Hiroshi Shigetomi1, Kiyoshi Oka1, Takeshi Seki2, Hiroshi Kobayashi3. 1. Department of Obstetrics and Gynecology, Nara Medical University, Nara, Japan. 2. Department of Mechanical Engineering, Graduate School of Engineering and Resource Science, Akita University, Akita, Japan. 3. Department of Obstetrics and Gynecology, Nara Medical University, Nara, Japan. Electronic address: hirokoba@naramed-u.ac.jp.
Abstract
STUDY OBJECTIVE: Because of the rapid growth of minimally invasive surgical procedures, we developed an ultrathin fiberscopic imaging system for laser surgery that could be an important instrument for clinical use in an office setting. METHODS AND MAIN RESULTS: A new device, consisting of a custom 1.1-mm diameter flexible fiberscope and ytterbium laser-supported ablation system (composite-type optical fiberscope), has been developed to achieve accurate laser irradiation for minimally invasive procedures of intrauterine disease. This system was validated ex vivo with successful laser ablation under observation. This study provides the design, characterization, performance, and preclinical validation of an optimized composite-type optical fiberscope system. The validation of this fiberscope for endometrial ablation was performed in 12 hysterectomy samples. The irradiated spot diameter and depth were (mean ± SD) 2.80 ± 0.28 mm and 1.53 ± 0.58 mm, respectively, in the range of 185 to 400 J. The effects of the laser on endometrial tissue depended strongly on the combined effects of the output power density and duration of irradiation. The new device makes it possible to perform accurate ablation, because our technology concentrated on combining the 2 subsystems into a single prototype capable of simultaneously observing both the endometrial lesion and the laser spot on a monitor. CONCLUSIONS: In conclusion, the feasibility and performance of the composite-type fiberscope system were demonstrated in preclinical studies.
STUDY OBJECTIVE: Because of the rapid growth of minimally invasive surgical procedures, we developed an ultrathin fiberscopic imaging system for laser surgery that could be an important instrument for clinical use in an office setting. METHODS AND MAIN RESULTS: A new device, consisting of a custom 1.1-mm diameter flexible fiberscope and ytterbium laser-supported ablation system (composite-type optical fiberscope), has been developed to achieve accurate laser irradiation for minimally invasive procedures of intrauterine disease. This system was validated ex vivo with successful laser ablation under observation. This study provides the design, characterization, performance, and preclinical validation of an optimized composite-type optical fiberscope system. The validation of this fiberscope for endometrial ablation was performed in 12 hysterectomy samples. The irradiated spot diameter and depth were (mean ± SD) 2.80 ± 0.28 mm and 1.53 ± 0.58 mm, respectively, in the range of 185 to 400 J. The effects of the laser on endometrial tissue depended strongly on the combined effects of the output power density and duration of irradiation. The new device makes it possible to perform accurate ablation, because our technology concentrated on combining the 2 subsystems into a single prototype capable of simultaneously observing both the endometrial lesion and the laser spot on a monitor. CONCLUSIONS: In conclusion, the feasibility and performance of the composite-type fiberscope system were demonstrated in preclinical studies.