Queensland Brain Institute, The University of Queensland, St Lucia, Queensland 4072, Australia.
QIMR Berghofer Medical Research Institute, Herston, Queensland 4006, Australia.
eNeuro. 2018 Jan 19;5(1). doi: 10.1523/ENEURO.0294-17.2018. eCollection 2018 Jan-Feb.
We often perceive real-life objects as multisensory cues through space and time. A key challenge for audiovisual integration is to match neural signals that not only originate from different sensory modalities but also that typically reach the observer at slightly different times. In humans, complex, unpredictable audiovisual streams lead to higher levels of perceptual coherence than predictable, rhythmic streams. In addition, perceptual coherence for complex signals seems less affected by increased asynchrony between visual and auditory modalities than for simple signals. Here, we used functional magnetic resonance imaging to determine the human neural correlates of audiovisual signals with different levels of temporal complexity and synchrony. Our study demonstrated that greater perceptual asynchrony and lower signal complexity impaired performance in an audiovisual coherence-matching task. Differences in asynchrony and complexity were also underpinned by a partially different set of brain regions. In particular, our results suggest that, while regions in the dorsolateral prefrontal cortex (DLPFC) were modulated by differences in memory load due to stimulus asynchrony, areas traditionally thought to be involved in speech production and recognition, such as the inferior frontal and superior temporal cortex, were modulated by the temporal complexity of the audiovisual signals. Our results, therefore, indicate specific processing roles for different subregions of the fronto-temporal cortex during audiovisual coherence detection.
我们经常通过时间和空间感知到真实物体的多感觉线索。视听整合的一个关键挑战是匹配不仅源自不同感觉模态,而且通常以略微不同的时间到达观察者的神经信号。在人类中,复杂的、不可预测的视听流比可预测的、有节奏的流产生更高的知觉连贯性。此外,对于复杂信号,知觉连贯性似乎不太受视觉和听觉模态之间增加的异步性的影响,而对于简单信号则受影响较大。在这里,我们使用功能磁共振成像来确定具有不同时间复杂度和同步性的视听信号的人类神经相关性。我们的研究表明,更大的感知异步性和更低的信号复杂性会损害视听一致性匹配任务的表现。异步性和复杂性的差异也由一组不完全相同的大脑区域支持。特别是,我们的结果表明,虽然背外侧前额叶皮层 (DLPFC) 中的区域因刺激异步引起的记忆负荷差异而受到调节,但传统上被认为参与言语产生和识别的区域,如额下回和颞上回,也受到视听信号时间复杂度的调节。因此,我们的结果表明,在视听一致性检测过程中,额颞皮质的不同子区域具有特定的处理作用。
