{"title":"对自然物体的感知和神经反应进行数据驱动分析,揭示人类视觉认知的组织原则。","authors":"David M Watson, Timothy J Andrews","doi":"10.1523/JNEUROSCI.1318-24.2024","DOIUrl":null,"url":null,"abstract":"<p><p>A key challenge in understanding the functional organisation of visual cortex stems from the fact that only a small proportion of the objects experienced during natural viewing can be presented in a typical experiment. This constraint often leads to experimental designs that compare responses to objects from experimenter-defined stimulus conditions, potentially limiting the interpretation of the data. To overcome this issue, we used images from the THINGS initiative, which provides a systematic sampling of natural objects. A data-driven analysis was then applied to reveal the functional organisation of the visual brain, incorporating both perceptual and neural responses to these objects. Perceptual properties of the objects were taken from an analysis of similarity judgements, and neural properties were taken from whole brain fMRI responses to the same objects. Partial least squares regression (PLSR) was then used to predict neural responses across the brain from the perceptual properties while simultaneously applying dimensionality reduction. The PLSR model accurately predicted neural responses across visual cortex using only a small number of components. These components revealed smooth, graded neural topographies, which were similar in both hemispheres, and captured a variety of object properties including animacy, real-world size, and object category. However, they did not accord in any simple way with previous theoretical perspectives on object perception. Instead, our findings suggest that visual cortex encodes information in a statistically efficient manner, reflecting natural variability among objects.<b>Significance statement</b> The ability to recognise objects is fundamental to how we interact with our environment, yet the organising principles underlying neural representations of visual objects remain contentious. In this study, we sought to address this question by analysing perceptual and neural responses to a large, unbiased sample of objects. Using a data-driven approach, we leveraged perceptual properties of objects to predict neural responses using a small number of components. This model predicted neural responses with a high degree of accuracy across visual cortex. The components did not directly align with previous explanations of object perception. Instead, our findings suggest the organisation of the visual brain is based on the statistical properties of objects in the natural world.</p>","PeriodicalId":50114,"journal":{"name":"Journal of Neuroscience","volume":" ","pages":""},"PeriodicalIF":4.4000,"publicationDate":"2024-11-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"A data-driven analysis of the perceptual and neural responses to natural objects reveals organising principles of human visual cognition.\",\"authors\":\"David M Watson, Timothy J Andrews\",\"doi\":\"10.1523/JNEUROSCI.1318-24.2024\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>A key challenge in understanding the functional organisation of visual cortex stems from the fact that only a small proportion of the objects experienced during natural viewing can be presented in a typical experiment. 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These components revealed smooth, graded neural topographies, which were similar in both hemispheres, and captured a variety of object properties including animacy, real-world size, and object category. However, they did not accord in any simple way with previous theoretical perspectives on object perception. Instead, our findings suggest that visual cortex encodes information in a statistically efficient manner, reflecting natural variability among objects.<b>Significance statement</b> The ability to recognise objects is fundamental to how we interact with our environment, yet the organising principles underlying neural representations of visual objects remain contentious. In this study, we sought to address this question by analysing perceptual and neural responses to a large, unbiased sample of objects. Using a data-driven approach, we leveraged perceptual properties of objects to predict neural responses using a small number of components. 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引用次数: 0
摘要
了解视觉皮层功能组织的一个主要挑战来自于这样一个事实,即在典型的实验中只能呈现一小部分在自然观看过程中体验到的物体。这种限制往往导致实验设计只能比较实验者定义的刺激条件下物体的反应,从而限制了对数据的解释。为了克服这一问题,我们使用了 THINGS 计划中的图片,该计划提供了系统的自然物体样本。然后,通过数据驱动分析,结合对这些物体的感知和神经反应,揭示视觉大脑的功能组织。物体的感知属性来自于对相似性判断的分析,而神经属性则来自于对相同物体的全脑 fMRI 反应。然后,利用偏最小二乘回归(PLSR)从感知属性预测整个大脑的神经反应,同时进行降维处理。PLSR 模型仅使用少量成分就能准确预测整个视觉皮层的神经反应。这些成分揭示了平滑、分级的神经拓扑图,在两个大脑半球中相似,并捕捉到了各种物体属性,包括动物性、真实世界大小和物体类别。然而,它们与之前关于物体感知的理论观点并不一致。意义声明 识别物体的能力是我们与环境互动的基础,但视觉物体神经表征的组织原理仍存在争议。在这项研究中,我们试图通过分析对大量无偏见物体样本的感知和神经反应来解决这个问题。通过数据驱动法,我们利用物体的感知特性,使用少量成分预测神经反应。该模型能高度准确地预测整个视觉皮层的神经反应。这些成分与之前对物体感知的解释并不直接一致。相反,我们的研究结果表明,视觉大脑的组织是基于自然世界中物体的统计特性。
A data-driven analysis of the perceptual and neural responses to natural objects reveals organising principles of human visual cognition.
A key challenge in understanding the functional organisation of visual cortex stems from the fact that only a small proportion of the objects experienced during natural viewing can be presented in a typical experiment. This constraint often leads to experimental designs that compare responses to objects from experimenter-defined stimulus conditions, potentially limiting the interpretation of the data. To overcome this issue, we used images from the THINGS initiative, which provides a systematic sampling of natural objects. A data-driven analysis was then applied to reveal the functional organisation of the visual brain, incorporating both perceptual and neural responses to these objects. Perceptual properties of the objects were taken from an analysis of similarity judgements, and neural properties were taken from whole brain fMRI responses to the same objects. Partial least squares regression (PLSR) was then used to predict neural responses across the brain from the perceptual properties while simultaneously applying dimensionality reduction. The PLSR model accurately predicted neural responses across visual cortex using only a small number of components. These components revealed smooth, graded neural topographies, which were similar in both hemispheres, and captured a variety of object properties including animacy, real-world size, and object category. However, they did not accord in any simple way with previous theoretical perspectives on object perception. Instead, our findings suggest that visual cortex encodes information in a statistically efficient manner, reflecting natural variability among objects.Significance statement The ability to recognise objects is fundamental to how we interact with our environment, yet the organising principles underlying neural representations of visual objects remain contentious. In this study, we sought to address this question by analysing perceptual and neural responses to a large, unbiased sample of objects. Using a data-driven approach, we leveraged perceptual properties of objects to predict neural responses using a small number of components. This model predicted neural responses with a high degree of accuracy across visual cortex. The components did not directly align with previous explanations of object perception. Instead, our findings suggest the organisation of the visual brain is based on the statistical properties of objects in the natural world.
期刊介绍:
JNeurosci (ISSN 0270-6474) is an official journal of the Society for Neuroscience. It is published weekly by the Society, fifty weeks a year, one volume a year. JNeurosci publishes papers on a broad range of topics of general interest to those working on the nervous system. Authors now have an Open Choice option for their published articles