2021
Kato, Takahisa; King, Franklin; Takagi, Kiyoshi; Hata, Nobuhiko
Robotized Catheter With Enhanced Distal Targeting for Peripheral Pulmonary Biopsy Journal Article
In: IEEE-ASME TRANSACTIONS ON MECHATRONICS, vol. 26, no. 5, pp. 2451–2461, 2021, ISSN: 1083-4435, 1941-014X, (Num Pages: 11 Place: Piscataway Publisher: Ieee-Inst Electrical Electronics Engineers Inc Web of Science ID: WOS:000707442500022).
Abstract | Links | BibTeX | Tags: ABLATION, Bending, biopsy, Bronchoscopy, Catheters, Continuum robots, Design, Dexterous manipulators, LESIONS, Lung, lung biopsy, medical robotics, PLATFORM, REMOTE MAGNETIC NAVIGATION, robotized catheter, robots, SHAPE ESTIMATION, Surgery, SYSTEM, Tools, TRACKING
@article{kato_robotized_2021,
title = {Robotized Catheter With Enhanced Distal Targeting for Peripheral Pulmonary Biopsy},
author = {Takahisa Kato and Franklin King and Kiyoshi Takagi and Nobuhiko Hata},
doi = {10.1109/TMECH.2020.3040314},
issn = {1083-4435, 1941-014X},
year = {2021},
date = {2021-10-01},
journal = {IEEE-ASME TRANSACTIONS ON MECHATRONICS},
volume = {26},
number = {5},
pages = {2451–2461},
abstract = {Transbronchial biopsy with a lung catheter is more appealing with lower complication risks for peripheral pulmonary biopsy. The distal tips of the current lung catheters lack targeting capabilities, however, which prevents a physician from guiding the biopsy tools to lesions, especially those in a peribronchial location. In this study, we investigated if a robotized catheter could enhance distal targeting after passing through tortuous bronchi. We experimentally evaluated targeting accuracy and the spatial dispersion of targeting with attention to catheter shape constraints by utilizing the bronchi of a patient-derived lung phantom. This newly developed robotized catheter has an outer diameter of 3 mm and a total length of 800 mm and comprises two bending sections at the distal 30 mm length. With these two bending sections, the distal tip can be steered to peribronchial lesions followed by the targeting of multiple locations inside the lesion with controlled dispersion to improve opportunities for tissue sampling. In the experimental results, the targeting position error for a peribronchial lesion ranged from 4.6 +/- 1.2 to 7.2 +/- 3.3 mm (mean +/- STD) among the different shape constraints. As for the targeting dispersion, the shape constraints reduced dispersion ability by a maximum of 50% compared to straight reference constraints, while the dispersion was still larger than the expected minimum requirement of 1 mm. One-way analysis of variance concluded that targeting accuracy and targeting dispersion included a significant dependence on shape constraints (p < .05). This study demonstrates the feasibility of enhancing distal targeting with the proposed robotized catheter and found that bronchi shape constraints significantly affect targeting capability.},
note = {Num Pages: 11
Place: Piscataway
Publisher: Ieee-Inst Electrical Electronics Engineers Inc
Web of Science ID: WOS:000707442500022},
keywords = {ABLATION, Bending, biopsy, Bronchoscopy, Catheters, Continuum robots, Design, Dexterous manipulators, LESIONS, Lung, lung biopsy, medical robotics, PLATFORM, REMOTE MAGNETIC NAVIGATION, robotized catheter, robots, SHAPE ESTIMATION, Surgery, SYSTEM, Tools, TRACKING},
pubstate = {published},
tppubtype = {article}
}
Transbronchial biopsy with a lung catheter is more appealing with lower complication risks for peripheral pulmonary biopsy. The distal tips of the current lung catheters lack targeting capabilities, however, which prevents a physician from guiding the biopsy tools to lesions, especially those in a peribronchial location. In this study, we investigated if a robotized catheter could enhance distal targeting after passing through tortuous bronchi. We experimentally evaluated targeting accuracy and the spatial dispersion of targeting with attention to catheter shape constraints by utilizing the bronchi of a patient-derived lung phantom. This newly developed robotized catheter has an outer diameter of 3 mm and a total length of 800 mm and comprises two bending sections at the distal 30 mm length. With these two bending sections, the distal tip can be steered to peribronchial lesions followed by the targeting of multiple locations inside the lesion with controlled dispersion to improve opportunities for tissue sampling. In the experimental results, the targeting position error for a peribronchial lesion ranged from 4.6 +/- 1.2 to 7.2 +/- 3.3 mm (mean +/- STD) among the different shape constraints. As for the targeting dispersion, the shape constraints reduced dispersion ability by a maximum of 50% compared to straight reference constraints, while the dispersion was still larger than the expected minimum requirement of 1 mm. One-way analysis of variance concluded that targeting accuracy and targeting dispersion included a significant dependence on shape constraints (p < .05). This study demonstrates the feasibility of enhancing distal targeting with the proposed robotized catheter and found that bronchi shape constraints significantly affect targeting capability.
