Journal of Peking University(Health Sciences) ›› 2019, Vol. 51 ›› Issue (3): 397-401. doi: 10.19723/j.issn.1671-167X.2019.03.004

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Discovery of a new division system in brain and the regionalized drainage route of brain interstitial fluid

Hong-bin HAN()   

  1. Beijing Key Laboratory of Magnetic Resonance Imaging Equipment and Technique, Beijing 100191, China
  • Received:2019-04-03 Online:2019-06-18 Published:2019-06-26
  • Supported by:
    Supported by the Beijing Brain Initiative of Beijing Municipal Science & Technology Commission Z181100001518004, National Science Fund for Distinguished Young Scholars 61625102, Program for Training Capital Science and Technology Leading Talents Z181100006318003, National Major Scientific Research Instrument Development Project 61827808, the Fundamental Research Funds for the Central Universities: Peking University Clinical Scientist Program BMU2019LCKXJ007

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Abstract:

SUMMARY Brain extracellular space (ECS) is a narrow, irregular space, which provides immediate living environment for neural cells and accounts for approximately 15%-20% of the total volume of living brain. Twenty-five years ago, as an interventional radiologist, the author was engaged in investigating early diagnosis and treatment of cerebral ischemic stroke, and the parameters of brain ECS was firstly derived and demonstrated during the study of the permeability of blood-brain barrier (BBB) and its diffusion changes in the cerebral ischemic tissue. Since then, the author and his team had been working on developing a novel measuring method of ECS: tracer-based magnetic resonance imaging (MRI), which could measure brain ECS parameters in the whole brain scale and make the dynamic drainage process of the labelled brain interstitial fluid (ISF) visualized. By using the new method, the team made a series of new findings about the brain ECS and ISF, including the discovery of a new division system in the brain, named regionalized ISF drainage system. We found that the ISF drainage in the deep brain was regiona-lized and the structural and functional parameters in different interstitial system (ISS) divisions were disparate. The ISF in the caudate nucleus could be drained to ipsilateral cortex and finally into the subarachnoid space, which maintained the pathway of ISF- cerebrospinal fluid (CSF) exchange. However, the ISF in the thalamus was eliminated locally in its anatomical division. After verifying the nature of the barrier structure between different drainage divisions, the author proposed the hypothesis of “regionalized brain homeostasis”. Thus, we demonstrated that the brain was protected not only by the BBB, which avoided potential exogenous damage through the vascular system, but was also protected by an internal ISF drainage barrier to avoid potentially harmful interference from other ECS divisions in the deep brain. With the new findings and the proposed hypothesis, an innovative therapeutic method for the treatment of encephalopathy with local drug delivery via the brain ECS pathway was esta-blished. By using this new administration method, the drug was achieved directly to the space around neurons or target regions, overwhelming the impendence from the blood-brain barrier, thus solved the obstacles of low efficiency in traditional drug investigation. At present, new methods and discoveries developed by the author and his team have been widely applied in several frontier fields including neuroscience, new drug research and development, neurodevelopment aerospace medicine, clinical encephalopathy treatment,new neural network modeling and so on.

Key words: Key Words: Extracellular space, Tracer-based magnetic resonance imaging method, Brain interstitial fluid, Regionalized brain homeostasis

CLC Number: 

  • R817.4

Figure 1

History of exploring the brain extracellular space During 1993-2003, when studying the early diagnosis of cerebral ischemic stroke and the quantitative analysis of the blood brain barrier permeability, a parameter of extracellular space was derived from the raw data of permeability of blood brain barrier. Dr. Han realized that the brain extracellular space is an unknown space to neuroscience and decided to explore the space since then. In 2004, Dr. Han proposed and established a novel method of measuring the brain extracellular space, magnetic resonance tracer based method to detect brain extracellular space, the measuring system was finally finished and got patented in 2013. In 2015, by using the newly developed method, Dr. Han and his group discovered that a new division system in the brain: the brain interstitial fluid drains in a regionalized extracellular space system. Based on the above findings, Dr. Han and his fellows designed and developed a new drug delivery method, by which the drug was delivered via brain extracellular space and bypass the obstacle of the blood-brain barrier as it does with the routine oral or intravenous administration. In 2017, the barrier structure to impede the brain interstitial fluid drainage was identified as the compact fiber fascicles in the deep brain, and a new hypothesis of local brain homeostasis within each extracellular space divisions was therefore proposed and published the cover story in the journal of Progress in Neurobiology. In pre-sent, new method and discoveries have been applied in several frontier fields such as neuroscience, pharmacy, aerospace, artificial intelligence, as well as tumor therapy."

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