The recent research progress in neurobiological characteristics and pain regulation of the cerebrospinal fluid-contacting nucleus

The ependymal epithelium forms the cerebrospinal fluid barrier, separating the brain and spinal cord from the cerebrospinal fluid. However, in specific regions of the central nervous system, there are neurons that directly interface with the cerebrospinal fluid, including neuronal bodies, dendrites, or axons, This constitutes what is referred to as the "cerebrospinal fluid contacting neurons system (CSF-CNS)". The research team led by Professor Zhang has successfully utilized cholera toxin subunit B coupled horseradish peroxidase complex (CB-HRP) to selectively label the specialized neuron system that interfaces with cerebrospinal fluid, pioneeringly designating it as the "cerebrospinal fluid-contacting nucleus", commonly referred to as the "CSF-contacting nucleus". For the first time, the discovery of the CSF-contacting nucleus provides compelling morphological evidence for the existence of a distinct neural structure within the brain parenchyma that establishes a connection with the cerebrospinal fluid, thereby suggesting its potential significance in facilitating material and information exchange between the brain parenchyma and cerebrospinal fluid. After conducting a comprehensive series of studies on the morphological structure, material expression, gene analysis and functional aspects of the CSF-contacting nucleus in rodents and non-human primates, it has been revealed that there are fibrous connections between the CSF-contacting nucleus and the cerebral cortex and subcortical nuclei being involved in the regulatory mechanisms of pain, cognition, learning and memory, emotion, addiction, stress and anxiety responses, visceral activity, olfaction, vision processing and perception, auditory processing, perception, motor control and coordination, homeostasis regulation including maintenance of body energy and fluid balance, as well as the control of sleep–wake cycles and synchronization of biological rhythms. Current experiments have confirmed that the CSF-contacting nucleus is related to pain, morphine dependence and withdrawal, learning and memory, as well as stress. This present article offers a comprehensive review of the neurobiological characteristics and recent advancements in pain regulation of the CSF-contacting nucleus. The aim is to provide novel insights into the investigation of pain regulation within bidirectional regulatory pathway between the brain and cerebrospinal fluid, with a specific focus on elucidating the role of the CSF-contacting nucleus as a bridge structure. Additionally, the objective of this research is to propose innovative strategies for pain management and associated disorders in the future.