Diagnostics of Toxic Lung Injuries
Keywords:
lungs, toxic damage, diagnostic methodsAbstract
The article is devoted to the diagnostics of morphogenesis of toxic lung damage and the possibilities of its diagnostics are currently more promising than before, since researchers have histochemical, immunohistochemical, electron microscopic, morphometric and other precision methods at their disposal, the use of which contributes to a more complete disclosure of the essence of this pathology. All this allows us to conduct a study of the pathological morphology of the lungs in poisoning at a new level and is a guarantee that a properly planned and well-supported study in terms of method can end with the receipt of results that are promising both in theoretical and practical terms.
References
Avdeev, S.N. The role and significance of inhaled glucocorticosteroids in patients with chronic obstructive pulmonary disease: current recommendations. Conclusion of the expert council. / S.N. Avdeev, Z.R. Aisanov, V.V. Arkhipov, A.S. Belevsky, I.V. Leshchenko, A.I. Sinopalnikov // Pulmonology. - 2019. - Vol. 29 (5) - P. 632–636.
Aleksandrov, N.S. Using Raman fluorescence spectroscopy for the diagnosis of clear cell renal cell carcinoma / N.S. Aleksandrov, S.T. Avraamova, Yu.A. Kirillov, T.O. Babicheva, V.I. Kukushkin, D.N. Artemyev // Clinical and experimental morphology. – 2017. – T. 4(24) – Р. 59–65.
Vdovina, N. V. The human body: life processes and their regulation: monograph / N. V. Vdovina. - 2nd ed., revised. and add. - Moscow: Yurait Publishing House, 2024. - 391 p.
Dvorakovskaya, I. V. Pathological anatomy of vascular lesions in influenza and viral-bacterial pneumonia / I. V. Dvorakovskaya, O. N. Titova, B. M. Ariel, I. S. Platonova, V. A. Volchkov, N. A. Kuzubova // Russian Medical Journal. - 2021. - Vol. 3 - P. 3–7.
Kirillov, Yu.A. Morphogenesis of pulmonary atelectasis under experimental radiation-induced exposure / Yu.A. Kirillov, I.A. Chernov, E.M. Malysheva, S.E. Timofeev, et al. // Clinical and experimental morphology. - 2020. - Vol. 9 - № 1.
"Clinical guidelines "Malignant neoplasm of the bronchi and lung" (approved by the Ministry of Health of Russia) [Electronic resource] / "Clinical guidelines. - 2021. - URL: https://cr.minzdrav.gov.ru/recomend/30_3 (date of access: 11/12/2021).
Rosenberg, O.A. Pulmonary surfactant preparations in acute and chronic lung diseases (part I) / O.A. Rosenberg // General reanimatology. - 2014. - Vol. 10 (4) - P. 51-73.
Chernyaev, A.L. Pulmonary atelectasis. In the book: Cellular biology of the lungs in health and pathology: a guide for doctors / Ed. V.V.Erohin, L.K.Romanova. / A.L. Chernyaev. - M .: Medicine, 2000. - Vol. 1 - P. 384-385.
Beike, L. Surfactant dysfunction and alveolar collapse are linked with fibrotic septal wall remodeling in the TGF-β1-induced mouse model of pulmonary fibrosis / L. Beike, C. Wrede, J. Hegermann, E. Lopez-Rodriguez, C. Kloth, J. Gauldie, M. Kolb, U.A. Maus, M. Ochs, L. Knudsen // Laboratory Investigation. – 2019. – Vol. 99 – № 6 – P. 830–852.
Bolourani, S. The interplay of DAMPs, TLR4, and proinflammatory cytokines in pulmonary fibrosis / S. Bolourani, M. Brenner, P. Wang // Journal of Molecular Medicine. – 2021. – Vol. 99 – № 10 – P. 1373–1384.
Cereda, M. Hyperpolarized gas diffusion MRI for the study of atelectasis and acute respiratory distress syndrome / M. Cereda, Y. Xin, S. Kadlecek, H. Hamedani, J. Rajaei, J. Clapp, R.R. Rizi // NMR in biomedicine. – 2014/06/11 ed. – 2014. – Vol. 27 – № 12 – P. 1468–1478.
Childs, B.G. Cellular Identification and Quantification of SenescenceAssociated β-Galactosidase Activity In Vivo. / B.G. Childs, T.J. Bussian, D.J. Baker // Methods in molecular biology (Clifton, N.J.). – 2019. – Vol. 1896 – P. 31–38.
Choi, J. Inflammatory Signals Induce AT2 Cell-Derived DamageAssociated Transient Progenitors that Mediate Alveolar Regeneration / J. Choi, J.-E. Park, G. Tsagkogeorga, M. Yanagita, B.-K. Koo, N. Han, J.-H. Lee // Cell Stem Cell. – Elsevier, 2020. – Vol. 27 – № 3 – P. 366-382.e7.
Colunga Biancatelli, R.M.L. Age-Dependent Chronic Lung Injury and Pulmonary Fibrosis following Single Exposure to Hydrochloric Acid. / R.M.L. Colunga Biancatelli, P. Solopov, C. Dimitropoulou, J.D. Catravas // International journal of molecular sciences. – 2021. – Vol. 22 – № 16.
Hur, W. Molecular Pathogenesis of Radiation-Induced Cell Toxicity in Stem Cells / W. Hur, S.K. Yoon // International Journal of Molecular Sciences. – 2017. – Vol. 18 – № 12.
Jarzebska, N. Scarred Lung. An Update on Radiation-Induced Pulmonary Fibrosis / N. Jarzebska, E.S. Karetnikova, A.G. Markov, M. Kasper, R.N. Rodionov, P.M. Spieth // Frontiers in Medicine. – 2021. – Vol. 7 – P. 1100.
Judge, J.L. The Lactate Dehydrogenase Inhibitor Gossypol Inhibits Radiation-Induced Pulmonary Fibrosis. / J.L. Judge, S.H. Lacy, W.-Y. Ku, K.M. Owens, E. Hernady, T.H. Thatcher, J.P. Williams, R.P. Phipps, P.J. Sime, R.M. Kottmann // Radiation research. – 2017. – Vol. 188 – № 1 – P. 35–43.
Kavanaugh, J. Anatomical Adaptation-Early Clinical Evidence of Benefit and Future Needs in Lung Cancer. / J. Kavanaugh, G.D. Hugo, C. Robinson, M. Roach // Seminars in radiation oncology. – 2019. – Vol. 29 3 – P. 274–283.
Li, F. Risk factors for radiation pneumonitis in lung cancer patients with subclinical interstitial lung disease after thoracic radiation therapy / F. Li, H. Liu, H. Wu, S. Liang, Y. Xu // Radiation Oncology. – 2021. – Vol. 16 – № 1 – P. 70.
Mungunsukh, O. Captopril reduces lung inflammation and accelerated senescence in response to thoracic radiation in mice / O. Mungunsukh, J. George, E.A. McCart, A.L. Snow, J.J. Mattapallil, S.R. Mog, R.A.M. Panganiban, D.L. Bolduc, W.B. Rittase, R.M. Bouten, R.M. Day // Journal of Radiation Research. – 2021. – Vol. 62 – № 2 – P. 236–248.
Sumita, K. Re-irradiation for locoregionally recurrent tumors of the thorax: a single-institution, retrospective study / K. Sumita, H. Harada, H. Asakura, H. Ogawa, T. Onoe, S. Murayama, S. Nakamura, N. Tanigawa, T. Takahashi, T. Nishimura // Radiation Oncology (London, England). – 2016. – Vol. 11 – P. 104.
