Conjunctive application of devices based on the Android platform in radiovisiographic research under war conditions in Ukraine

Authors

  • M. M. Yasinskyi Bukovinian State Medical University, Chernivtsi
  • Ya. R. Karavan Bukovinian State Medical University, Chernivtsi
  • M. A. Rusnak Yuri Fedkovich Chernivtsi National University
  • M. V. Kasiyanchuk Bukovinian State Medical University, Chernivtsi Private specialized medical practice, Chernivtsi

DOI:

https://doi.org/10.11603/2311-9624.2022.2.13161

Keywords:

dental implants, medical navigation, endoscopte, implant, operating system Android, mobile communication device

Abstract

Summary. The experiment feasibility of the medical navigation, endoskopi end radiovisiografi method at background traumatic factor on biological tissue during surgery was determined.

The aim of the study – to estimate the efficiency of medical navigation mode at clinical study using Android technology and mobile device during surgery for the maximum possible bone preservation.

Materials and Methods. An experimental dental implant surgery with registration of the traumatic impact stimulus on the periosteum in the area of ​​the implant. To control the positioning of the implant the navigation module (Ukraine patent N68641) integrated with the mobile phone platform Android was used. The dynamic pressure on the periosteum by own technique with stain gauge was determined. Bone deformation using inductive displacement meter was defined. These results were compared with other ones, obtained in the experiment with navigation system, integrated with desktop computer under Windows software. The feasibility of integrating medical navigation device on Android platform with standard dental unit for the ergonomics of implant surgeon was determined.

Results and Discussion. Preclinical testing of medical navigation ,, Navigator YuК-A’’ device provides accurate angular positioning of the implant at 2±0.5 ' (if angular displacement less than 25') and 1±0.5 ' (if angular displacement of less than 5'), precision linear positioning was 0.50±0.05 mm (when moving the implant up to 10 mm). The gap of 0.1-0.5 mm between the periosteum and the implant platform is the limit. With the same effort in the area of ​​the rotating implant platform the bone tissue pressure increases disproportionately and in some sense is destructive. In 22 % of cases we observed a continuing process of bone deformation layer during ~3 minutes after removing of mechanical stress. When comparing both experimental techniques results they look similar, the difference data rate is not determined subjectively.

Conclusions. The approach optimizes the process of surgery and can be recommended for clinical use. Application of medical navigation systems on Android platform is relevant with the development of telecommunication technologies.

References

Ewers, R., Schicho, K., Undt, G., Wanschitz, F., Truppe, M., & Seemann, R. (2005). Basic research and 12 years of clinical experience in computer-assisted navigation technology: a review. Int. J. Oral. Maxillofac. Surg., 34(1),1-8. DOI: 10.1016/j.ijom.2004.03.018.

Zoeller, J., Kasiyanchuк, М., & Fochuk, P. (2016). Conservation method of bone adaptive opportunities during oral osteoplastic surgical intervention. In: Conference proceedings International Osteology Symposium in Monaco; Apr 21-23; Monaco. Monaco: Osteology Foundation, Switzerland, 143.

Klug, C., Schicho, K., Ploder, O., Yerit, K., Watzinger, F., & Ewers R. (2006). Point-to-point computer-assisted navigation for precise transfer of planned zygoma osteotomies from the stereolithographic model into reality. J. Oral. Maxillofac. Surg., 64(3), 550-559. DOI: 10.1016/j.joms.2005.11.024.

Zoeller, J., Ostapov, S., Kasiyanchuk, Y., Pshenichka, P., Kasiyanchuk, М., & Fochuk, Р. (2015). Medical navigation as a method of minimize posteriori error in oral osteoplastic surgical intervention. In: Proceedings of the Forth International Conference Informatics and computer technics problems (PICT-2015), May 26-29, Chernivtsi. Chernivtsi, 81-83.

Horowicz, G., applicant; Horowicz, G., patent owner. Dental Guiding System аnd Method. Patent US № WO/2015/107520. 2015 Jul 23.

