Neuroimaging Center (NIC), Focus Program Translational Neuroscience,
Deutsches Resilienz Zentrum (DRZ), Johannes Gutenberg University Medical Center Mainz, 55131 Mainz, Germany.
J Neurosci. 2019 Jul 3;39(27):5326-5335. doi: 10.1523/JNEUROSCI.3128-18.2019. Epub 2019 May 1.
Dopamine dysfunction is associated with a wide range of neuropsychiatric disorders commonly treated pharmacologically or invasively. Recent studies provide evidence for a nonpharmacological and noninvasive alternative that allows similar manipulation of the dopaminergic system: transcranial direct current stimulation (tDCS). In rodents, tDCS has been shown to increase neural activity in subcortical parts of the dopaminergic system, and recent studies in humans provide evidence that tDCS over prefrontal regions induces striatal dopamine release and affects reward-related behavior. Based on these findings, we used fMRI in healthy human participants and measured the fractional amplitude of low-frequency fluctuations to assess spontaneous neural activity strength in regions of the mesostriatal dopamine system before and after tDCS over prefrontal regions ( = 40, 22 females). In a second study, we examined the effect of a single dose of the dopamine precursor levodopa (l-DOPA) on mesostriatal fractional amplitude of low-frequency fluctuation values in male humans ( = 22) and compared the results between both studies. We found that prefrontal tDCS and l-DOPA both enhance neural activity in core regions of the dopaminergic system and show similar subcortical activation patterns. We furthermore assessed the spatial similarity of whole-brain statistical parametric maps, indicating tDCS- and l-DOPA-induced activation, and >100 neuronal receptor gene expression maps based on transcriptional data from the Allen Institute for Brain Science. In line with a specific activation of the dopaminergic system, we found that both interventions predominantly activated regions with high expression levels of the dopamine receptors D2 and D3. Studies in animals and humans provide evidence that transcranial direct current stimulation (tDCS) allows a manipulation of the dopaminergic system. Based on these findings, we used fMRI to assess changes in spontaneous neural activity strength in the human dopaminergic system after prefrontal tDCS compared with the administration of the dopamine precursor and standard anti-Parkinson drug levodopa (l-DOPA). We found that prefrontal tDCS and l-DOPA both enhance neural activity in core regions of the dopaminergic system and show similar subcortical activation patterns. Using whole-brain transcriptional data of >100 neuronal receptor genes, we found that both interventions specifically activated regions with high expression levels of the dopamine receptors D2 and D3.
多巴胺功能障碍与广泛的神经精神疾病有关,这些疾病通常通过药理学或侵入性治疗。最近的研究为一种非药理学和非侵入性的替代方法提供了证据,该方法允许对多巴胺系统进行类似的操作:经颅直流电刺激(tDCS)。在啮齿动物中,tDCS 已被证明可以增加多巴胺系统下皮质部分的神经活动,最近在人类中的研究提供了证据,表明 tDCS 在前额区域上诱导纹状体多巴胺释放并影响与奖励相关的行为。基于这些发现,我们在健康的人类参与者中使用 fMRI 测量了前额区域 tDCS 前后中脑多巴胺系统区域的低频波动幅度分数,以评估自发神经活动强度(n = 40,22 名女性)。在第二项研究中,我们检查了单剂量多巴胺前体左旋多巴(l-DOPA)对男性人类中中脑多巴胺系统低频波动幅度分数的影响(n = 22),并比较了两项研究的结果。我们发现,前额 tDCS 和 l-DOPA 均增强了多巴胺系统核心区域的神经活动,并显示出类似的皮质下激活模式。我们还评估了全脑统计参数图的空间相似性,这些图指示 tDCS 和 l-DOPA 诱导的激活,以及基于艾伦脑科学研究所的转录数据的> 100 个神经元受体基因表达图谱。与多巴胺系统的特异性激活一致,我们发现这两种干预措施主要激活了多巴胺受体 D2 和 D3 表达水平高的区域。动物和人类的研究提供了证据,证明经颅直流电刺激(tDCS)允许对多巴胺系统进行操作。基于这些发现,我们使用 fMRI 来评估前额 tDCS 后与多巴胺前体和标准抗帕金森药物左旋多巴(l-DOPA)给药相比,人类多巴胺系统中自发神经活动强度的变化。我们发现,前额 tDCS 和 l-DOPA 均增强了多巴胺系统核心区域的神经活动,并显示出类似的皮质下激活模式。使用> 100 个神经元受体基因的全脑转录数据,我们发现这两种干预措施均特异性地激活了多巴胺受体 D2 和 D3 表达水平高的区域。