PARAMETERS OF VITREOUS CHEMILUMINESCENCE UNDER THE INFLUENCE OF ULTRASONIC AND PNEUMATIC GUILLOTINE VITRECTOMY

Purpose. To study and compare the chemiluminescence parameters of the vitreous body aspirate during microinvasive ultrasonic 25G vitrectomy and pneumatic guillotine 25G vitrectomy.
Material and methods. The study was performed by chemiluminescence in the chemiluminometer "KhLM-003" (Ufa State Aviation Technical University, Russia) with subsequent analysis of chemiluminescence parameters light sum (S) and the maximum amplitude of the slow flash (Imax) on the intact vitreous body and on the vitreous aspirate of 16 Chinchilla rabbits eyes operated on by microinvasive ultrasonic 25G vitrectomy (main group, n=8) and pneumatic guillotine 25G vitrectomy (control group, n=8).
Results. The addition of aspirate samples to the model system increased the level of the light sum and the maximum luminosity. The difference in the light sum in case of the intact vitreous body in the main group was 16.7±6.2%, in the control group it was 14.2±9.3%. The tendencies towards an increase in the light sum and maximum luminosity revealed as a result of the study were comparable in the two groups, p>0,05.
Conclusion. There were no significant differences in parameters of vitreous aspirate chemiluminescence during microinvasive ultrasonic and pneumatic guillotine 25G vitrectomy.

1. Neroev, V.V. Invalidnost' po zreniyu v Rossijskoj Federacii. Dokl. na oftal'mologicheskom kongresse «Belye nochi ‒ 2017». ‒ SanktPeterburg, 2017. (In Russ)

2. Stolyarenko G.E. Osobennosti vitreomakulyarnogo interfejsa pri epiretinal'nom fibroze / G.E. Stolyarenko, A.A. Kolchin, L.V. Didenko // X S"ezd oftal'mologov Rossii. Tez. dokl. 2015. ‒ S. 162. (In Russ)

3. Stebnev V.S. Mikroinvazivnaya hromovitrektomiya v lechenii bol'nyh s vitreomakulyarnoj adgeziej: dis. … d-ra med. nauk. ‒ Samara, 2016. ‒ 309 s. (In Russ)

4. Kosovsky, L.V. The use of domestic ultrasonic phacofragmentator in eye surgery (message 2) / L.V.Kosovsky, G.E. Stolyarenko, I.L. Kossovskaya // Vestnik oftalmologii. ‒ 1983. ‒ No. 3. ‒ S. 29-33.

5. Girard, L.G. Ultrasonic fragmentation for vitrectomy and associated surgical procedures / L.G. Girard, R. Niewes, R.S. Hawkins // Trans. Sect. Ophthalmol. Am. Acad. Ophthalmol. Otolaryngol. – 1976. – 81. – P. 432-450.

6. Mohamed S. Review of Small Gauge Vitrectomy: Progress and Innovations / S. Mohamed, С. Claes, C.W. Tsang // Hindawi Journal of Ophthalmology. ‒ 2017. ‒ P. 1-9.

7. Pavlidis M. Two-Dimensional Cutting (TDC) Vitrectome: In vitro flow assessment and prospective clinical study evaluating core vitrectomy efficiency versus standard vitrectome / М. Pavlidis // Hindawi Journal of Ophthalmology. ‒ 2016. ‒ P. 1-6.

8. Performance analysis of a new hypersonic vitrector system / Stanga P.E. [et al.] // Plos One. – 2017. – № 6. ‒ Р. 2-3.

9. Wuchinich, D. Ultrasonic vitrectomy instrument / D. Wuchinich // Physics Procedia. – 2015. – Vol. 63 – P. 217-222.

10. Charles, S. Vitreous Microsurgery / S. Charles, J. Calzada, B. Wood // Lippincott Williams & Wilkins, a Wolters Kluwer business, 2011. – P. 259.

11. Ultrastructural and histopathologic findings after pars plana vitrectomy with a new hypersonic vitrector system / S. Pastor-Idoate [et al.] // Qualitative preliminary assessment / PLoS One. – 2017. – Vol. 12. – P. 4.

12. Milowska, K. Reactive oxygen species and DNA damage after ultrasound exposure. / K. Milowska, T. Gabryelak // Biomolecular Engineering. – 2007. 24(2). ‒ P. 263-267.

13. Turrens, J.F. Formation of reactive oxygen species / J.F. Turrens // Journal of Physiology. – 2003. – Vol. 552. – P. 335-44.

14. Liochev, S.I. Reactive oxygen species and the free radical theory of aging // S.I. Liochev // Free Radic Biol Med. ‒ 2013. – Vol. 60. ‒ P. 1-4.