Prevention of neurodegenerative damage to the brain in rats in experimental Alzheimer's disease by adaptation to hypoxia

被引：37

作者：

Manukhina E.B. ^{[1
]}

Goryacheva A.V. ^{[1
]}

Barskov I.V. ^{[2
]}

Viktorov I.V. ^{[2
]}

Guseva A.A.

Pshennikova M.G. ^{[1
]}

Khomenko I.P. ^{[1
]}

Mashina S.Yu. ^{[1
]}

Pokidyshev D.A. ^{[1
]}

Malyshev I.Yu. ^{[1
]}

机构：

[1] State Research Institute of General Pathology and Pathophysiology, Russian Academy of Medical Sciences, Moscow 125315

[2] Faculty of Biology, Lomonosov Moscow State University, Moscow

来源：

Neuroscience and Behavioral Physiology | 2010年 / 40卷 / 7期

基金：

俄罗斯基础研究基金会;

关键词：

adaptation to hypoxia; Alzheimer's disease; beta-amyloid; brain neurons; nitric oxide; oxidative stress;

D O I：

10.1007/s11055-010-9320-6

中图分类号：

学科分类号：

摘要：

We report here studies addressing the possibility of preventing neurodegenerative changes in the brain using adaptation to periodic hypoxia in rats with experimental Alzheimer's disease induced by administration of the neurotoxic peptide fragment of β-amyloid (Ab) into the basal magnocellular nucleus. Adaptation to periodic hypoxia was performed in a barochamber (4000 m, 4 h per day, 14 days). The following results were obtained 15 days after administration of Ab. 1. Adaptation to periodic hypoxia significantly blocked Ab-induced memory degradation in rats, as assessed by testing a conditioned passive avoidance reflex. 2. Adaptation to periodic hypoxia significantly restricted increases in oxidative stress, measured spectrophotometrically in the hippocampus in terms of the content of thiobarbituric acid-reactive secondary lipid peroxidation products. 3. Adaptation to periodic hypoxia completely prevented the overproduction of NO in the brains of rats with experimental Alzheimer's disease, as measured in terms of increases in tissue levels of stable NO metabolites, i.e., nitrites and nitrates. 4. The cerebral cortex of rats given Ab injections after adaptation to periodic hypoxia did not contain neurons with pathomorphological changes or dead neurons (Nissl staining), which were typical in animals with experimental Alzheimer's disease. Thus, adaptation to periodic hypoxia effectively prevented oxidative and nitrosative stress, protecting against neurodegenerative changes and protecting cognitive functions in experimental Alzheimer's disease. © 2010 Springer Science+Business Media, Inc.

引用

页码：737 / 743

页数：6

共 44 条

[1]

Bachurin S.O., Medical chemistry of the targeted search for agents for the treatment and prevention of neurodegenerative diseases using Alzheimer's disease as an example, Neurodegenerative Diseases and Aging, pp. 399-454, (2001)

[2]

Vanin A.F., Dinitrosyl complexes of iron and S-nitrosothiols - Two possible forms of stabilization and transport of nitric oxide in biological systems, Biokhimiya, 63, 7, pp. 924-938, (1998)

[3]

Elchaninova S.A., Korenyak N.A., Smagina I.V., Pinegin L.E., Ya B., Varshavskii, "discontinuous hypoxia in the treatment of chronic cerebral ischemia, Zh. Nevrol. Psikhiat. Im. S. S. Korsakova, 102, pp. 29-32, (2002)

[4]

Krushinskii A.L., Reutov V.P., Kuzenkov V.S., Sorokina E.G., Koshelev V.B., Fadyukova O.E., Baider L.M., Kuropteva Z.V., Zhumabaeva T.T., Lkh K., Ryasina T.V., Kositsyn N.S., Pinelis V.G., Nitric oxide is involved in the mechanisms of short-term adaptation to hypoxia and protective actions during the development of stress lesions in Krushinskii-Molodkina rats, Izv. Ros. Akad. Nauk. Ser. Biol., 34, 3, pp. 329-335, (2007)

[5]

Kulinskii V.I., Minakina L.N., Gavrilina T.V., Neuroprotective effects of hypoxic preconditioning: The phenomenon and its mechanisms, Byull. Eksperim. Biol. Med., 133, 2, pp. 237-239, (2002)

[6]

Manukhina E.B., Viegant F., Torshin V.I., Goryacheva A.V., Khomenko I.P., Kruglov S.V., Syu M., Pokidyshev D.A., Popova E.V., Pshennikova M.G., Vlasova M.A., Zelenina O.M., Iyu M., Potential non-medication-based approaches to Alzheimer's disease, Izv. Ros. Akad. Nauk. Ser. Biol., 31, 4, pp. 382-395, (2004)

[7]

Manukhina E.B., Iyu M., The stress-limiting nitric oxide system, Ros. Fiziol. Zh. Im. I. M. Sechenova, 86, 10, pp. 1283-1292, (2000)

[8]

Manukhina E.B., Smirin B.V., Iyu M., Zh-K S., Muller B., Solodkov A.P., Shebeko V.I., Vanin A.F., Deposition of nitric oxide in the cardiovascular system, Izv. Akad. Nauk. Ser. Biol., 29, 5, pp. 585-596, (2002)

[9]

Syu M., Aleksandrov V.V., Goryacheva A.V., Vlasova M.A., Vanin A.F., Iyu M., Manukhina E.B., Adaptation to hypoxia prevents impairments of cerebral circulation in neurodegenerative damage: The role of nitric oxide, Byull. Eksperim. Biol. Med., 142, 8, pp. 132-135, (2006)

[10]

Meerson F.Z., Adaptation Medicine: Mechanisms and Protective Effects of Adaptation, (1993)

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