2020
Shono, Naoyuki; Ninni, Brian; King, Franklin; Kato, Takahisa; Tokuda, Junichi; Fujimoto, Takahiro; Tuncali, Kemal; Hata, Nobuhiko
Simulated accuracy assessment of small footprint body-mounted probe alignment device for MRI-guided cryotherapy of abdominal lesions Journal Article
In: MEDICAL PHYSICS, vol. 47, no. 6, pp. 2337–2349, 2020, ISSN: 0094-2405, 2473-4209, (Num Pages: 13 Place: Hoboken Publisher: Wiley Web of Science ID: WOS:000521855600001).
Abstract | Links | BibTeX | Tags: biopsy, Cryoablation, feasibility study, hepatic tumor, LIVER-TUMORS, MICROWAVE ABLATION, MOTION MANAGEMENT, MRI-guided intervention, needle guidance, RADIOFREQUENCY ABLATION, renal tumor, RENAL TUMORS, TRACKING
@article{shono_simulated_2020,
title = {Simulated accuracy assessment of small footprint body-mounted probe alignment device for MRI-guided cryotherapy of abdominal lesions},
author = {Naoyuki Shono and Brian Ninni and Franklin King and Takahisa Kato and Junichi Tokuda and Takahiro Fujimoto and Kemal Tuncali and Nobuhiko Hata},
doi = {10.1002/mp.14116},
issn = {0094-2405, 2473-4209},
year = {2020},
date = {2020-06-01},
journal = {MEDICAL PHYSICS},
volume = {47},
number = {6},
pages = {2337–2349},
abstract = {Purpose Magnetic resonance imaging (MRI)-guided percutaneous cryotherapy of abdominal lesions, an established procedure, uses MRI to guide and monitor the cryoablation of lesions. Methods to precisely guide cryotherapy probes with a minimum amount of trial-and-error are yet to be established. To aid physicians in attaining precise probe alignment without trial-and-error, a body-mounted motorized cryotherapy-probe alignment device (BMCPAD) with motion compensation was clinically tested in this study. The study also compared the contribution of body motion and organ motion compensation to the guidance accuracy of a body-mounted probe alignment device. Methods The accuracy of guidance using the BMCPAD was prospectively measured during MRI-guided percutaneous cryotherapies before insertion of the probes. Clinical parameters including patient age, types of anesthesia, depths of the target, and organ sites of target were collected. By using MR images of the target organs and fiducial markers embedded in the BMCPAD, we retrospectively simulated the guidance accuracy with body motion compensation, organ motion compensation, and no compensation. The collected data were analyzed to test the impact of motion compensation on the guidance accuracy. Results Thirty-seven physical guidance of probes were prospectively recorded for sixteen completed cases. The accuracy of physical guidance using the BMCPAD was 13.4 +/- 11.1 mm. The simulated accuracy of guidance with body motion compensation, organ motion compensation, and no compensation was 2.4 +/- 2.9 mm, 2.2 +/- 1.6 mm, and 3.5 +/- 2.9 mm, respectively. Data analysis revealed that the body motion compensation and organ motion compensation individually impacted the improvement in the accuracy of simulated guidance. Moreover, the difference in the accuracy of guidance either by body motion compensation or organ motion compensation was not statistically significant. The major clinical parameters impacting the accuracy of guidance were the body and organ motions. Patient age, types of anesthesia, depths of the target, and organ sites of target did not influence the accuracy of guidance using BMCPAD. The magnitude of body surface movement and organ movement exhibited mutual statistical correlation. Conclusions The BMCPAD demonstrated guidance accuracy comparable to that of previously reported devices for CT-guided procedures. The analysis using simulated motion compensation revealed that body motion compensation and organ motion compensation individually impact the improvement in the accuracy of device-guided cryotherapy probe alignment. Considering the correlation between body and organ movements, we also determined that body motion compensation using the ring fiducial markers in the BMCPAD can be solely used to address both body and organ motions in MRI-guided cryotherapy.},
