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声音识别区和面部识别区之间的直接结构连接。

Direct structural connections between voice- and face-recognition areas.

机构信息

Max Planck Institute for Human Cognitive and Brain Sciences, 04103 Leipzig, Germany.

出版信息

J Neurosci. 2011 Sep 7;31(36):12906-15. doi: 10.1523/JNEUROSCI.2091-11.2011.

DOI:10.1523/JNEUROSCI.2091-11.2011
PMID:21900569
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6623403/
Abstract

Currently, there are two opposing models for how voice and face information is integrated in the human brain to recognize person identity. The conventional model assumes that voice and face information is only combined at a supramodal stage (Bruce and Young, 1986; Burton et al., 1990; Ellis et al., 1997). An alternative model posits that areas encoding voice and face information also interact directly and that this direct interaction is behaviorally relevant for optimizing person recognition (von Kriegstein et al., 2005; von Kriegstein and Giraud, 2006). To disambiguate between the two different models, we tested for evidence of direct structural connections between voice- and face-processing cortical areas by combining functional and diffusion magnetic resonance imaging. We localized, at the individual subject level, three voice-sensitive areas in anterior, middle, and posterior superior temporal sulcus (STS) and face-sensitive areas in the fusiform gyrus [fusiform face area (FFA)]. Using probabilistic tractography, we show evidence that the FFA is structurally connected with voice-sensitive areas in STS. In particular, our results suggest that the FFA is more strongly connected to middle and anterior than to posterior areas of the voice-sensitive STS. This specific structural connectivity pattern indicates that direct links between face- and voice-recognition areas could be used to optimize human person recognition.

摘要

目前,关于人类大脑如何整合语音和面部信息来识别身份,存在两种对立的模式。传统模型假设语音和面部信息仅在超模态阶段结合(Bruce 和 Young,1986;Burton 等人,1990;Ellis 等人,1997)。另一种模型则假设,编码语音和面部信息的区域也直接相互作用,这种直接相互作用对于优化身份识别具有行为相关性(von Kriegstein 等人,2005;von Kriegstein 和 Giraud,2006)。为了区分这两种不同的模型,我们通过结合功能磁共振成像和弥散磁共振成像来测试语音和面部处理皮质区域之间是否存在直接结构连接的证据。我们在个体受试者水平上定位了三个在前、中、后上颞叶(STS)的语音敏感区域和在梭状回的面部敏感区域[梭状回面部区域(FFA)]。使用概率追踪技术,我们证明了 FFA 与 STS 中的语音敏感区域在结构上是相连的。特别是,我们的结果表明,FFA 与中颞叶和前颞叶的语音敏感区的连接比与后颞叶的连接更强。这种特定的结构连接模式表明,面部识别区和语音识别区之间的直接联系可以用于优化人类身份识别。

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