Subthalamic nucleus detects unnatural android movement

An android, i.e., a realistic humanoid robot with human-like capabilities, may induce an uncanny feeling in human observers. The uncanny feeling about an android has two main causes: its appearance and movement. The uncanny feeling about an android increases when its appearance is almost human-like...

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Veröffentlicht in:	Scientific reports 2017-12, Vol.7 (1), p.17851-7, Article 17851
Hauptverfasser:	Ikeda, Takashi, Hirata, Masayuki, Kasaki, Masashi, Alimardani, Maryam, Matsushita, Kojiro, Yamamoto, Tomoyuki, Nishio, Shuichi, Ishiguro, Hiroshi
Format:	Artikel
Sprache:	eng
Schlagworte:	631/378/2632/1323 639/166/988 692/617/375/346/1718 Adult Brain - physiology Brain mapping Brain research Deep Brain Stimulation - methods Electrical stimuli Female Functional magnetic resonance imaging Humanities and Social Sciences Humans Hypotheses Magnetic Resonance Imaging - methods Male Movement - physiology multidisciplinary Psychomotor Performance - physiology Questionnaires Robots Science Science (multidisciplinary) Solitary tract nucleus Subthalamic nucleus Subthalamic Nucleus - physiology Young Adult
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description	An android, i.e., a realistic humanoid robot with human-like capabilities, may induce an uncanny feeling in human observers. The uncanny feeling about an android has two main causes: its appearance and movement. The uncanny feeling about an android increases when its appearance is almost human-like but its movement is not fully natural or comparable to human movement. Even if an android has human-like flexible joints, its slightly jerky movements cause a human observer to detect subtle unnaturalness in them. However, the neural mechanism underlying the detection of unnatural movements remains unclear. We conducted an fMRI experiment to compare the observation of an android and the observation of a human on which the android is modelled, and we found differences in the activation pattern of the brain regions that are responsible for the production of smooth and natural movement. More specifically, we found that the visual observation of the android, compared with that of the human model, caused greater activation in the subthalamic nucleus (STN). When the android’s slightly jerky movements are visually observed, the STN detects their subtle unnaturalness. This finding suggests that the detection of unnatural movements is attributed to an error signal resulting from a mismatch between a visual input and an internal model for smooth movement.
doi_str_mv	10.1038/s41598-017-17849-2
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subjects	631/378/2632/1323 639/166/988 692/617/375/346/1718 Adult Brain - physiology Brain mapping Brain research Deep Brain Stimulation - methods Electrical stimuli Female Functional magnetic resonance imaging Humanities and Social Sciences Humans Hypotheses Magnetic Resonance Imaging - methods Male Movement - physiology multidisciplinary Psychomotor Performance - physiology Questionnaires Robots Science Science (multidisciplinary) Solitary tract nucleus Subthalamic nucleus Subthalamic Nucleus - physiology Young Adult
title	Subthalamic nucleus detects unnatural android movement
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