Instituto de Medicina Fisica e Reabilitacao, Hospital das Clinicas HCFMUSP, Faculdade de Medicina, Universidade de Sao Paulo, São Paulo, SP, Brasil; Departamento de Medicina Legal, Bioética, Medicina do Trabalho e Medicina Física e Reabilitação, Faculdade de Medicina da Universidade de São Paulo, São Paulo, Brasil.
Instituto de Medicina Fisica e Reabilitacao, Hospital das Clinicas HCFMUSP, Faculdade de Medicina, Universidade de Sao Paulo, São Paulo, SP, Brasil.
Neurophysiol Clin. 2024 Feb;54(1):102939. doi: 10.1016/j.neucli.2023.102939. Epub 2024 Feb 20.
Phantom pain limb (PLP) has gained more attention due to the large number of people with amputations around the world and growing knowledge of the pain process, although its mechanisms are not completely understood.
The aim of this study was to understand, in patients with amputations, the association between PLP and residual limb pain (RLP), and the brain metabolic response in cortical motor circuits, using functional near-infrared spectroscopy (fNIRS).
Sixty participants were recruited from the rehabilitation program in São Paulo, Brazil. Included patients were aged over 18 years, with traumatic unilateral lower-limb amputation, with PLP for at least 3 months after full recovery from amputation surgery. PLP and RLP levels were measured using visual analogue scales. fNIRS was performed during motor execution and motor mirror tasks for 20 s. In order to highlight possible variables related to variation in pain measures, univariate linear regression analyses were performed for both experimental conditions, resulting in four fNIRS variables (two hemispheres x two experimental conditions). Later, in order to test the topographic specificity of the models, eight multivariate regression analyses were performed (two pain scales x two experimental conditions x two hemispheres), including the primary motor cortex (PMC) related channel as an independent variable as well as five other channels related to the premotor area, supplementary area, and somatosensory cortex. All models were controlled for age, sex, ethnicity, and education.
We found that: i) there is an asymmetric metabolic activation during motor execution and mirror task between hemispheres (with a predominance that is ipsilateral to the amputated limb), ii) increased metabolic response in the PMC ipsilateral to the amputation is associated with increased PLP (during both experimental tasks), while increased metabolic response in the contralateral PMC is associated with increased RLP (during the mirror motor task only); ii) increased metabolic activity of the ipsilateral premotor region is associated with increased PLP during the motor mirror task; iii) RLP was only associated with higher metabolic activity in the contralateral PMC and lower metabolic activity in the ipsilateral inferior frontal region during motor mirror task, but PLP was associated with higher metabolic activity during both tasks.
These results suggest there is both task and region specificity for the association between the brain metabolic response and the two different types of post-amputation pain. The metabolic predominance that is ipsilateral to the amputated limb during both tasks was associated with higher levels of PLP, suggesting a cortical motor network activity imbalance due to potential interhemispheric compensatory mechanisms. The present work contributes to the understanding of the underlying topographical patterns in the motor-related circuits associated with pain after amputations.
幻肢痛(PLP)引起了人们的更多关注,这是因为全世界有大量的截肢患者,而且人们对疼痛过程的了解也在不断增加,尽管其机制尚未完全了解。
本研究旨在使用功能近红外光谱(fNIRS)技术,理解截肢患者中 PLP 与残肢痛(RLP)之间的关系,以及皮质运动回路的大脑代谢反应。
从巴西圣保罗的康复计划中招募了 60 名参与者。纳入标准为年龄在 18 岁以上,单侧下肢创伤性截肢,截肢手术后至少 3 个月出现 PLP。使用视觉模拟量表(VAS)测量 PLP 和 RLP 水平。在执行运动和运动镜像任务期间进行 fNIRS 测量,持续 20 秒。为了突出与疼痛测量值变化相关的可能变量,对两种实验条件分别进行了单变量线性回归分析,产生了四个 fNIRS 变量(两个半球 x 两个实验条件)。随后,为了测试模型的地形特异性,进行了 8 个多变量回归分析(两个疼痛量表 x 两个实验条件 x 两个半球),其中包括初级运动皮层(PMC)相关通道作为自变量,以及与运动前区、补充区和体感皮层相关的五个其他通道。所有模型均控制了年龄、性别、种族和教育程度。
我们发现:i)在执行运动和镜像任务时,大脑半球之间存在代谢活动的不对称性(以优势侧偏向于截肢侧);ii)PMC 对侧代谢活动增加与 RLP 增加有关(在两种实验任务中),而 PMC 同侧代谢活动增加与 PLP 增加有关(在两种实验任务中);iii)对侧 PMC 代谢活动增加与运动镜像任务中的 RLP 增加有关,而同侧运动前区代谢活动增加与运动镜像任务中的 PLP 增加有关;iv)PLP 仅与运动镜像任务中对侧 PMC 代谢活动增加和同侧额下回代谢活动减少有关,而 RLP 与两种任务的代谢活动均有关。
这些结果表明,大脑代谢反应与两种不同类型的截肢后疼痛之间存在任务和区域特异性。在两种任务中,对侧肢体的代谢优势与更高水平的 PLP 有关,这表明由于潜在的半球间代偿机制,皮质运动网络活动失衡。本研究有助于理解与截肢后疼痛相关的运动相关回路的基础地形模式。
