Физиологическая оценка результатов спектрометрии содержания оксигемоглобина и реакции микрососудов на изменение гемодинамики

Проанализированы данные спектрометрических измерений плотности, площади сечения микроциркуляторных сосудов поверхностных тканей, содержания в крови тканевых сосудов оксигемоглобина и их реакции на прекращение кровотока, ограничение притока артериальной крови и блокады оттока венозной крови. Характер и направленность полученных изменений согласуются с существующими представлениями о физиологических и патофизиологических механизмах реагирования сосудов и метаболизма тканей на нарушения локального кровотока. Метод спектрометрии может найти применение для оценки соответствия микроциркуляции метаболическим потребностям тканей в условиях физиологических нагрузок и патологии.

1. Shury’gin I.A. Monitoring dy’haniya: p u l’soksimetriya, kapnografiya, oksimetriya [Breath monitoring: pulse oximetry, capnography, oximetry]. SPb: Nevskiy Dialekt ; M. : BINOM, 2000, 301 p. (in Russian).

2. Hitachi Developing Non-Invasive Blood Sugar Monitoring Device. Proprietary Technologies Would Take the Pain and Hassle Out of Measuring Blood Sugar Levels [electronic resource]. Available at: https:// www.yumpu.com/en/document/view/22311684/hitachi-developing-non- invasive-blood-sugar-monitoring-device. (accessed: 19. 10. 2017).

3. Tuchina V.V. eds. Opticheskaya biomedicinskaya diagnostika. T 1. [Optical biomedical diagnostics. T.1]. Moskw: FizMatLit, 2007, 560 s. (in Russian).

4. Rogatkin D.A. Fizicheskie osnovy’ opticheskoy oksimetrii [Physical basis of optical oximetry]. Med fizika, 2012, № 2, pp. 97-114. (in Russian).

5. Drexler W. Cellular and Functional Optical Coherence Tomography of the Human Retina the Cogan Lecture. Invest Ophthalmol Vis Sci, 2007, vol. 48, № 12, pp. 5340-5351.

6. Palczewski1 K. Silver Anniversary Review Focus on vision: 3 decades of remarkable contributions to biology and medicine. FASEB J 2011, vol. 25, № 2, pp. 439-443.

7. Cheung C.Y., Ikram M.K., Sabanayagam Ch., Wong T.Y. Retinal Microvasculature as a Model to Study the Manifestations of Hypertension. Hypertension, 2012, vol. 60, № 5, pp. 1094-1103.

8. Jacques S.L. Corrigendum: Opticalpropertiesofbiologicaltissues: areview. Phys Med Biol, 2013, vol. 58, pp. 5007.

9. Ly’senko S.A., Firago V.A., Kugeyko M.M., Kubarko A.I. Opredelenie strukturno-morfologicheskih parametrov bul’barnoy kon‘yunktivy’ cheloveka po spektram diffuznogo otrajeniya sveta [The definition of structural- morphological parameters of the bulbar conjunctiva of man in the spectra of diffuse reflection of light]. Jurnprikladnoyspektroskopii, 2016, vol. 83, № 4, pp. 606-615. (in Russian).

10. Nerobeev A. I., Dobrodeev A. S., Maly’hina I.F., Somova M.M., Garelik E.I. Kriterii vy’jivaemosti my’shechny’h loskutov na osnove tkanevoy somaticheskoy oksimetrii [Free muscle flaps survival criteria on the basis of tissue somatic oximetry]. Annaly’ plast, rekonstruktivie'stethirurgii, 2014, № 3, pp. 10-18. (in Russian).

11. Maly’hina I.F., Nerobeev A.I., Dobrodeev A.S., Verbo E.V., Garelik E.I., Salihov K.S. Tkanevaya oksimetriya: ocenka jiznesposobnosti svobodny’h loskutov pri rekonstrukcii [Tissue Oximetry: Monitoring of Microsurgical Freetissue Transfers for Head and Neck Reconstruction]. Vopr rekonstruktiv ipiasthirurgii, 2015, vol. 18, № 2, pp. 11-24. (in Russian).

12. Pinto M., Barjas-Castro M. L., Nascimenti S. The new noninvasive occlusion spectroscopy hemoglobin measurement method: a reliable and easy anemia screening test for blood donors. Transfusion, 2013, vol. 53, pp. 766-769.

