早期盲人的中枕叶回中空间处理功能的保留与专业化。
Preserved functional specialization for spatial processing in the middle occipital gyrus of the early blind.
机构信息
Department of Physiology and Biophysics, Georgetown University Medical Center, Washington, DC 20007, USA.
出版信息
Neuron. 2010 Oct 6;68(1):138-48. doi: 10.1016/j.neuron.2010.09.021.
Abstract
The occipital cortex (OC) of early-blind humans is activated during various nonvisual perceptual and cognitive tasks, but little is known about its modular organization. Using functional MRI we tested whether processing of auditory versus tactile and spatial versus nonspatial information was dissociated in the OC of the early blind. No modality-specific OC activation was observed. However, the right middle occipital gyrus (MOG) showed a preference for spatial over nonspatial processing of both auditory and tactile stimuli. Furthermore, MOG activity was correlated with accuracy of individual sound localization performance. In sighted controls, most of extrastriate OC, including the MOG, was deactivated during auditory and tactile conditions, but the right MOG was more activated during spatial than nonspatial visual tasks. Thus, although the sensory modalities driving the neurons in the reorganized OC of blind individuals are altered, the functional specialization of extrastriate cortex is retained regardless of visual experience.
摘要
早期失明者的枕叶皮层(OC)在各种非视觉感知和认知任务中被激活,但对于其模块化组织知之甚少。使用功能磁共振成像,我们测试了早期盲人的 OC 中听觉与触觉以及空间与非空间信息的处理是否存在分离。没有观察到特定于模态的 OC 激活。然而,右中枕叶回(MOG)显示出对听觉和触觉刺激的空间处理比对非空间处理的偏好。此外,MOG 的活动与个体声音定位性能的准确性相关。在视力正常的对照组中,包括 MOG 在内的大部分外侧枕叶在听觉和触觉条件下失活,但在空间视觉任务中比非空间视觉任务中更活跃。因此,尽管驱动盲人重组 OC 神经元的感觉模态发生了变化,但无论视觉经验如何,外侧皮质的功能专业化仍然保留。
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