Kasiianchuk, Yu.M., Fochuk, P.M., & Kasiianchuk, M.V. (2016). Zastosuvannia platformy ,,Android’’ u systemakh medychnoi navihatsii v aspekti do klinichnykh doslidzhen [Application of the Android platform in medical navigation systems in the context of clinical trials]. Materialy V Mizhnar. nauk.-prakt. konf. Problemy informatyky ta kompiuternoi tekhniky (PIKT-2016) – Materials V International. science and practice conf. "Problems of informatics and computer technology (PIKT-2016). Chernivtsi: Rodovid [in Ukrainian].

Kasiianchuk, Yu.M., Rusnak, M.A., Fochuk, P,M., & Kasiianchuk, M.V. (2016). Erhonomika pryladiv endoskopii ta kompiuternoho suprovodu aspekti doklinichnykh ta klinichnykh doslidzhen [Ergonomics of endoscopy devices and computer support aspects of preclinical and clinical research]. Materialy V Mizhnar. nauk.-prakt. konf. Problemy informatyky ta kompiuternoi tekhniky (PIKT-2016) – Materials V International. science and practice conf. "Problems of informatics and computer technology (PIKT-2016). Chernivtsi: Rodovid [in Ukrainian].

Kasiianchuk, Yu.M., Kasiianchuk, M.V. vynakhidnyky; Kasiianchuk, Yu.M., & Kasiianchuk, M.V. patentovlasnyky. Prylad "Navihator YuK-M" dlia vyznachennia pozytsiiuvannia instrumentu chy implantatu pry operatyvnykh vtruchanniakh [Device "Navigator UK-M" to determine the position of the tool or implant during surgery]. Patent Ukrainy № 85876. 2013 Hru 10 [in Ukrainian].

Kasiianchuk, Yu.M., Pshenichka, P.F., & Kasiianchuk, M.V. vynakhidnyky; Kasiianchuk, Yu.M., Pshenichka, P.F., & Kasiianchuk, M.V. patentovlasnyky. Prylad "Navihator YuK" dlia vyznachennia pozytsiiuvannia instrumentu chy implantatu pry operatyvnykh vtruchanniakh [Device "Navigator UK" for determining the position of the tool or implant during surgery]. Patent Ukrainy № 68641. 2012 Kvi. 10. [in Ukrainian].

Kasiyanchuk, M., Fochuk, P., Ostapov, S., Pshenichka, P., & Kasiyanchuk, Y. (2013). Мedical navigation as a method of preclinical investigation optimization in oral osteoplastic surgical intervention. Int. Poster. J. Dent. Oral. Med., 1, 220.

Kasiyanchuk, M., Fochuk, P., Ostapov, S., Pshenichka, P., Kasiyanchuk, Y. (2013). Тhe method of clinical trial optimization at oral osteoplastic surgical intervention. In: Conference proceedings International Osteology Symposium in Monaco; 2013; Monaco. Monaco: Osteology Foundation; Monaco.

Kasiyanchuk, M.V., Pshenichka, P.F., Ostapov, S.E., Fochuk, P.M., & Kasiyanchuk, Y.M. (2013). Metodolohichni aspekty navchalnoho protsesu ta tekhnolohii medychnoi navihatsii v klinitsi stomatolohii [Methodological aspects of educational process and medical navigation technology in dentistry clinic]. Novyny stomatolohii – Dentistry News, 1, 99-102 [in Ukrainian].

Kokh, R. (2019). Pryntsyp 80/20. Sekret dosiahnennia bilshoho za menshykh vytrat [Principle 80/20. The secret to achieving more at less cost]. Kyiv: KM-BUKS [in Ukrainian].

Niuport, K. (2018). Ne turbuvaty! Yak sfokusuvatysia v informatsiinomu shumi [Do not disturb! How to focus in information noise]. Kyiv: Nash format [in Ukrainian].

Barns, A. (2017). Yak buty usvidomlenym [How to be aware]. Kharkiv: Fabula [in Ukrainian].

Downloads

Published

2022-09-06

How to Cite

Yasinskyi, M. M., Karavan, Y. R., Rusnak, M. A., & Kasiyanchuk, M. V. (2022). Conjunctive application of devices based on the Android platform in radiovisiographic research under war conditions in Ukraine. CLINICAL DENTISTRY, (2), 12–21. https://doi.org/10.11603/2311-9624.2022.2.13161

Issue

No. 2 (2022)

Section

Ortopedic stomatology

License

Copyright (c) 2022 CLINICAL DENTISTRY

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.