The Role of Hyperhomocysteinemia in the Development of Changes in the Lungs

Author(s): Inga Samborska, Oleksandr Kovalchuk, Sharmila Fagoonee, Tetyana Falalyeyeva*, Oleksandr Maievskyi.

Journal Name: Reviews on Recent Clinical Trials

Volume 15 , Issue 1 , 2020

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Abstract:

Background: In recent years, attention of the scientific community has been drawn to the study of the role of homocysteine in the pathology of diseases in general and the respiratory system in particular. Violations of the synthesis and disposal of homocysteine are the cause of its excessive accumulation in the body, which subsequently leads to damage to all organs and systems.

Methods: We conducted this study on 64 white non-linear rats of 6-8 and 24-26 months old rats, which were divided into two control and experimental groups during the experiment. The study of ultrastructural changes in the lungs of rats was performed using an electron microscope.

Results: The results of the conducted study show that all the animals of the experimental group, corresponding to 32 (50%) cases, possess conspicuous morphological changes in the structure of the lungs.

The specific features of mature animals were the narrowing of the alveolar space of the part of the alveoli and the increase in the number of macrophages in them. Partial desquamation of capillary endothelial lining and a slight increase of collagen fibers in interalveolar membranes were observed compared to control animals. A characteristic feature for older animals was the growth of connective tissue, predominantly collagen fibers, which led to pneumosclerosis. The thickening of the aerogemic barrier was also detected, and the endothelial lining was intermittent or desquamated.

Conclusion: Mature animals of the experimental group were characterized by activation of inflammatory processes, oxidative stress, due to increased production of macrophages and, as a consequence, the launch of the humorous link of immunity, while in old rats were determined by fibrosis, disorders of the trophic and gas metabolism, as well as damage to the endothelium part of lungs.

Keywords: Alveolocytes, apoptosis, homocysteine, hyperhomocysteinemia, lungs, macrophages, necrosis.

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VOLUME: 15
ISSUE: 1
Year: 2020
Page: [48 - 59]
Pages: 12
DOI: 10.2174/1574887114666191114152235
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