Показати скорочену інформацію

dc.contributor.authorJiao, Hunkunen
dc.contributor.authorAvrunin, Olegen
dc.contributor.authorЦзяо, Хунькуньuk
dc.contributor.authorAvrunin, Oleguk
dc.date.accessioned2024-07-08T07:00:30Z
dc.date.available2024-07-08T07:00:30Z
dc.date.issued2023
dc.identifier.citationJiao Hunkun. Investigation the feasibility of complex circular motion of implants in magnetic stereotaxis systems [Текст] / Jiao Hunkun, О. Аvrunin // Оптико-електронні інформаційно енергетичні технології. – 2023. – Т. 46, № 2. – С. 124-134.uk
dc.identifier.issn1681-7893
dc.identifier.issn2311-2662
dc.identifier.urihttps://ir.lib.vntu.edu.ua//handle/123456789/42963
dc.description.abstractУ даній роботі ми досліджуємо можливість управління круговим рухом імплантату безконтактним способом шляхом контролю зміни зовнішнього магнітного поля в магнітній стереотаксичній системі. Зміна зовнішнього магнітного поля була змодельована за допомогою комп'ютерних симуляційних експериментів, щоб контролювати круговий рух невеликого постійного магніту безконтактним способом, і в реальному експерименті система ковзання була оснащена великим постійним магнітом для формування зовнішнього магнітного поля, а робота системи ковзання контролювалася мікроконтролером Arduino. Перевірено результати комп'ютерно-імітаційних експериментів та уточнено доцільність безконтактного керування круговим рухом імплантату.uk
dc.description.abstractIn this paper, we explore the feasibility of controlling the circular motion of the implant in a non-contact manner by controlling the change of the external magnetic field in a magnetic stereotaxic system. The change of the external magnetic field was simulated through computer simulation experiments, so as to control the circular motion of a small permanent magnet in a non-contact manner, and in the actual experiment, the slide rail system was equipped with a large permanent magnet to form an external magnetic field, and the operation of the slide rail system was controlled by an Arduino microcontroller. The results of computer simulation experiments were verified, and the feasibility of non-contact control of the circular motion of the implant was clarified.en
dc.language.isouk_UAuk_UA
dc.publisherВНТУuk
dc.relation.ispartofОптико-електронні інформаційно енергетичні технології. № 2 : 124-134.uk
dc.relation.urihttps://oeipt.vntu.edu.ua/index.php/oeipt/article/view/668
dc.subjectHuman healthen
dc.subjectMagnetic fielden
dc.subjectCOMSOL Softwareen
dc.subjectPermanent magnetsen
dc.subjectArduino microcontrollersen
dc.subjectBiomedical systemen
dc.subjectздоров'я людиниuk
dc.subjectмагнітне полеuk
dc.subjectпрограмне забезпечення COMSOLuk
dc.subjectпостійні магнітиuk
dc.subjectікроконтролери Arduinouk
dc.subjectбіомедична системаuk
dc.titleInvestigation the feasibility of complex circular motion of implants in magnetic stereotaxis systemsen
dc.title.alternativeДослідження можливості складного кругового руху імплантатів в системах магнітного стереотаксисуuk
dc.typeArticle
dc.relation.referencesGrady S M, Howard III M A, Broaddus W C, et al. Magnetic stereotaxis: a technique to deliver stereotactic hyperthermia[J]. Neurosurgery, 1990, 27(6): 1010-1016.en
dc.relation.referencesNelson B J, Gervasoni S, Chiu P W Y, et al. Magnetically actuated medical robots: An in vivo perspective [J]. Proceedings of the IEEE, 2022, 110(7): 1028-1037.en
dc.relation.referencesGrady M S, Howard M A, Dacey R G, et al. Experimental study of the magnetic stereotaxis system for catheter manipulation within the brain[J]. Journal of neurosurgery, 2000, 93(2): 282-288en
dc.relation.referencesAvrunin, O., Tymkovych, M., Semenets, V., & Piatykop, V. (2019). Computed tomography dataset analysis for stereotaxic neurosurgery navigation. Paper presented at the Proceedings of the International Conference on Advanced Optoelectronics and Lasers, CAOL, , 2019-September 606-609. doi:10.1109/CAOL46282.2019.9019459en
dc.relation.referencesAvrunin, O. G., Alkhorayef, M., Saied, H. F. I., & Tymkovych, M. Y. (2015). The surgical navigation system with optical position determination technology and sources of errors. Journal of Medical Imaging and Health Informatics, 5(4), 689-696. doi:10.1166/jmihi.2015.1444en
dc.relation.referencesAvrunin, O. G., Tymkovych, M. Y., Moskovko, S. P., Romanyuk, S. O., Kotyra, A., & Smailova, S. (2017). Using a priori data for segmentation anatomical structures of the brain. PrzegladElektrotechniczny, 93(5), 102-105. doi:10.15199/48.2017.05.20en
