Department of Cognitive Neuroscience, Faculty of Psychology, Maastricht University, The Netherlands.
Hum Brain Mapp. 2013 May;34(5):1148-62. doi: 10.1002/hbm.21500. Epub 2012 Jan 16.
Fine surface texture is best discriminated by touch, in contrast to macro geometric features like shape. We used functional magnetic resonance imaging and a delayed match-to-sample task to investigate the neural substrate for working memory of tactile surface texture. Blindfolded right-handed males encoded the texture or location of up to four sandpaper stimuli using the dominant or non-dominant hand. They maintained the information for 10-12 s and then answered whether a probe stimulus matched the memory array. Analyses of variance with the factors Hand, Task, and Load were performed on the estimated percent signal change for the encoding and delay phase. During encoding, contralateral effects of Hand were found in sensorimotor regions, whereas Load effects were observed in bilateral postcentral sulcus (BA2), secondary somatosensory cortex (S2), pre-SMA, dorsolateral prefrontal cortex (dlPFC), and superior parietal lobule (SPL). During encoding and delay, Task effects (texture > location) were found in central sulcus, S2, pre-SMA, dlPFC, and SPL. The Task and Load effects found in hand- and modality-specific regions BA2 and S2 indicate involvement of these regions in the tactile encoding and maintenance of fine surface textures. Similar effects in hand- and modality-unspecific areas dlPFC, pre-SMA and SPL suggest that these regions contribute to the cognitive monitoring required to encode and maintain multiple items. Our findings stress both the particular importance of S2 for the encoding and maintenance of tactile surface texture, as well as the supramodal nature of parieto-frontal networks involved in cognitive control.
精细的表面纹理最好通过触摸来区分,与形状等宏观几何特征形成对比。我们使用功能磁共振成像和延迟匹配样本任务来研究触觉表面纹理工作记忆的神经基础。 右利手的男性被试蒙上眼睛,使用优势手或非优势手对多达四个砂纸刺激进行纹理或位置编码。他们将信息保持 10-12 秒,然后回答探针刺激是否与记忆数组匹配。对编码和延迟阶段的估计信号变化百分比进行了具有 Hand、Task 和 Load 因素的方差分析。在编码期间,手的对侧效应在感觉运动区域中发现,而负载效应在双侧中央后沟(BA2)、次级体感皮层(S2)、前运动皮层(pre-SMA)、背外侧前额叶皮层(dlPFC)和顶下小叶(SPL)中观察到。在编码和延迟期间,任务效应(纹理>位置)在中央沟、S2、pre-SMA、dlPFC 和 SPL 中发现。在 BA2 和 S2 中手和模态特异性区域以及任务和负载效应的发现表明这些区域参与了精细表面纹理的触觉编码和保持。dlPFC、pre-SMA 和 SPL 中手和模态非特异性区域的相似效应表明,这些区域有助于编码和保持多个项目所需的认知监测。我们的发现强调了 S2 对触觉表面纹理的编码和保持的特殊重要性,以及参与认知控制的顶叶-额叶网络的超模态性质。
