Laser Ablation-Generated Crystalline Selenium Nanoparticles Prevent Damage of DNA and Proteins Induced by Reactive Oxygen Species and Protect Mice against Injuries Caused by Radiation-Induced Oxidative Stress.
Sergey V GudkovMeng GaoAlexander V SimakinAlexey S BaryshevRoman V PobedonostsevIlya V BaimlerMaksim B RebezovRuslan M SarimovMaxim E AstashevAnastasia O DikovskayaElena A MolkovaValeriy A KozlovNikolay F BunkinMikhail A SevostyanovAlexey G KolmakovMikhail A KaplanVictor P KutyshenkoVladimir E IvanovVadim I BruskovValery P KalinichenkoKuder O AiyyzhyValery V VoronovNuttaporn PimphaRuibin LiGeorgy A ShafeevPublished in: Materials (Basel, Switzerland) (2023)
With the help of laser ablation, a technology for obtaining nanosized crystalline selenium particles (SeNPs) has been created. The SeNPs do not exhibit significant toxic properties, in contrast to molecular selenium compounds. The administration of SeNPs can significantly increase the viabilities of SH-SY5Y and PCMF cells after radiation exposure. The introduction of such nanoparticles into the animal body protects proteins and DNA from radiation-induced damage. The number of chromosomal breaks and oxidized proteins decreases in irradiated mice treated with SeNPs. Using hematological tests, it was found that a decrease in radiation-induced leukopenia and thrombocytopenia is observed when selenium nanoparticles are injected into mice before exposure to ionizing radiation. The administration of SeNPs to animals 5 h before radiation exposure in sublethal and lethal doses significantly increases their survival rate. The modification dose factor for animal survival was 1.2. It has been shown that the introduction of selenium nanoparticles significantly normalizes gene expression in the cells of the red bone marrow of mice after exposure to ionizing radiation. Thus, it has been demonstrated that SeNPs are a new gene-protective and radioprotective agent that can significantly reduce the harmful effects of ionizing radiation.
Keyphrases
- radiation induced
- radiation therapy
- oxidative stress
- induced apoptosis
- high fat diet induced
- gene expression
- bone marrow
- reactive oxygen species
- cell cycle arrest
- dna methylation
- copy number
- magnetic resonance imaging
- endoplasmic reticulum stress
- mesenchymal stem cells
- dna damage
- signaling pathway
- wild type
- type diabetes
- insulin resistance
- adipose tissue
- walled carbon nanotubes
- skeletal muscle
- genome wide
- transcription factor
- pi k akt
- high speed
- cell proliferation
- radiofrequency ablation
- newly diagnosed