П.В. Никитин scite author profile

We applied terahertz (THz)-pulsed spectroscopy to study ex vivo the refractive index and absorption coefficient of human brain gliomas featuring different grades, as well as perifocal regions containing both intact and edematous tissues. Glioma samples from 26 patients were considered and analyzed according to further histological examination. In order to fix tissues for the THz measurements, we applied gelatin embedding, which allows for sustaining their THz response unaltered, as compared to that of the freshly excised tissues. We observed a statistical difference between the THz optical constants of intact tissues and gliomas of grades I to IV, while the response of edema was similar to that of tumor. The results of this paper justify a potential of THz technology in the intraoperative label-free diagnosis of human brain gliomas for ensuring the grosstotal resection.

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Terahertz dielectric spectroscopy of human brain gliomas and intact tissues ex vivo: double-Debye and double-overdamped-oscillator models of dielectric response

Gavdush

Chernomyrdin

Komandin

et al. 2020

Biomed. Opt. Express

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Terahertz (THz) technology offers novel opportunities in the intraoperative neurodiagnosis. Recently, the significant progress was achieved in the study of brain gliomas and intact tissues, highlighting a potential for THz technology in the intraoperative delineation of tumor margins. However, a lack of physical models describing the THz dielectric permittivity of healthy and pathological brain tissues restrains the further progress in this field. In the present work, the ex vivo THz dielectric response of human brain tissues was analyzed using relaxation models of complex dielectric permittivity. Dielectric response of tissues was parametrized by a pair of the Debye relaxators and a pair of the overdamped-oscillators – namely, the double-Debye (DD) and double-overdamped-oscillator (DO) models. Both models accurately reproduce the experimental curves for the intact tissues and the WHO Grades I–IV gliomas. While the DD model is more common for THz biophotonics, the DO model is more physically rigorous, since it satisfies the sum rule. In this way, the DO model and the sum rule were, then, applied to estimate the content of water in intact tissues and gliomas ex vivo. The observed results agreed well with the earlier-reported data, justifying water as a main endogenous label of brain tumors in the THz range. The developed models can be used to describe completely the THz-wave – human brain tissues interactions in the frameworks of classical electrodynamics, being quite important for further research and developments in THz neurodiagnosis of tumors.

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Optimal hyperosmotic agents for tissue immersion optical clearing in terahertz biophotonics

Musina

Dolganova

Chernomyrdin

et al. 2020

Journal of Biophotonics

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In this work, a thorough analysis of hyperosmotic agents for the immersion optical clearing (IOC) in terahertz (THz) range was performed. It was aimed at the selection of agents for the efficient enhancement of penetration depth of THz waves into biological tissues. Pulsed spectroscopy in the frequency range of 0.1 to 2.5 THz was applied for investigation of the optical properties of common IOC agents. Using the collimated transmission spectroscopy in visible range, binary diffusion coefficients of tissue water and agent in ex vivo rat brain tissue were measured. IOC agents were objectively compared using two-dimensional nomogram, accounting for their THz-wave absorption coefficients and binary diffusion coefficients. The results of this study demonstrate an interplay between the penetration depth enhancement and the diffusion rate and allow for pointing out glycerol as an optimal agent among the considered ones for particular applications in THz biophotonics.

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Effects of age on mechanical and structural properties of myocardium of Fischer 344 rats

Anversa

Puntillo

Никитин

et al. 1989

American Journal of Physiology-Heart and Circulatory Physiology

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To determine whether the mechanical and structural characteristics of the myocardium from the left and right ventricles are comparable in the adult rat and whether aging affects the two ventricles in a similar manner, the left and right posterior papillary muscles of rats at 10-11 and 19-20 mo of age were studied in terms of function and quantitative morphology. At 10-11 mo of age, the duration of isometric contraction was shorter and resting tension higher in the right muscle than in the left muscle. Isotonic velocity of shortening and relengthening were quicker in the left, but time-to-peak shortening was faster in the right. With aging (19-20 mo), velocity of shortening fell in the left ventricle while duration of contraction became prolonged. No such age-related effects were found in the right papillary muscle. On a structural basis, myocardial damage in the form of replacement scarring was present in the left and right muscles at 10-11 mo of age. However, the left muscle was more severely injured, and this difference persisted with age because a comparable increase in replacement fibrosis occurred in both muscles. It was concluded that cardiac performance is distinctly different in the left and right papillary muscles and aging exerts its detrimental impact on the left more than in the right myocardium, an observation that is further supported by the magnitude of tissue injury.

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