Modern approaches and new methodological possibilities in the functional state of small laboratory animals assessing

Authors

  • Yu. M. Kolesnyk Zaporizhzhia State Medical University, Ukraine,
  • O. V. Hancheva Zaporizhzhia State Medical University, Ukraine,
  • A. V. Abramov Zaporizhzhia State Medical University, Ukraine,
  • M. Yu. Kolesnyk Zaporizhzhia State Medical University, Ukraine,
  • T. V. Ivanenko Zaporizhzhia State Medical University, Ukraine,
  • S. V. Tishсhenko Zaporizhzhia State Medical University, Ukraine,
  • M. V. Danukalo Zaporizhzhia State Medical University, Ukraine,
  • M. I. Fedotova Zaporizhzhia State Medical University, Ukraine,

DOI:

https://doi.org/10.14739/2310-1237.2017.3.118770

Keywords:

heart function tests, echocardiography, electrocardiography, bioimpedance measurement, arterial pressure, rats

Abstract

Modern biomedical research conducted in scientific laboratories is a basis not only for studying the pathogenetic mechanisms of diseases formation and progression, today they are widely used for highly informative diagnostic methods development, new medicines creation, and the study of newly developed pharmaceutical compounds influence on the organism with their potential effectiveness assessment. The article highlights new approaches and possibilities for the functional state of small laboratory animals assessing, taking into account modern international requirements for research conduction and findings interpretation.

References

Zutphen van, L. F., Baumans, V., & Beynen, A. C. (2001) Principles of Laboratory Animal Science. Amsterdam: Elsevier.

Anon. (2014). The 2014 Lush Prize: A Global View of Animal Experiments 2014, 42pp. Retrieve from: http:// www.lushprize.org/wp-content/uploads/Global_View_of-Animal_Experiments_2014.pdf (Accessed 05.11.15).

Turner, P. V., Brab, Th., Pekow, C., & Vasbinder, M. A. (2011) Administration of substances to laboratory animals: routes of administration and factors to consider. Journal of the American Association for Laboratory Animal Science, 50(5), 600–613.

Konopelski, P., & Ufnal, M. (2016) Electrocardiography in Rats: a Comparison to Human. Physiological Research, 65, 717–725.

Kuzmenko, N. V, Pliss, M. G., & Tsyrlin, V. A. (2016) Invazivnye i neinvazivnye metody registracii parametrov gemodinamiki u krys linii Wistar v modeli renovaskulyarnoj gipertenzii (2 pochki, 1 zazhim) [Invasive and non-invasive methods of hemodynamic parameters registration in Wistar rats in renovaskular hypertension model (2 kidney, 1 clip)]. Translyacionnaya medicina, 3(2), 61–69. [in Russian].

Krege, J. H., Hodgin, J. B., Hagaman, J. R., & Smithies, O. (1995) A Noninvasive Computerized Tail-Cuff System for Measuring Blood Pressure in Mice. Hypertension, 25, 1111–1115.

Baranovskij, A. Yu. (2012) Dietologiya [Dietetics]. Saint Petersburg: Piter [in Russian].

Nikolaev, D. V., Smirnov, A. V., Bobrinskaya, I. G., & Rudnev, S. G. (2009) Bioimpedansnyj analiz sostava tela cheloveka [Bioimpedance analysis of the composition of the human body]. Moscow: Nauka [in Russian].

Tornuev, Yu. V., Nepomnyashchikh, D. L., Nikityuk, D. B., Lapij, G. A., Molodykh, O. P., Nepomnyashchikh, R. D., et al. (2014) Diagnosticheskiye vozmozhnosti neinvazivnoj bioimpedansometrii [Diagnostic capabilities of noninvasive bioimpedanceometry]. Fundamental'nyye issledovaniya, 10–4, 782–788. [in Russian].

Smith, D. Jr., Johnson, M., & Nagy, T. (2009) Precision and accuracy of bioimpedance spectroscopy for determination of in vivo body composition in rats. International Journal of Body Composition Research, 7(1), 21–26.

Yokoi, K., Lukaski, H. C., Uthus, E. O., & Nielsen, F. H. (2001) Use of bioimpedance spectroscopy to estimate body water distribution in rats fed high dietary sulfur amino acids. Journal of Nutrition, 131(4), 1302–1308.

Stefanov, O. V. (2001) Doklinichni doslidzhennia likarskykh zasobiv (metodychni rekomendatsii) [Preclinical research of medicinal products (methodical recommendations)]. Kyiv: Avitsena [in Ukrainian].

Kawahara, Y., Tanonaka, K. Daicho, T., Nawa, M., Oikawa, R., Nasa, Y., & Takeo, S. (2005) Preferable anesthetic conditions for echocardiographic determination of murine cardiac function. Journal of Pharmacological Sciences, 99, 95–104.

Xu, Q., Ming, Z., Dart, A. M., & Du, X. J. (2007) Optimizing dosage of ketamine and xylazine in murine echocardiography. Clinical and Experimental Pharmacology and Physiology, 34(5-6), 499–507. doi: 10.1111/j.1440-1681.2007.04601.x

Gao, Sh., Ho, D., Vatner, E., & Vatner, S. F. (2011) Echocardiography in mice. Current Protocols in Mouse Biology, 1, 71–83. doi: 10.1002/9780470942390.mo100130

Darbandi Azar, A., Tavakoli, F., Moladoust, H., Zare, A., & Sadeghpour, A. (2014) Echocardiographic evaluation of cardiac function in ischemic rats: value of M-mode echocardiography. Research in Cardiovascular Medicine, 3(4), е22941. doi: 10.5812/cardiovascmed.2294

Dragoi Galrinho, R., Ciobanu, A. O., Rimbas, R. C., Manole, C. G., Leena, B. M., & Vinereanu, D. (2015) New echocardiographic protocol for the assessment of experimental myocardial infarction in rats. MAEDICA – a Journal of Clinical Medicine, 10(2), 85–90.

Lakomkin, V. L., Abramov, A. A., Gramovich, V. V., Vyborov, O. N., Lukoshkova, E. V., Ermishkin, V. V., & Kapelko, V. I. (2017) Dinamika formirovaniya sistolicheskoj disfunkcii serdca pri doksorubicinovoj kardiomiopatii [The Time Course of Formation Of Systolic Dysfunction of the Heart in Doxorubicin Cardiomyopathy]. Kardiologiya, 57, 59–64. [in Russian].

Watson, L. E., Jewell, C., Song, J., & Dostal, D. E. (2013) Echocardiographic effects of eplerenone and aldosterone in hypertensive rats. Frontiers in Bioscience, 1(5), 922–927.

How to Cite

1.
Kolesnyk YM, Hancheva OV, Abramov AV, Kolesnyk MY, Ivanenko TV, Tishсhenko SV, Danukalo MV, Fedotova MI. Modern approaches and new methodological possibilities in the functional state of small laboratory animals assessing. Pathologia [Internet]. 2017Dec.22 [cited 2024Mar.28];(3). Available from: http://pat.zsmu.edu.ua/article/view/118770

Issue

Section

Modern technologies of scientific research