Your search keyword '"Qingyuan He"' showing total 3 results

1. Epidural Pulsation Accelerates the Drainage of Brain Interstitial Fluid.

Author

Xianjie Cai, Qingyuan He, Wei Wang, Chunlin Li, Hui Wang, Feng Yin, Tong Li, Dongsheng Kong, Yanxing Jia, Hongfeng Li, Junhao Yan, Xunbin Wei, Qiushi Ren, Yajuan Gao, Shuangfeng Yang, Huaiyu Tong, Yun Peng, and Hongbin Han

Subjects

*EXTRACELLULAR space, *BRAIN disease treatment, *EXTRACELLULAR fluid

Abstract

Unhindered transportation of substances in the brain extracellular space (ECS) is essential for maintaining brain function. Regulation of transportation is a novel strategy for treating ECS blockage-related brain diseases, but few techniques have been developed to date. In this study, we established a novel approach for accelerating the drainage of brain interstitial fluid (ISF) in the ECS using minimally invasive surgery, in which a branch of the external carotid artery is separated and implanted epidurally (i.e., epidural arterial implantation [EAI]) to promote a pulsation effect on cerebrospinal fluid (CSF) in the frontoparietal region. Tracer-based magnetic resonance imaging was used to evaluate the changes in ISF drainage in rats 7 and 15 days post-EAI. The drainage of the traced ISF from the caudate nucleus to ipsilateral cortex was significantly accelerated by EAI. Significant increases in the volume fraction of the ECS and molecular diffusion rate were demonstrated using the DECS-mapping technique, which may account for the mechanisms underlying the changes in brain ISF. This study provides a novel perspective for encephalopathy treatment via the brain ECS. [ABSTRACT FROM AUTHOR]

Published

2023

2. The Alteration of Brain Interstitial Fluid Drainage with Myelination Development.

Author

Rui Wang, Hongbin Han, Kuangyu Shi, Alberts, Ian Leigh, Rominger, Axel, Chenlong Yang, Junhao Yan, Dehua Cui, Yun Peng, Qingyuan He, Yajuan Gao, Jingge Lian, Shuangfeng Yang, Huipo Liu, Jun Yang, Chaolan Wong, Xunbin Wei, Feng Yin, Yanxing Jia, and Huaiyu Tong

Subjects

EXTRACELLULAR fluid, MYELINATION, NEURAL development

Abstract

The integrity of myelination is crucial for maintaining brain interstitial fluid (ISF) drainage in adults; however, the mechanism of ISF drainage with immature myelin in the developing brain remains unknown. In the present study, the ISF drainage from the caudate nucleus (Cn) to the ipsilateral cortex was studied at different developmental stages of the rat brain (P 10, 20, 30, 40, 60, 80, 10-80). The results show that the traced ISF drained to the cortex from Cn and to the thalamus in an opposite direction before P30. From P40, we found impeded drainage to the thalamus due to myelin maturation. This altered drainage was accompanied by enhanced cognitive and social functions, which were consistent with those in the adult rats. A significant difference in diffusion parameters was also demonstrated between the extracellular space (ECS) before and after P30. The present study revealed the alteration of ISF drainage regulated by myelin at different stages during development, indicating that a regional ISF homeostasis may be essential for mature psychological and cognitive functions. [ABSTRACT FROM AUTHOR]

Published

2021

3. The Drainage of Interstitial Fluid in the Deep Brain is Controlled by the Integrity of Myelination.

Author

Aibo Wang, Rui Wang, Dehua Cui, Xinrui Huang, Lan Yuan, Huipo Liu, Yu Fu, Lei Liang, Wei Wang, Qingyuan He, Chunyan Shi, Xiangping Guan, Ze Teng, Guomei Zhao, Yuanyuan Li, Yajuan Gao, and Hongbin Han

Subjects

EXTRACELLULAR fluid, MYELINATION, DEEP brain stimulation, CAUDATE nucleus

Abstract

In searching for the drainage route of the interstitial fluid (ISF) in the deep brain, we discovered a regionalized ISF drainage system as well as a new function of myelin in regulating the drainage. The traced ISF from the caudate nucleus drained to the ipsilateral cortex along myelin fiber tracts, while in the opposite direction, its movement to the adjacent thalamus was completely impeded by a barrier structure, which was identified as the converged, compact myelin fascicle. The regulating and the barrier effects of myelin were unchanged in AQP4-knockout rats but were impaired as the integrity of boundary structure of drainage system was destroyed in a demyelinated rat model. We thus proposed that the brain homeostasis was maintained within each ISF drainage division locally, rather than across the brain as a whole. A new brain division system and a new pathogenic mechanism of demyelination are therefore proposed. [ABSTRACT FROM AUTHOR]

Published

2019