note = {Num Pages: 13
Place: Hoboken
Publisher: Wiley
Web of Science ID: WOS:000521855600001},
keywords = {biopsy, Cryoablation, feasibility study, hepatic tumor, LIVER-TUMORS, MICROWAVE ABLATION, MOTION MANAGEMENT, MRI-guided intervention, needle guidance, RADIOFREQUENCY ABLATION, renal tumor, RENAL TUMORS, TRACKING},
pubstate = {published},
tppubtype = {article}
}
Purpose Magnetic resonance imaging (MRI)-guided percutaneous cryotherapy of abdominal lesions, an established procedure, uses MRI to guide and monitor the cryoablation of lesions. Methods to precisely guide cryotherapy probes with a minimum amount of trial-and-error are yet to be established. To aid physicians in attaining precise probe alignment without trial-and-error, a body-mounted motorized cryotherapy-probe alignment device (BMCPAD) with motion compensation was clinically tested in this study. The study also compared the contribution of body motion and organ motion compensation to the guidance accuracy of a body-mounted probe alignment device. Methods The accuracy of guidance using the BMCPAD was prospectively measured during MRI-guided percutaneous cryotherapies before insertion of the probes. Clinical parameters including patient age, types of anesthesia, depths of the target, and organ sites of target were collected. By using MR images of the target organs and fiducial markers embedded in the BMCPAD, we retrospectively simulated the guidance accuracy with body motion compensation, organ motion compensation, and no compensation. The collected data were analyzed to test the impact of motion compensation on the guidance accuracy. Results Thirty-seven physical guidance of probes were prospectively recorded for sixteen completed cases. The accuracy of physical guidance using the BMCPAD was 13.4 +/- 11.1 mm. The simulated accuracy of guidance with body motion compensation, organ motion compensation, and no compensation was 2.4 +/- 2.9 mm, 2.2 +/- 1.6 mm, and 3.5 +/- 2.9 mm, respectively. Data analysis revealed that the body motion compensation and organ motion compensation individually impacted the improvement in the accuracy of simulated guidance. Moreover, the difference in the accuracy of guidance either by body motion compensation or organ motion compensation was not statistically significant. The major clinical parameters impacting the accuracy of guidance were the body and organ motions. Patient age, types of anesthesia, depths of the target, and organ sites of target did not influence the accuracy of guidance using BMCPAD. The magnitude of body surface movement and organ movement exhibited mutual statistical correlation. Conclusions The BMCPAD demonstrated guidance accuracy comparable to that of previously reported devices for CT-guided procedures. The analysis using simulated motion compensation revealed that body motion compensation and organ motion compensation individually impact the improvement in the accuracy of device-guided cryotherapy probe alignment. Considering the correlation between body and organ movements, we also determined that body motion compensation using the ring fiducial markers in the BMCPAD can be solely used to address both body and organ motions in MRI-guided cryotherapy.
2018
Abayazid, Momen; Kato, Takahisa; Silverman, Stuart G.; Hata, Nobuhiko
Using needle orientation sensing as surrogate signal for respiratory motion estimation in percutaneous interventions Journal Article
In: INTERNATIONAL JOURNAL OF COMPUTER ASSISTED RADIOLOGY AND SURGERY, vol. 13, no. 1, pp. 125–133, 2018, ISSN: 1861-6410, 1861-6429, (Num Pages: 9 Place: Heidelberg Publisher: Springer Heidelberg Web of Science ID: WOS:000419481300013).
