How Researchers study effect of brain irradiation on damage to liver and protective effects of Dragon’s Blood

Beijing Institute of Technology Press Co., Ltd

Radiation is the main source of biological stress in the low Earth orbit (LEO), which is the region encompassed by the Earth’s magnetosphere where all manned missions currently occur. In the upcoming missions to the moon and Mars, deep space radiation is a serious health risk. Low dose of radiation can cause dysfunction in the central nervous system, while larger doses of radiation cause pathological changes in neuronal cells. Moreover, radiation can not only directly cause damage to target organs, but also trigger side effects to affect non-target organs. In recent years, traditional Chinese medicine has been widely used due to its multi component, multi target, low toxicity and high safety characteristics. Dragon’s Blood, a bright red resin extracted from Dracaena cochinchinensis, has been used in China for more than 1500 years and is known as the “Holy Medicine for Promoting Blood” in the Compendium of Materia Medica. This traditional Chinese Dai medicine has been proved to exhibit radioprotective effects. Specifically, it can alleviate brain damage, hematopoietic dysfunction and gastrointestinal damage caused by radiation in rats, but its mechanism of action is not clear yet. In a research paper recently published in Space: Science & Technology, Yulin Deng’s team, from Beijing Key Laboratory for Separation and Analysis in Biomedicine and Pharmaceuticals, conducted a study on the effect of brain irradiation on the damage to liver and the protective effects of Dragon’s Blood (DB). This work could provide insights on the pathways that involved in the brain radiation induced liver damage, as well as guidance that pharmacologists could potentially focused to develop drugs for radio therapy protection.

The author first prepared necessary materials for the study. Dragon’s Blood (voucher specimen number: 20160701), provided by Xishuangbanna Yulin Pharmaceutical Factory (Xishuangbanna, China), was used to make fresh Dragon’s Blood suspension (200 mg/ml) for immediate use. Twenty-four healthy male Wistar rats, purchased from Sibeifu Biotechnology Co., Ltd. (NO. SCXK Jing 2019-0010) were randomly divided into three groups, and circulated light for 12 hours and had free access to food and water. Specifically, Control group (CON) rats were given 10 mL/kg distilled water (containing 0.5% sodium carboxymethyl cellulose) daily to the day of sacrifice. The whole brain irradiated group (RAD) was given 10 mL/kg of distilled water (containing 0.5% sodium carboxymethyl cellulose) daily while Dragon’s Blood administration group (DB) was given 10 mL/kg of 200 mg/mL Dragon’s Blood aqueous suspension daily. After intragastric administration for ten days, the rats were irradiated with Co60γ-ray whole brain in the cobalt source room of Peking University. All the mice were sacrificed on the third day after irradiation, and the rat liver was excised for histomorphological study.

Afterwards, the histological features of the rat liver were determined by H&E to examine the effect of whole brain Co60γ irradiation on liver damage. The cell morphology of the liver was observed under an optical microscope, and the atrophy morphology, hepatocyte necrosis, inflammatory cell infiltration and other pathological conditions of liver slices in each group were counted. The liver lobules of the CON group were clearly structured and the liver cords were neatly arranged. The liver cells were rich in cytoplasm, and the morphology and structure were normal. In the RAD group, hepatocyte necrosis was seen locally, the normal structure disappeared, and the nucleus fragmented and disappeared; accompanied by inflammatory cell infiltration. In contrast, there was no observed hepatocyte necrosis in the DB group. Pathological analysis showed that whole brain Co60γ irradiation did cause rat liver damage. Administration of Dragon’s Blood before irradiation help alleviating the liver damage. The local hepatocyte necrosis, nuclear fragmentation and disappearance caused by radiation can be significantly improved by DB.

Besides, to study the pathology pathways and the protection effect of drugs, the authors used liquid chromatography and mass spectrometer to analyze the total differential protein expression in the rat liver. A total of 4557 proteins were identified in rat liver. A total of 299 co-expressed differential proteins were screened in the RAD/CON group indicating that brain radiation significantly affected the liver’s metabolic system, chemical carcinogenesis, and peroxisomes process. A total of 85 differential proteins were screened in the DB/RAD group. Results indicated that Dragon’s Blood significantly regulated the expression of 26 proteins to normal levels mainly through regulating metabolism and redox homeostasis process. Furthermore, in order to explore the interaction between the phytochemicals in Dragon’s Blood and target proteins, the computer aided drug design platform to molecularly dock each target protein in the Dragon’s Blood compound library with the target protein library was performed. The results of molecular docking and network pharmacology found that the main effective radiation protection components in Dragon’s Blood are natural chalcones, flavan and phenolic derivatives. In summary, Dragon’s Blood can protect the liver of brain irradiated rats to by improving liver necrosis, regulating the level of inflammatory factors and regulating the expression of liver proteins.

Reference

Author: Bo Li, Tianmei Li, Chu Han, Yuanyuan Liu, Xia Zhong, Yanlu Cao, and Yulin Deng

Title of original paper: Potential of Dragon’s Blood as space radiation protectant especially on brain-liver bystander effect

Article link: https://spj.sciencemag.org/journals/space/2022/9791283/

Journal: Space: Science & Technology

DOI: 10.34133/2022/9791283

Affiliations:

Beijing Key Laboratory for Separation and Analysis in Biomedicine and Pharmaceuticals, School of Life Science, Beijing Institute of Technology, Beijing, PR China;

Advanced Research Institute of Multidisciplinary Science, Beijing Institute of Technology, Beijing, 100081, China;

School of Chemistry and Chemical Engineering, Beijing Institute of Technology, Beijing, 100081, China

About the Author

Deng Yulin, a professor from the School of Life Science at BIT. He was honored as academician from International Academy of Astronautics on 2013. His research interests and publication topics include chromatography, molecular biophysics, cellular biophysics, and mass spectroscopic chemical analysis etc.

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