Peculiarities of Microwave Radiation of Dental Materials Contacting with Human Body Tissue
DOI:
https://doi.org/10.37155/2972-449X-vol1(3)-85Keywords:
Implant, Dental Materials, Effect on Human Body Tissues, Microwave Radiation, Electromagnetic Hemostasis, Negative ("-") and Positive ("+") Flow, Electromagnetic CompatibilityAbstract
The success of dental operations with the use of implants mostly depends on the properties of the implant materials and their compatibility with the tissues of the human body. A number of physical compatibility criteria are known, which include biological stability, biocorrosion resistance, chemical stability, antimicrobial resistance, so an in-depth study of these criteria is relevant. Among the used implants, dielectric materials of natural and synthetic origin make up a large share. The peculiarity of such materials, in contrast to metal ones, is the ability to form, at a human body temperature of 310°K, low-intensity electromagnetic radiation (EMR) of the microwave range, which interacts with the biotissue adjacent to the implant. SuchEMR exerts an influence at the cellular level, too. This effect of EMRin fact has not been investigated. The article discusses the physical basis of the formation of positive (“+”) and negative (“-“) microwave radiation flows that occur between the implant and the adjacent biotissue. By using a highly sensitive radiometric system, an experimental study of the radiation properties of the most used implant materials contacting with human body tissues was carried out. In the course of the research the levels of inherent radiation of a number of dental materials were determined, the calculation and evaluation of the coefficients of their radiation capacity was carried out. Comparing the radiation capacity of contacting dental materials with the level of radiation of the human body tissues made it possible to determine the level of their electromagnetic compatibility. Recommendations for the selection of the most used contacting dental materials based on the criterion of electromagnetic compatibility have been developed.
References
Safavi M S, Khalil-Allafi J, Ahadzadeh I, et al. Improved corrosion protection of a NiTi implant by an electrodeposited HAp-Nb2O5 composite layer[J]. Surface and Coatings Technology, 2023, 470: 129822. https://doi.org/10.1016/j.surfcoat.2023.129822.
Safavi M S, Khalil-Allafi J, Restivo E, et al. Enhanced in vitro immersion behavior and antibacterial activity of NiTi orthopedic biomaterial by HAp-Nb2O5 composite deposits[J]. Scientific Reports, 2023, 13(1): 16045. https://doi.org/10.1038/s41598-023-43393-3.
Safavi M S, Khalil-Allafi J, Visai L. Improved osteogenic activity of NiTi orthopedic implant by HAp-Nb2O5 composite coatings: Materials and biological points of view[J]. Biomaterials Advances, 2023, 150: 213435. https://doi.org/10.1016/j.bioadv.2023.213435.
Pratap B, Gupta R K, Bhardwaj B, et al. Resin based restorative dental materials: Characteristics and future perspectives[J]. Japanese Dental Science Review, 2019, 55(1): 126-138. https://doi.org/10.1016/j.jdsr.2019.09.004.
Yanenko O. Low─ Intensive Microwave Signals in Biology and Medicine[J]. Journal of Human Physiology, 2019, 1(1): 29-41. https://doi.org/10.30564/jhp.v1i1.1453.
Pyuryk V P, Prots G B, Ogienko S A, et al. "Combined use of autologous bone marrow and artificial bone substitutes to replace postoperative bone defects", Visn. problems of biology and medicine, 2014: 105-109.
Zhao R, Yang R, Cooper P R, et al. Bone grafts and substitutes in dentistry: A review of current trends and developments[J]. Molecules, 2021, 26(10): 3007. https://doi.org/10.3390/molecules26103007.
Cordonnier T, Sohier J, Rosset P, et al. Biomimetic materials for bone tissue engineering–state of the art and future trends[J]. Advanced Engineering Materials, 2011, 13(5): B135-B150.
Tour G. Craniofacial bone tissue engineering with biomimetic constructs. Available from: https://pdfs.semanticscholar.org/276e/ f884c9c3dd46fb0da19db9947518f1229a6b.pdf.
Zhu W, Nie X, Tao Q, et al. Interactions at engineered graft–tissue interfaces: A review[J]. APL bioengineering, 2020, 4(3). https://doi.org/10.1063/5.0014519.
Yanenko O, Shevchenko K, Peregudov S, et al. Low Intensity Microwave Fields and Radiation and Their Interaction with the Human Body[J]. Journal of Human Physiology, 2021, 3(2): 40-50. https://doi.org/10.30564/jhp.v3i2.4160.
Sculean A, Nikolidakis D, Schwarz F. Regeneration of periodontal tissues: combinations of barrier membranes and grafting materials–biological foundation and preclinical evidence: a systematic review[J]. Journal of clinical periodontology, 2008, 35: 106-116.
Gozhenko A I, Gorbachevsky O V. ELECTROMAGNETIC HOMEOSTASIS AND HUMAN ADAPTATION TO STRESS-FACTORS (Elektromagnitnii gomeostaz i adaptatsia organizmu lyudini do stress-faktoriv)[J]. Visnyk Natsionalnoyi akademiyi nauk Ukrainy (Herald of the National Academy of Sciences of Ukraine), 2009, 10: 12-21.
Yanenko O, Peregudov S, Shevchenko K, et al. Assessment of dielectric implantable biomaterials compatibility based on the level of low-intensity mm-range signals[C]//2020 IEEE 40th International Conference on Electronics and Nanotechnology (ELNANO). IEEE, 2020: 436-441.
Yanenko O, Shevchenko K, Malanchuk V, et al. Microwave Evaluation of Electromagnetic Compatibility of Dielectric Remedial and Therapeutic Materialswith Human Body[J]. International Journal of Materials Besearch, USA, 2019, 7(1): 37-43.
Piszczek P, Wójcik-Piotrowicz K, Gil K, et al. Immunity and electromagnetic fields[J]. Environmental Research, 2021, 200: 111505.
Yoshikawa H, Myoui A. Bone tissue engineering with porous hydroxyapatite ceramics[J]. Journal of Artificial Organs, 2005, 8: 131-136.
YanenkoO.Ph.,PeregudovS.M., GolovchanskaO.D. Sposibvymiriuvanniapotuzhnostielectromagnitnogosygnalataidentifikacii stomatologichnyhmaterialiv. PatentUkrainy №49357, 2008. Bull. №15.
YanenkoO.Ph., KrasiukO.D., GolovchanskaO.D. PeregudovS.M. Ocinkasumisnostistomatologichnyhmaterialiv / VisnykNTUU “KPI”. Pryladobuduvannia. - 2008. Vyp.35. – P.143-147.
R.vanNurt. Osnovystomatologicheskogomaterialovedeniia. 2-е izd.: MMosby, London 2002 – 302 pp.
Danilevskyi N.F., Borysenko A.V. I dr. Terapevticheskaia stomatologija, tom 1. Fantomnyi kurs.– К.: Medicina, 2007. – 360 pp.
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Copyright (c) 2023 Oleksiy Yanenko, Sergey Peregudov, Kostiantyn Shevchenko, Vladyslav Malanchuk, Oleksandra Golovchanska
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