Functional activity of leucocytes in seminal fluid of patients with pathos-permia


如何引用文章

全文:

开放存取 开放存取
受限制的访问 ##reader.subscriptionAccessGranted##
受限制的访问 订阅或者付费存取

详细

Objective. Assessment of leukocyte activity as the main source of ROS in seminal fluid of patients with normospermia and pathospermia using an original protocol based on the kinetic chemiluminescence method and adapted for semen analysis. Materials and methods. A prospective study was attended by 95 men of reproductive age who applied to the Research Center of Medical Genetics (Moscow) for semen analysis. The material for the study were samples of native ejaculate. Chemiluminescent measurements were performed on a Lum-1200 chemiluminometer (DISoft, Russia) using the original method. Results. Both in amplitude of basal and stimulated response, between the “normozoospermia”, “pathozoospermia” and “pathozoospermia + leucospermia” groups, significant differences were obtained in the level of ROS production by leukocytes (p<0.05): the median level of basal chemiluminescence, normalized on the count of leukocytes was 0.13, 0.71 and 1.78, respectively; the median level of stimulated chemiluminescence normalized to the number of leukocytes was 0.62, 2.14, 5.94, respectively. The level of stimulated response did not exceed 0.5 arb. units in normozoospermic samples. In pathospermic groups, the level of stimulated response was low in about a third of semen samples, it was moderate in one third of patients, and high in one third of patients. Conclusions. A protocol previously developed for blood analysis was adapted to analyze the total ROS level produced by leukocytes in seminal fluid. In the groups of “pathozoospermia”, “pathozoospermia + leucospermia”, the level of basal ROS production by leukocytes was about 5 and 15 times higher than in the “normozoospermia” group, the level of stimulated ROS production was 3.5 and 9.5 times; this indicates oxidative stress, including with a normal number of leukocytes.

全文:

受限制的访问

作者简介

E. Proskurnina

Bochkov Research Center for Medical Genetics

Email: proskurnina@gmail.com
MD, Doctor of Medical Sciences, chief researcher at the Laboratory of Molecular Biology Moscow, Russia

N. Melnikov

Lomonosov Moscow State University

Email: elniko.nikita@yandex.ru
MD, resident at the Faculty of Fundamental Medicine Moscow, Russia

V. Chernykh

Bochkov Research Center for Medical Genetics

Email: chernykh@med-gen.ru
MD, Doctor of Medical Sciences, Professor, head of the Laboratory of Genetics of Reproductive Disorders Moscow, Russia

S. Chistyakova

Lomonosov Moscow State University

Email: sevastyana98@gmail.com
MD, Candidate of Medical Sciences, associate professor at the Department of Urology and Andrology of the Faculty of Fundamental Medicine, senior researcher at the Medical Scientific and Educational Center Moscow, Russia

D. Okhobotov

Lomonosov Moscow State University

Email: 14072003m@gmail.com
Moscow, Russia

A. Kamalov

Lomonosov Moscow State University

Email: armais.kamalov@rambler.ru
MD, Doctor of Medical Sciences, Professor, Full Member of the Russian Academy of Sciences, director of the Medical Research and Education Center, head of the Department of Urology and Andrology of the Faculty of Fundamental Medicine Moscow, Russia

参考

  1. Agarwal A., Durairajanayagam D., Halabi J., Peng J., Vazquez-Levin M. Proteomics, oxidative stress and male infertility. Reprod Biomed Online. 2014;29(1):32- 58.
  2. Sukhikh G.T., Bozhedomov V.A. Male infertility. Moscow: Eksmo; 2009. Russian (Сухих Г.Т., Божедомов В.А. Мужское бесплодие. М.: Эксмо; 2009).
  3. Aitken R.J., Smith T.B., Jobling M.S., Baker M.A., De Iuliis G.N. Oxidative stress and male reproductive health. Asian J Androl. 2014;16(1):31-38.
  4. Sharma R.K., Thompson A., Kothari S., Agarwal A. Oxidative stress in male reproduction. In: Pantopoulos K, Schipper HM, editors. Principles of Free Radical Biomedicine: Nova Science Publisher, Inc.; 2012. Р. 305-327.
  5. Aitken R.J., Baker M.A., Nixon B. Are sperm capacitation and apoptosis the opposite ends of a continuum driven by oxidative stress? Asian J Androl. 2015;17(4):633-639.
  6. Sabeti P., Pourmasumi S., Rahiminia T., Akyash F., Talebi A.R. Etiologies of sperm oxidative stress. Int J Reprod Biomed. 2016;14(4):231-240.
  7. Ishii T., Yasuda K., Miyazawa M., Mitsushita J., Johnson T.E., Hartman P.S. Infertility and recurrent miscarriage with complex II deficiency-dependent mitochondrial oxidative stress in animal models. Mech Ageing Dev. 2016;155:22-35.
  8. Kulabukhov V.V., Ryabov G.A. Modern methods for assessing the body’s oxygen status and the possibility of metabolic monitoring of critical conditions. Kremlin medicine. Klinicheskij vestnik. 1996;2:43-46. Russian (Кулабухов В.В., Рябов Г.А. Современные методы оценки кислородного статуса организма и возможности метаболического мониторинга критических состояний. Кремлевская медицина. Клинический вестник. 1996;2:43-46).
  9. World Health Organization. WHO Laboratory manual for the examination and processing of human semen. 5th edition; 2010. 287 pp.
  10. Aitken R.J., Buckingham D.W., West K.M. Reactive oxygen species and human spermatozoa: analysis of the cellular mechanisms involved in luminol- and lucigenin-dependent chemiluminescence. J Cell Physiol. 1992;151(3):466-477.
  11. McKinney K.A., Lewis S.E., Thompson W. Reactive oxygen species generation in human sperm: luminol and lucigenin chemiluminescence probes. Arch Androl. 1996;36(2):119-125.
  12. Образцов И.В., Годков М.А., Полимова А.М., Дёмин Е.М., Проскурнина Е.В., Владимиров Ю.А. Оценка функциональной активности нейтрофилов цельной крови методом двухстадийной стимуляции: новый подход к хемилюминесцентному анализу. Российский иммунологический журнал. 2015;9 (18)(4):418-425).
  13. Aitken R.J., West K.M. Analysis of the relationship between reactive oxygen species production and leucocyte infiltration in fractions of human semen separated on Percoll gradients. Int J Androl. 1990;13(6):433-451.

补充文件

附件文件
动作
1. JATS XML
下载

版权所有 © Bionika Media, 2019
##common.cookie##