Hayato Takeyama scite author profile

Hayato Takeyama

2Publications

5Citation Statements Received

68Citation Statements Given

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Tokyo Institute of Technology

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Eye Explorer: A robotic endoscope holder for eye surgery

Zhou

Kimura

Takeyama

et al. 2020

Robotics Computer Surgery

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Background Holding endoscopes by hand when performing eye surgery reduces the dexterity of the surgeon. Methods A robotic endoscope holder called “Eye Explorer” is proposed to hold the endoscope and free the surgeon's hand. Results This device satisfies the engineering and clinical requirements of eye surgery. The force for manual operation is less than 0.5 N. The observable ranges inside the patient's eye considering horizontal and vertical perspectives are 118° and 97°, and the motion of the holder does not interfere with the surgeon's hand and other surgical devices. The self‐weight compensation can prevent the endoscope from falling when extra supporting force is released. When comparing the external force exerted on the eye by the Eye Explorer with that in case of manual operation, a decrease of more than 15% can be observed. Moreover, the consumption time of endoscope view adjustment using the Eye Explorer and manual operation does not significantly differ. Conclusion The Eye Explorer allows dual‐hand operation, facilitating a successful endoscopic eye surgery.

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Real‐time fundus reconstruction and intraocular mapping using an ophthalmic endoscope

Zhou

Takeyama

Nakao

et al. 2023

Robotics Computer Surgery

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Background: Robotic ophthalmic endoscope holders allow surgeons to execute dual-hand operations in eye surgery. To prevent needle-like endoscopes from invading the retina when moving, surgeons expect visual and real-time information about the relative special relationship between the endoscope and fundus. Methods:This study develops a real-time fundus reconstruction method. First, using deep learning, the method estimates the distance between the fundus part corresponding to every pixel of the RGB endoscopic image and the endoscope.Then, by combining the estimated distance with the kinematics of a robotic holder, the point cloud representing the present fundus area is generated, and by which the size and position of the eyeball are estimated. Results:This method shows a real-time frequency of 10 Hz, which is robust to eyeball movement. The error of fundus reconstruction is about 0.5 mm, and the error of eyeball estimation is about 1 mm. Conclusion:Using this fundus reconstruction method can map the position of the endoscope inside the eyeball when using a robotic endoscope holder in eye surgery.The overall accuracy level meets the ophthalmologists' accuracy requirements of ophthalmologists.

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Hayato Takeyama

Eye Explorer: A robotic endoscope holder for eye surgery

Real‐time fundus reconstruction and intraocular mapping using an ophthalmic endoscope

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