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啮齿动物胫骨骨折模型:一项关键评估及与复杂性区域疼痛综合征文献的比较。

The Rodent Tibia Fracture Model: A Critical Review and Comparison With the Complex Regional Pain Syndrome Literature.

机构信息

University Medical Center of the Johannes Gutenberg University Mainz, Department of Neurology, Mainz, Germany.

Palo Alto Veterans Institute for Research, Veterans Affairs Palo Alto Health Care System, Palo Alto, California.

出版信息

J Pain. 2018 Oct;19(10):1102.e1-1102.e19. doi: 10.1016/j.jpain.2018.03.018. Epub 2018 Apr 21.

DOI:10.1016/j.jpain.2018.03.018
PMID:29684510
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6163066/
Abstract

UNLABELLED

Distal limb fracture is the most common cause of complex regional pain syndrome (CRPS), thus the rodent tibia fracture model (TFM) was developed to study CRPS pathogenesis. This comprehensive review summarizes the published TFM research and compares these experimental results with the CRPS literature. The TFM generated spontaneous and evoked pain behaviors, inflammatory symptoms (edema, warmth), and trophic changes (skin thickening, osteoporosis) resembling symptoms in early CRPS. Neuropeptides, inflammatory cytokines, and nerve growth factor (NGF) have been linked to pain behaviors, inflammation, and trophic changes in the TFM model and proliferating keratinocytes were identified as the primary source of cutaneous cytokines and NGF. Tibia fracture also activated spinal glia and upregulated spinal neuropeptide, cytokine, and NGF expression, and in the brain it changed dendritic architecture. B cell-expressed immunoglobulin M antibodies also contributed to pain behavior, indicating a role for adaptive immunity. These results modeled many findings in early CRPS, but significant differences were also noted.

PERSPECTIVE

Multiple neuroimmune signaling mechanisms contribute to the pain, inflammation, and trophic changes observed in the injured limb of the rodent TFM. This model replicates many of the symptoms, signs, and pathophysiology of early CRPS, but most post-fracture changes resolve within 5 months and may not contribute to perpetuating chronic CRPS.

摘要

非标记

四肢骨折是复杂性区域疼痛综合征(CRPS)最常见的原因,因此开发了啮齿动物胫骨骨折模型(TFM)来研究 CRPS 的发病机制。本综述总结了已发表的 TFM 研究,并将这些实验结果与 CRPS 文献进行了比较。TFM 产生自发性和诱发性疼痛行为、炎症症状(水肿、发热)和营养变化(皮肤增厚、骨质疏松),类似于早期 CRPS 的症状。神经肽、炎症细胞因子和神经生长因子(NGF)与 TFM 模型中的疼痛行为、炎症和营养变化有关,并且增殖的角质形成细胞被鉴定为皮肤细胞因子和 NGF 的主要来源。胫骨骨折还激活了脊髓胶质细胞,上调了脊髓神经肽、细胞因子和 NGF 的表达,并且在大脑中改变了树突形态。B 细胞表达的免疫球蛋白 M 抗体也有助于疼痛行为,表明适应性免疫的作用。这些结果模拟了早期 CRPS 的许多发现,但也注意到了明显的差异。

观点

多种神经免疫信号机制导致啮齿动物 TFM 受伤肢体中观察到的疼痛、炎症和营养变化。该模型复制了早期 CRPS 的许多症状、体征和病理生理学,但大多数骨折后变化在 5 个月内解决,并且可能不会导致慢性 CRPS 持续存在。

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