动物穴位“Telocyte -纠缠复合体”的发现及其超微特征

doi:10.3864/j.issn.0578-1752.2026.11.016

摘要/Abstract

摘要：

【背景】厘定穴位的结构实质是阐明针灸机制的核心前提，然而长期以来，穴位的物质形态尚未完全明确。现有研究认为穴位本质多与神经、循环、免疫或筋膜等已知结构系统相关，但各观点间难以整合兼容。从传统中医理论来看，穴位是人体经络气血输注出入的特殊部位，其与经络的关系密不可分。基于“Telocyte（TC）为潜在经络实质细胞”的新观点，进一步探究穴位区域TC及其相关结构的作用，为厘清穴位的物质基础、揭示针灸作用原理提供新的研究思路。【目的】旨在通过电镜观察，明确穴位区域TC及其细长突起（telopode，Tp）与周围多种结构成分的相互作用，探究是否存在与穴位功能相关的特殊超微结构单元，也为阐释针刺的初始细胞响应提供形态学基础。【方法】以大鼠、小鼠、家兔和湖羊常用穴位为对象，采用超微电镜技术，聚焦穴位区域TC及其Tp，观察其与神经、血管、淋巴管、免疫细胞、肥大细胞、胞外囊泡（包括外泌体）、皮肤衍生物、穴位基质及其纤维等多种成分的空间关系与相互作用。【结果】透射电镜观察发现，穴位区域的TC及其Tp呈现出广泛的连接特征：频繁缠绕或伴行于神经、血管、淋巴管、免疫细胞、肥大细胞、胞外囊泡、皮肤衍生物、穴位基质及其纤维等多种成分，部分Tp甚至伸进结构内部，直接与其他成分接触或连接，形成一种新的结构单元—“Telocyte-纠缠复合体”（TC-entanglement complex，TCEC）。其中，TC既可以与单一成分发生纠缠，也能同时与多种结构成分形成纠缠关系。TC这种广泛的连接特性，可能是中医“整体观”理念的超微证据；此外，TC通过缠绕穴位纤维并形成发达的黏附斑，与穴位基质紧密锚链，表明其是针刺动作最初的联动装置，有利于阐释TC是针刺效应的初始细胞。该结果为TC在穴位组织中的联系与整合作用提供了形态学证据，并得到针灸刺激的初步验证。【结论】系统揭示了穴位区域TC及其Tp与多种结构成分之间的复杂空间联系，发现了一种新的超微结构单元-TCEC，体现了穴位组织的整合特征。研究结果不仅有助于厘清穴位的生物学基础，也为揭示针灸作用原理提供了新的研究视角。

关键词: 穴位, 结构本质, “TC纠缠复合体”, 针灸验证

Abstract:

【Background】Clarification of acupoint essence is a core prerequisite for elucidating the mechanisms of acupuncture, yet the structural form of acupoints has not been fully clarified over the long term. Current research suggests that acupoint essence is related to specific structural systems, such as nerves, circulation, immunity, or fascia; however, these perspectives are not easily integrated. According to traditional Chinese medicine (TCM), acupoints along meridians are special locations of the human body where “qi” and “xue” flow in and out. Based on the novel concept that “Telocyte (TC) is a potential meridian parenchymal cell”, this study further investigated the role of TCs and their associated structures within acupoint regions, so as to provide new experimental evidence for elucidating the material basis of acupoints and revealing the principles underlying acupuncture effects. 【Objective】The aim of this study was to clarify, using electron microscopy, the interactions between TCs and their elongated protrusion (telopode, Tp) within acupoint regions and various surrounding structural components, and to investigate whether specialized ultrastructural units related to acupoint functions exist, thereby providing a morphological foundation for elucidating the initial cellular responses to acupuncture.【Method】The study subjects included commonly used acupoints in rats, mice, rabbits, and sheep. Focusing on the ultrastructure of acupoint regions, this study primarily employed electron microscopy techniques. It examined the spatial relationships and interactions between TCs and their Tp in acupoint regions and various components, including nerves, blood vessels, lymphatic vessels, immune cells, mast cells, extracellular vesicles (including exosomes), skin derivatives, acupoint matrix, and its fibers. 【Result】TEM revealed that TC and its Tp in the acupoint frequently entangled with or accompany various components, such as nerves, blood vessels, lymphatic vessels, immune cells, mast cells, extracellular vesicles(including exosomes), skin derivatives, acupoint matrix, and fibers. Some Tp even extended into the interior of structures, directly contacting or connecting with target components to form new structural units-“Telocyte-entanglement complexes” (TCEC). Notably, TC and its Tps could simultaneously entangle with one or multiple special components, thereby forming distinct morphological units among the TCECs. The extensive connectivity characteristic of TC indicated the ultrafine evidence of the "holistic view" concept in TCM. Furthermore, TC wrapped around fibers and forms developed adhesive spots, anchoring tightly to the matrix within acupoints, which might be conducive to explaining that TC was the initial cell of acupuncture effects. This observation provided the morphological evidence for the connective and integrative functions of TC within acupoint tissues and has been preliminarily validated by acupuncture.【Conclusion】The study systematically revealed the complex spatial relationships between TC and Tp within acupoint regions and various structural components, identifying a neglected ultrastructural unit - TCEC at acupoints. This structure reflected both the integration of local cells and tissues and provided a morphological foundation for understanding the initial cellular-mechanical responses to acupuncture. The findings not only clarified the biological basis of acupoints but also provided a new research perspective at the ultrastructural level for elucidating the mechanisms underlying acupuncture effects.

Key words: acupoint, structural essence, Telocyte-entanglement complex, acupuncture verification

代萌, 梅璐, 陆露, 朱倩美, 白雪兵, 杨童, 张臻玮, 乐建铭, 黄海翔, 杨敏, 陈秋生, 王德云. 动物穴位“Telocyte -纠缠复合体”的发现及其超微特征[J]. 中国农业科学, 2026, 59(11): 2526-2536.

DAI Meng, MEI Lu, LU Lu, ZHU QianMei, BAI XueBing, YANG Tong, ZHANG ZhenWei, YUE JianMing, HUANG HaiXiang, YANG Min, CHEN QiuSheng, WANG DeYun. Discovery of the Animal Acupoint “Telocyte- Entanglement Complex” and Its Ultrastructural Characteristics[J]. Scientia Agricultura Sinica, 2026, 59(11): 2526-2536.

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