Morphology of exorbital lacrimal glands of not purebred white rats at high-intensity light influence

Purpose: this study morphological changes the exorbital lacrimal glands at experimental impact on an organ of vision of high-intensity light.

Material and methods. White not purebred rats males (n = 40) were subjected to continuous influence of light intensity by 3500 lx within 1, 7, 14 and 30 days, the control group (n = 10) contained in conditions of natural lighting (20 lx). Exorbital lacrimal glands fixed in formalin, embedded in paraffin wax, stained hematoxylin-eosine. By means of an oculary insert of Avtandilov counted specific volumes of output channels, an epithelium, stroma and vessels of exorbital lacrimal glands, defined an epitelio/stroma ratio. The analysis of data was carried out by methods of descriptive statistics with calculation of a median (Ме) and interquartile range (Q1 –Q3). For an assessment of distinctions used nonparametric criterion of Mann – Whitney.

Results. In 1 days in response to high-intensity light influence there is a reflex strengthening of synthetic function of exorbital lacrimal glands. For the 7th days the first signs of violation of functioning with development of hydropic dystrophy in the lacrimacytes appear. By 14th days fibrous changes develop, in a glandular parenchyma harderization sites appear. For the 30th days the nuclear pycnosis of separate lacrimacit, accumulation of a lipofuscin in cytoplasm is observed.

Conclusion. The obtained data allow to estimate in dynamics compensatory and adaptive reactions of lacrimal gland in response to high-intensity light influence from the moment of the beginning of their development before emergence of the first signs of a decompensation.

1. Venable J., Grafflin A. Gross anatomy of the orbital glands in the albino rat // J. Mammalogy. 1940; 21 (1): 66–71.

2. Conrady C.D., Joos Z.P., Patel B.C.K. Review: The lacrimal gland and its role in dry eye // Journal of Ophthalmology. 2016: 7542929. DOI 10.1155/2016/7542929.

3. Rocha E.M., Alves M., Rios J.D., Dartt D.A. The aging lacrimal gland: changes in structure and function // The Ocular Surface. 2008; 6 (4): 162–174.

4. Ryzhov A.I., Logvinov S.V., Yagnitsyna A.A. Morfologiya sleznogo apparata belykh krys pri vozdeystvii ultrafioletovykh luchey. Tomsk. 1984. 8 s. Rukopis predostavlena Tomskim med. in-tom. Dep. v VINITI 14.06.1984. № 4422-84 Dep. (in Russuan).

5. Logvinov S.V. Morfologiya sleznogo apparata beloy krysy pri vozdeystvii mikrovoln. Tomsk. 1984. 9 s. Rukopis predostavlena Tomskim med. in-tom. Dep. v VINITI 15.03.1984. ¹ 1455-84 Dep. (in Russuan).

6. Logvinov S.V. Morfologiya sleznoy ekzoorbitalnoy zhelezy posle drobnogo vozdeystviya rentgenovymi luchami // Vopr.teoret.i klinich.meditsiny. Tomskiy med.institut. 1984; 10: 78–81 (in Russuan).

7. Li J., Shan Z., Ou G. et al. Structural and functional characteristics of irradiation damage to parotid glands in the miniature pig // Int. J. Radiat. Oncol. Biol. Phys. 2005; 62: 1510–1516

8. Muhvic-Urek M., Bralic M., Curic S. et al. Imbalance between apoptosis and proliferation causes late radiation damage of salivary gland in mouse // Physiol. Res. 2006; 55: 89–95.

9. Nakamura S., Kinoshita S., Yokoi N. et al. Lacrimal hypofunction as a new mechanism of dry eye in visual display terminal users. Chakravarti S., ed.PLoS ONE. 2010; 5 (6): e11119.

10. Hakim S.G., Schroder C., Geerling G. et al. Early and late immunohistochemical and ultrastructural changes associated with functional impairment of the lachrymal gland following external beam radiation // International Journal of Experimental Pathology. 2006; 87 (1): 65–71.

11. Seo Y., Ji Y.W., Lee S.M. et al. Activation of HIF-1α (hypoxia inducible factor-1α) prevents dry eye-induced acinar cell death in the lacrimal gland // Cell Death & Disease. 2014; 5(6): e1309.

12. Brodskiy V.Ya., Uryvayeva I.V. Kletochnaya poliploidiya. Proliferatsiya i differentsirovka. M.: Nauka, 1981: 260 (in Russuan).

13. Ríos J.D., Horikawa Y., Chen L.-L. et al. Age-dependent alterations in mouse exorbital lacrimal gland structure, innervation and secretory response // Experimental eye research. 2005; 80 (4): 477–491. DOI 10.1016/j.exer.2004.10.012.

14. El-Fadaly A.B., El-Shaarawy E.A.A., Rizk A.A. et al. Age-related alterations in the lacrimal gland of adult albino rat: A light and electron microscopic study // Ann. Anat. 2014; 196 (5): 336–351. DOI 10.1016/j.aanat.2014.06.005.

15. Porta E.A. Dietary factors in lipofuscinogenesis and ceroidogenesis. // Arch. Gerontol. Geriatr. 2002; 34: 319–327.

16. Benson W.R. Acceleration of aging changes in the exorbital lacrimal gland of the female rat // The American Journal of Pathology. 1964; 45 (4): 587–597.

17. Ferrara D., Monteforte R., Baccari G. et. al. Androgen and estrogen receptors expression in the rat exorbital lacrimal gland in relation to “harderianization” // Journal of experimental zoology. Part A, Comparative experimental biology. 2004; 301 (4): 297–306.