dc.relation.referencesMoresi G, Magin R. Miniature permanent magnet for table‐top NMR[J]. Concepts in Magnetic Resonance Part B: Magnetic Resonance Engineering: An Educational Journal, 2003, 19(1): 35-43.en
dc.relation.referencesO’Reilly T, Teeuwisse W M, de Gans D, et al. In vivo 3D brain and extremity MRI at 50 mT using a permanent magnet Halbach array[J]. Magnetic resonance in medicine, 2021, 85(1): 495-505.en
dc.relation.referencesHunkun J. Explore the Feasibility Study of Magnetic Stereotaxic System / J. Hunkun, O. G. Avrunin // Optoelectronic Information-Power Technologies, vol. 45, no. 1, Sept. 2023, pp. 86-96.en
dc.relation.referencesJ. Hunkun and O. Avrunin, "Possibilities of Field Formation by Permanent Magnets in Magnetic Stereotactic Systems," 2022 IEEE 3rd KhPI Week on Advanced Technology (KhPIWeek), Kharkiv, Ukraine, 2022, pp. 1-4, doi: 10.1109/KhPIWeek57572.2022.9916450.en
dc.relation.referencesMultiphysics C. Introduction to COMSOL multiphysics® //COMSOL Multiphysics, Burlington, MA, accessed Feb. – 1998. – Т. 9. – №. 2018. – С. 32.en
dc.relation.referencesPepper D W, Heinrich J C. The finite element method: basic concepts and applications with MATLAB, MAPLE, and COMSOL[M]. CRC press, 2017.en
dc.relation.referencesO’Reilly T, Teeuwisse W M, de Gans D, et al. In vivo 3D brain and extremity MRI at 50 mT using a permanent magnet Halbach array[J]. Magnetic resonance in medicine, 2021, 85(1): 495-505.en
dc.relation.referencesBadamasi Y. A. The working principle of an Arduino //2014 11th international conference on electronics, computer and computation (ICECCO). – IEEE, 2014. – С. 1-4.en
dc.relation.referencesBanzi M., Shiloh M. Getting started with Arduino. – Maker Media, Inc., 2022.en
dc.relation.referencesVirgala I, Kelemen M, Gmiterko A, et al. Control of stepper motor by microcontroller[J]. Journal of Automation and Control, 2015, 3(3): 131-134.en
dc.relation.referencesAvrunin O., Sakalo S., Semenetc V., Development of up-to-date laboratory base for microprocessor systems investigation, 2009 19th International Crimean Conference Microwave & Telecommunication Technology, Sevastopol, 2009, pp. 301-302.en
dc.relation.referencesAvrunin О.G. Experience of Developing a Laboratory Base for the Study of Modern Microprocessor Systems / О.G. Avrunin, T.V. Nosova, V.V. Semenets. // Proceedings of I International Scientific and Practical Conference «Theoretical and Applied Aspects of Device Development on Microcontrollers and FPGAs» MC&FPGA-2019, Kharkiv, Ukraine. – 2019. – P. 6-8.en
dc.relation.referencesAlipal J, Pu'Ad N A S M, Lee T C, et al. A review of gelatin: Properties, sources, process, applications, and commercialisation[J]. Materials Today: Proceedings, 2021, 42: 240-250.en
dc.relation.referencesHunkun, J. і Avrunin, O. (2023) , Feasibility analysis of implant movement along arc trajectory under non-contact control in magnetic stereotaxic system //Innovative technologies and scientific solutions for industries. 2023. No. 3 (25). – P. 174–182. doi: 10.30837/ITSSI.2023.25.174.en
dc.relation.referencesKolisnyk, K., Deineko, D., Sokol, T., Kutsevlyak, S., and Avrunin, O., “Application of modern internet technologies in telemedicine screening of patient conditions,” in 2019 IEEE International Scientific-Practical Conference Problems of Infocommunications, Science and Technology (PIC S&T), (2019).en
dc.relation.referencesSokol, Y., Avrunin, O., Kolisnyk, K., and Zamiatin, P., “Using medical imaging in disaster medicine,” in IEEE 4th International Conference on Intelligent Energy and Power Systems IEPS, 287 –290 (2020). https://doi.org/10.1109/IEPS51250.2020.9263175/en
dc.relation.referencesWójcik, W., Pavlov, S., Kalimoldayev, M. (2019). Information Technology in Medical Diagnostics II. London: Taylor & Francis Group, CRC Press, Balkema book. – 336 Pages, https://doi.org/10.1201/ 9780429057618. eBook ISBN 9780429057618.en
dc.relation.referencesPavlov S. V. Information Technology in Medical Diagnostics //Waldemar Wójcik, Andrzej Smolarz, July 11, 2017 by CRC Press - 210 Pages. https://doi.org/10.1201/9781315098050. eBook ISBN 9781315098050.en
dc.relation.referencesPavlov Sergii, Avrunin Oleg, Hrushko Oleksandr, and etc. System of three-dimensional human face images formation for plastic and reconstructive medicine // Teaching and subjects on bio-medical engineering Approaches and experiences from the BIOART-project Peter Arras and David Luengo (Eds.), 2021, Corresponding authors, Peter Arras and David Luengo. Printed by Acco cv, Leuven (Belgium). - 22 P. ISBN: 978-94-641-4245-7.en
dc.identifier.doi10.31649/1681-7893-2023-46-2-124-134


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