1Department of Gastrointestinal Surgery/Clinical Nutrition, Beijing Shijitan Hospital/Capital Medical University Beijing International Science and Technology Cooperation Base for Cancer Metabolism and Nutrition/Department of Oncology, Capital Medical University, Beijing 100038 ,China; 2Traditional Chinese Medicine Department of Beijing Shijitan Hospital, Capital Medical University, Beijing 100038,China; 3School of Nursing, Peking University, Beijing 100191,China
Abstract:Molecular communication is a short-distance communication technology using biochemical molecules as information carriers, which has unique advantages in metabolic disease research. Cell mitochondrial system contains abundant molecular information. Mitochondrial metabolism is also a process of many molecular interactions. Dynamic observation, vivification and visualization of mitochondrial metabolism by using molecular communication technology are of great significance to reveal the mechanism of mitochondrial diseases, diagnosis, prevention and treatment. In this paper, the basic concepts, architecture, the communication process and the transmission mechanism of molecular communication are summarized. The specific applications of molecular communication technology in mitochondrial metabolism research are introduced, such as mitochondrial energy metabolism, mitochondrial calcium concentration, mitochondrial spatial structure and mitochondrial-nuclear retrograde signal detection and analysis of molecular communication technology. The problems and prospects of molecular communication technology in mitochondrial metabolism research are helpful to deepen the understanding of molecular communication science and to understand the progress of molecular communication technology in mitochondrial metabolism research. Molecular communication provides a method of capturing mitochondrial metabolic information from molecular level to individual level. It can gradually realize quantitative detection of mitochondrial metabolism, and make the monitoring of mitochondrial metabolism develop from invasive, abstract to non-invasive, real-time, quantitative and visual. It will play an important role in the research and prevention of mitochondrial diseases.
1杨振鹏,1邓丽,1饶本强,2潘国凤,3靳帅. 分子通信与线粒体代谢研究[J]. 肿瘤代谢与营养电子杂志, 2019, 6(3): 277-282.
1YANG Zhen-peng, 1DENG Li, 1RAO Ben-qiang, 2PAN Guo-feng, 3JIN Shuai. Molecular communication and mitochondrial metabolism. Electron J Metab Nutr Cancer, 2019, 6(3): 277-282.
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