Abstract | Links | BibTeX | Tags: ABDOMINAL INTERVENTIONS, biopsy, INSERTION, Interventional radiology, Lung, Machine learning, Magnetic Resonance Imaging, MODEL, Motion compensation, percutaneous needle insertion, Radiotherapy, Respiratory motion, SYSTEM, TOMOGRAPHY, TRACKING, TUMOR MOTION
@article{abayazid_using_2018,
title = {Using needle orientation sensing as surrogate signal for respiratory motion estimation in percutaneous interventions},
author = {Momen Abayazid and Takahisa Kato and Stuart G. Silverman and Nobuhiko Hata},
doi = {10.1007/s11548-017-1644-z},
issn = {1861-6410, 1861-6429},
year = {2018},
date = {2018-01-01},
journal = {INTERNATIONAL JOURNAL OF COMPUTER ASSISTED RADIOLOGY AND SURGERY},
volume = {13},
number = {1},
pages = {125–133},
abstract = {Purpose To develop and evaluate an approach to estimate the respiratory-induced motion of lesions in the chest and abdomen. Materials and methods The proposed approach uses the motion of an initial reference needle inserted into a moving organ to estimate the lesion (target) displacement that is caused by respiration. The needles position is measured using an inertial measurement unit (IMU) sensor externally attached to the hub of an initially placed reference needle. Data obtained from the IMU sensor and the target motion are used to train a learning-based approach to estimate the position of the moving target. An experimental platform was designed to mimic respiratory motion of the liver. Liver motion profiles of human subjects provided inputs to the experimental platform. Variables including the insertion angle, target depth, target motion velocity and target proximity to the reference needle were evaluated by measuring the error of the estimated target position and processing time. Results The mean error of estimation of the target position ranged between 0.86 and 1.29mm. The processing maximum training and testing time was 5ms which is suitable for real-time target motion estimation using the needle position sensor. Conclusion The external motion of an initially placed reference needle inserted into a moving organ can be used as a surrogate, measurable and accessible signal to estimate in real-time the position of a moving target caused by respiration; this technique could then be used to guide the placement of subsequently inserted needles directly into the target.},
note = {Num Pages: 9
Place: Heidelberg
Publisher: Springer Heidelberg
Web of Science ID: WOS:000419481300013},
keywords = {ABDOMINAL INTERVENTIONS, biopsy, INSERTION, Interventional radiology, Lung, Machine learning, Magnetic Resonance Imaging, MODEL, Motion compensation, percutaneous needle insertion, Radiotherapy, Respiratory motion, SYSTEM, TOMOGRAPHY, TRACKING, TUMOR MOTION},
pubstate = {published},
tppubtype = {article}
}
Purpose To develop and evaluate an approach to estimate the respiratory-induced motion of lesions in the chest and abdomen. Materials and methods The proposed approach uses the motion of an initial reference needle inserted into a moving organ to estimate the lesion (target) displacement that is caused by respiration. The needles position is measured using an inertial measurement unit (IMU) sensor externally attached to the hub of an initially placed reference needle. Data obtained from the IMU sensor and the target motion are used to train a learning-based approach to estimate the position of the moving target. An experimental platform was designed to mimic respiratory motion of the liver. Liver motion profiles of human subjects provided inputs to the experimental platform. Variables including the insertion angle, target depth, target motion velocity and target proximity to the reference needle were evaluated by measuring the error of the estimated target position and processing time. Results The mean error of estimation of the target position ranged between 0.86 and 1.29mm. The processing maximum training and testing time was 5ms which is suitable for real-time target motion estimation using the needle position sensor. Conclusion The external motion of an initially placed reference needle inserted into a moving organ can be used as a surrogate, measurable and accessible signal to estimate in real-time the position of a moving target caused by respiration; this technique could then be used to guide the placement of subsequently inserted needles directly into the target.