Morphological study of lymphoid organs at early stages of experimental prostate carcinogenesis


Cite item

Full Text

Open Access Open Access
Restricted Access Access granted
Restricted Access Subscription or Fee Access

Abstract

Aim. the aim of our study was to identify of structural transformations in the thymus and lymph nodes at the early stages of the development of an experimental prostate cancer. Materials and methods. Experiments were performed on 60 adult male CBA mice weighing 28-30 g. An experimental model of a prostate cancer was created by inoculating a diluted cell strain of Ehrlich Ascites Carcinoma cells into the prostatic parenchyma through midline laparotomy under ether anesthesia. The animals were divided into three groups of 20 each: 1) control (intact animals) 2) animals on the 5th day of experimental prostate tumor growth and 3) animals on the 18th day of experimental prostate tumor growth. The pathological examination of the prostate, thymus, and pelvic lymph nodes was performed. The selection of structural components and cellular elements in the thymus and lymph nodes was carried out according to the International histological nomenclature. Results. According to the results, there was an increase in the percentage of connective tissue elements and glandular tissue increased in the thymus and the number of immunoblasts increased on the 5th day of the experiment. However, disorganization of the thymus structure was detected on the 18th day as well as an increase in the cortical substance, the number of epithelial reticular cells and decrease in the number of immunoblasts. On the 5th day, paracortical hyperplasia, sinus histiocytosis and activation of the blast transformation were detected in lymphatic nodes. On the 18th day, metastases, follicular reaction and activation of the transport function were determined. Conclusion. Our data suggest that the accidental thymus involution and impairment of transport and immune functions of pelvic lymph nodes in experimental prostate cancer. The severity of disturbances depends on the stage of prostate carcinogenesis.

Full Text

Restricted Access

About the authors

A. A Lomshakov

MC «Stolitsa»

Email: a.lomshakov@gmail.com
h.D., urologist

V. V Astashov

«RUDN University»

Email: vastashov3@gmail.com
MD, professor at the Department of Human Anatomy of Medical Institute

V. I Kozlov

«RUDN University»

Email: akvi13@yandex.ru
MD, professor, Honored Scientist of Russia, Head of the Department of Human Anatomy of Medical Institute

S. M Ryzhakin

«RUDN University»

associate professor at the Department of Human Anatomy of Medical Institute

M. V Uloga

«RUDN University»

assistant at the Department of Human Anatomy of Medical Institute

D. A Medyantseva

«RUDN University»

Email: mihail.uloga@mail.ru
assistant at the Department of Human Anatomy of Medical Institute

References

  1. Berezhnaya N.M., Chehun V.F. Immunology of malignant growth. Kyiv: Naukova Dumka, 2005. Ukraina (Бережная Н.М., Чехун В.Ф. Иммунология злокачественного роста. Киев: Наукова думка, 2005).
  2. Алексеев Б.Я., Русаков И.Г., Франк Г.А. и др. Определение сторожевых лимфатических узлов у больных раком предстательной железы. Российский онкологический журнал. 2006;5:16-22
  3. Harisinghani M.G., Barentsz J., Hahn P.F. et al. Noninvasive detection of clinically occult lymph-node metastases in prostate cancer. New Engl. J. Med. 2003;348(25):2491-2499.
  4. Асташов В.В., Ломшаков А.А., Ларионов П.М. и др. Лимфатические узлы и сосуды при экспериментальной опухоли простаты. Вестник НГУ; сер. Биол. 2011;9(2):118-125
  5. Лилли Р. Патологическая техника и практическая гистохимия. М.: Мир, 1969
  6. Sarkisov D.S., Perov Yu.L. Microscopic technique: manual. Rassian (Саркисов Д.С., Перов Ю.Л. Микроскопическая техника: руководство).
  7. Лапач С.Н., Чубенко Л.В., Бабич П.Н. Статистические методы в медико-биологических исследованиях с использованием Excel. Киев: МОРИОН, 2001
  8. Whiteside T.L. The role ofimmune cells the tumor microenvironment. Cancer Treatm. Res. 2006;130:103-124.
  9. Mailloux A.W., Young M.R. Regulatory T-cell trafficking: from thymic development to tumor-induced immune suppression. Crit. Rev. Immunol. 2010;30(5):435-447.
  10. Stewart T.J., Smyth M.J. Improving cancer immunotherapy by targeting tumor-induced immune suppression. Cancer Metastasis Rev. 2011;30(1):125-140.
  11. Киселева Е.П. Механизмы инволюции тимуса при опухолевом росте. Успехи современной биологии. 2004;124:589-601
  12. Bodey B., Siegel S.E., Kaise Н.Е. Immunological Aspects of Neoplasia -The Role of Thymus. Dordrecht: Boston: Kluwer Acad. Publ., 2004.
  13. Ивановская Т.Е., Зайратьянц О.В., Леонова Л.В., Волощук И.Н. Патология тимуса у детей. СПб.: Сотис, 1996.
  14. Ohm J.E., Gabrilovich D.I., Sempowski G.D. et al. VEGF inhibits T-cell development and may contribute to tumor-induced immune suppression. Blood. 2003;101:4878-4886.
  15. Datta K., Muders M., Zhang H., Tindall D.J. Mechanism of limph node metastasis inprostate cancer. Future Oncology. 2010;6(5): 823-836.

Supplementary files

Supplementary Files
Action
1. JATS XML
Download

Copyright (c) 2019 Bionika Media

This website uses cookies

You consent to our cookies if you continue to use our website.

About Cookies