal Dose. Neufeld, E., and Kuster, N. Health Physics Society (2018).

Millimeter Wave Radiation Activates Leech Nociceptors via TRPV1-Like Receptor Sensitization. Romanenko, S., et al. Biophysical Journal 116(12): 2331-2345 (2019).

Ocular Response to Millimeter Wave Exposure Under Different Levels of Humidity. Kojima, M., et al. Journal of Infrared Milli Terahz Waves 40: 574–584 (2019).

Untargeted Metabolomics Unveil Alterations of Biomembranes Permeability in HumanHaCaT Keratinocytes Upon 60 HGz Millimeter-Wave Exposure. Pogam, Pierre., et al. Scientific Reports 9(9343) (2019).



XII. Miscellaneous Articles



Untargeted Metabolomics Unveil Alterations of Biomembranes Permeability in Human HaCaT Keratinocytes Upon 60 HGz Millimeter-Wave Exposure. Pogam, Pierre., et al. Scientific Reports 9(9343) (2019).

Risks to Health and Well-Being From Radio-Frequency Radiation Emitted by Cell Phones and Other Wireless Devices. Miller, A., et al. Frontiers in Public Health 7(223) (2019).

Computational Simulations of The Penetration of 0.30 THz Radiation into the Human Ear. Vilaagosh, Z., et al. Biomedical Optics Express 10(3) (2019).

Radiofrequency Electromagnetic Field Exposure and Risk Perception: A Pilot Experimental Study. Zeleke, B., et al. Environmental Research 170: 493-499 (2019).

Commentary on The Utility of The National Toxicology Program Study on Cell Phone Radiofrequency Radiation Data for Assessing Human Health Risks Despite Unfounded Criticisms Aimed at Minimizing the Findings of Adverse Health Effects. Melnick, R. Environmental Research 168:1-6 (2019).

Pathological Findings Observed in the Kidneys of Postnatal Male Rats Exposed to the 2100 MHz Electromagnetic Field. Bedir, R., et al. Archives of Medical Research (2019).

Genotoxic and Carcinogenic Effects of Non-Ionizing Electromagnetic Fields. Kocaman, A., et al. Environmental Research 163:71-79 (2018).

Non-Ionizing EMF Hazard in the 21st Century. Koh, W.J., and Moochhala, S.M. IEEE (2018).

Comparison of Radiofrequency Electromagnetic Field Exposure Levels in Different Everyday Microenvironments in an International Context. Sagar, S, et al. Environmental International 114:297-306 (2018).

Radiation from Wireless Technology Elevates Blood Glucose and Body Temperature in 40-Year-Old Type 1 Diabetic Male. Kleiber, C. Electromagnetic Biology and Medicine 36:3 259-264 (2017).

Cardiovascular Disease: Time to Identify Emerging Environmental Risk Factors. Bandara, P. & Weller, S. European Journal of Preventative Cardiology (2017).

Effects of Exposure to 2100MHz GSM-like Radiofrequency Electromagnetic Field on Auditory System of Rats. Celiker, Ozgur, et al. Brazilian Journal of Otorhinolaryngology (2017).

An Investigation of the Effect of Extremely Low Frequency Pulsed Electromagnetic Fields on Human Electrocardiograms (ECGs). Fang, Mahmoud, et al. International Journal of Environmental Research and Public Health 13(11) (2016).

Evaluation of the Protective Role of Vitamin C on the Metabolic and Enxymatic Activities of the Liver in the Male Rats After Exposure to 2.45 GHz of Wi-Fi Routers. Shekoohi-Shooli, F., et al. Journal of Biomedical Physics and Engineering 6(3):157-164 (2016).

Exposure of ELF-EMF and RF-EMF Increase the Rate of Glucose Transport and TCA Cycle in Budding Yeast. Lin, Yan, et al. Frontiers in Microbiology (2016).

Awareness Campaign Against Cell Phone Radiation Hazard: Case Study Oman. Osmen and Saar. Procedia - Social and Behavioral Sciences 205(9):381-385 (2015).

Electromagnetic Energy Radiated from Mobile Phone Alters Electrocardiographic Records of Patients with Ischemic Heart Disease. Alhusseiny, Al-Nimer, et al. Annals of Medical and Health Science Research 2(2):146-151 (2012).

Effects of Radiofrequency Radiation on Human Ferritin: An in vitro Enzymun Assay. Fattahi-asl, Baradaran-Ghahfarokhi, et al. Journal of Medical Signals and Sensors 2(4):235-240 (2012).

Epidemiology of Health Effects of Radiofrequency Exposure. Ahlbom, Green, et al. Environmental Health Perspectives 112(17):1741-1753 (2004).

The Possible Role of Radiofrequency Radiation in the Development of Uveal Melanoma Stang, Anastassiou, et al. Journal of Epidemiology 12(1):7-12 (2001).