13. Lima A., van Bommel J., Sikorska K., van Genderen M., Klijn E., Lesaffre E., Ince C., Bakker J. The relation of near-infrared spectroscopy with changes in peripheral circulation in critically ill patients. Crit Care Med, 2011, vol. 39, № 7, pp. 1649-1654. doi: 10.1097/CCM.0b013e3182186675.

14. Liasi F.T., Samatham R., Jacques S.L. Noninvasive in vivo optical characterization of blood flow and oxygen consumption in the superficial plexus of skin. JBiomed Opt, 2017, vol. 22, № 11, pp. 1-6. doi: 10.1117/ 1.JBO.22.11.115002.

15. Dunaev A.V., Rogatkin D.A. K voprosu o vozmojnosti ispol’zovaniya metodov neinvazivnoy spektrofotometrii dlya kontrolya e‘ffektivnosti nizkointensivnoy lazernoy terapii [To question of possibility to use methods of non-invasive spectrophometry for controlling the effectiveness of the low level laser therapy]. Fundam i priklad problemy’ tehniki I tehnoiogii, 2009, № 3, pp. 110-115. (in Russian).

16. Stromblad S. Measuring the Optical Properties o f Human Muscle Tissue using Time-of-Flight Spectroscopy in the Near Infrared: Magist. diss. Lund University Faculty of Engineering. LTH, 2015, 45 p.

17. Wang W., Winlove C.P., Michel C.C. Oxygen partial pressure in outer layers of skin of human finger nail folds. J Physiol, 2003, vol. 549, № 3, pp. 855-863. doi: 10.1113/jphysiol.2002.037994.

18. Ly’senko S. A. Operativnaya diagnostika bioob'ektovpo spektral’noprostranstvenny’m harakteristikam ih svetorasseyaniya [Operative diagnostics of biological objects by spectral-spatial characteristics of their light scattering]: Avtoref. diss. d-ra. fiz.-mat. nauk : 01.04.05. Minsk, BGU, 2017, 46 s. (in Russian).

19. Krog A. Anatomiya i fiziologiya kapillyarov [The anatomy and physiology of capillaries]. M.: Moszdravotdel, 1927, 184 p. (in Russian).

20. Svaasand L.O., Norwang L.T., Fiskerstrand E.J., Stopps E.K.S., Berns M.W., Nelson J.S. Tissue parameters determining the visual appearance of normal skin and port-wine stans. Laser Med Sci, 1995, vol. 10, pp. 55-65. doi: 10.1007/bf02133165.

21. Gayton A.K., Holl E. Medicinskaya fiziologiya [Medical physiology]. M.: Logosfera, 2008, 1296 s. (in Russian).

22. Marchal G., Young A.R., Baron J-C. Early Postischemic Hyperperfusion: Pathophysiologic Insights From Positron Emission Tomography. J Cereb Blood Flow Metab, 1999, № 19, p. 467-482.

23. Tkachenko B.I. eds. Fiziologiya krovoobrasch’eniya: fiziologiya sosudistoy sistemy’ [Physiology of blood circulation: physiology of the vascular system]. L. : Nauka, 1984, 652 s. (in Russian).

24. Jaszczak P. Skin oxygen tension, skin oxygen consumption, and skin blood flow measured by a tc-pO2 electrode. Acta PhysiolScandSupplJ991, № 603, pp. 53-57.

25. Grundman A., Ludders D.W. The determination of the O2-consumption of the skin by the measurement of the decrease of the skin surface PO2 after flow stop using an optical O2-stnsor without O2-consumption : a theoretical analysis. Grote J., Witzleb eds. Regulation of blood flow and tissue oxygen supply. Verlag, 1994, pp. 265-270.

26. Jensen-Kondering U., Baron J-C. Oxygen Imaging by MRI: Can Blood Oxygen Level-Dependent Imaging Depict theIschemic Penumbra? Stroke, 2012, vol. 43, № 8, pp. 2264-2269. doi: 10.1161/STROKEAHA.111.632455.

27. Pal’cev M.A., Anichkov N.M. Patologicheskaya anatomiya. T. 1: Obsch’iy kurs [Pathological anatomy. Vol. 1: General course.]. M.: Medicina, 2001, 528 s. (in Russian).