Shunsuke Yoshimoto scite author profile

We have previously reported the production of endothelin, a potent vasoconstrictor peptide, by porcine cerebral microvessel endothelia and suggested its important role in the regulation of local blood flow within the brain. In our present study, radioimmunoassay with anti-porcine endothelin antiserura revealed that endothelin, produced by cerebral microvessel endothelia grown on a filter, is released mainly to the basement membrane side, not the vascular lumen side. This finding suggests that endothelin constricts arterioles locally where it is produced by endothelia. We also found that cerebral microvessel endothelia produce less endothelin under low oxygen pressure and more endothelin under low carbon dioxide pressure. Our results suggest that endothelin has a role in the regulation of cerebral blood flow in response to oxygen and carbon dioxide pressure. (Stroke 1991;22:378-383)

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Cerebral microvessel endothelium is producing endothelin

Yoshimoto

et al. 1990

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Material Roughness Modulation via Electrotactile Augmentation

Yoshimoto

Kuroda

Imura

et al. 2015

IEEE Trans. Haptics

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Tactile exploration of a material's texture using a bare finger pad is a daily human activity. However, modern tactile displays do not allow users to experience the natural sensations of a material when artificial sensations are presented. We propose an electrotactile augmentation technique capable of superimposing vibrotactile sensations in a finger pad, thereby allowing the texture modulation of real materials. Users attach two stimulus electrodes to the middle phalanx of a finger and a grounded electrode at the base of the finger in order to evoke nerve activity. This paper evaluates the proposed electrotactile augmentation for roughness modulation of real materials. First, we introduce the principle of the electrotactile display, which presents artificial sensations at the finger pad. We then confirm that the perceived frequency of mechanical vibration at the finger pad can be shifted using electrotactile augmentation. Finally, we discuss a user study, wherein participants rated the roughness of real materials explored using the proposed system. Experimental results indicate that fine- and macro-roughness perceptions of real materials can be altered using electrotactile augmentation.

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An articulated neurosurgical navigation system using MRI and CT images

Kosugi

Watanabe

Goto

et al. 1988

IEEE Trans. Biomed. Eng.

117

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Tomographic Approach for Universal Tactile Imaging With Electromechanically Coupled Conductors

Yoshimoto

Kuroda

Oshiro

2020

IEEE Trans. Ind. Electron.

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