Your search keyword '"Svenja Ipsen"' showing total 26 results

1. Learning Local Feature Descriptions in 3D Ultrasound.

Author

Daniel Wulff, Jannis Hagenah, Svenja Ipsen, and Floris Ernst

Published

2020

2. A visual probe positioning tool for 4D ultrasound-guided radiotherapy.

Author

Svenja Ipsen, Ralf Bruder, Ivo Kuhlemann, Philipp Jauer, Laura Motisi, Florian Cremers, Floris Ernst, and Achim Schweikard

Published

2018

3. Medical Robotics for Ultrasound Imaging: Current Systems and Future Trends

Author

Felix von Haxthausen, Jannis Hagenah, Svenja Ipsen, Verónica García-Vázquez, Sven Böttger, and Daniel Wulff

Subjects

0209 industrial biotechnology, Computer science, media_common.quotation_subject, Autonomous image acquisition, 02 engineering and technology, 030218 nuclear medicine & medical imaging, Virtual/augmented reality, 03 medical and health sciences, 020901 industrial engineering & automation, 0302 clinical medicine, Human–computer interaction, Intelligent systems, media_common, Focus (computing), business.industry, Intelligent decision support system, Robotics, General Medicine, Autonomous therapy guidance, Medical robotics, Collaborative robotics, Medical and Surgical Robotics (F Ernst, Section Editor), Teleoperation, Telesonography, Robot, Augmented reality, Artificial intelligence, business, Autonomy

Abstract

Purpose of Review This review provides an overview of the most recent robotic ultrasound systems that have contemporary emerged over the past five years, highlighting their status and future directions. The systems are categorized based on their level of robot autonomy (LORA). Recent Findings Teleoperating systems show the highest level of technical maturity. Collaborative assisting and autonomous systems are still in the research phase, with a focus on ultrasound image processing and force adaptation strategies. However, missing key factors are clinical studies and appropriate safety strategies. Future research will likely focus on artificial intelligence and virtual/augmented reality to improve image understanding and ergonomics. Summary A review on robotic ultrasound systems is presented in which first technical specifications are outlined. Hereafter, the literature of the past five years is subdivided into teleoperation, collaborative assistance, or autonomous systems based on LORA. Finally, future trends for robotic ultrasound systems are reviewed with a focus on artificial intelligence and virtual/augmented reality.

Published

2021

4. Target tracking accuracy and latency with different 4D ultrasound systems – a robotic phantom study

Author

Sven Böttger, Holger Schwegmann, Svenja Ipsen, and Floris Ernst

Subjects

Motion compensation, real-time imaging, Computer science, business.industry, Biomedical Engineering, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Real time imaging, radiation therapy, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, motion compensation, 0302 clinical medicine, 030220 oncology & carcinogenesis, Medicine, Computer vision, Artificial intelligence, image guidance, Latency (engineering), business, Image guidance, 4d ultrasound

Abstract

Ultrasound (US) imaging, in contrast to other image guidance techniques, offers the distinct advantage of providing volumetric image data in real-time (4D) without using ionizing radiation. The goal of this study was to perform the first quantitative comparison of three different 4D US systems with fast matrix array probes and real-time data streaming regarding their target tracking accuracy and system latency. Sinusoidal motion of varying amplitudes and frequencies was used to simulate breathing motion with a robotic arm and a static US phantom. US volumes and robot positions were acquired online and stored for retrospective analysis. A template matching approach was used for target localization in the US data. Target motion measured in US was compared to the reference trajectory performed by the robot to determine localization accuracy and system latency. Using the robotic setup, all investigated 4D US systems could detect a moving target with sub-millimeter accuracy. However, especially high system latency increased tracking errors substantially and should be compensated with prediction algorithms for respiratory motion compensation.

Published

2020

5. Assessment of 4D Ultrasound Systems for Image-guided Radiation Therapy – Image Quality, Framerates and CT Artifacts

Author

Verónica García-Vázquez, Achim Schweikard, Svenja Ipsen, Floris Ernst, and Ralf Bruder

Subjects

business.industry, Computer science, Image quality, lcsh:R, Biomedical Engineering, lcsh:Medicine, radiation therapy, motion compensation, system compari, Computer vision, image guidance, Artificial intelligence, business, 4d us, 4d ultrasound, Image-guided radiation therapy

Abstract

4D ultrasound (4D US) is gaining relevance as a tracking method in radiation therapy (RT) with modern matrix array probes offering new possibilities for real-time target detection. However, for clinical implementation of USguided RT, image quality, volumetric framerate and artifacts caused by the probe’s presence during planning and / or setup computed tomography (CT) must be quantified. We compared three diagnostic 4D US systems with matrix array probes using a commercial wire phantom to measure spatial resolution as well as a calibration and a torso phantom to assess different image quality metrics. CT artifacts were quantified in the torso phantom by calculating the total variation and percentage of affected voxels between a reference CT scan and CT scans with probes in place. We found that state-of-the-art 4D US systems with small probes can fit inside the CT bore and cause fewer metal artifacts than larger probes. US image quality varies between systems and is task-dependent. Volume sizes and framerates are much higher than the commercial guidance solution for US-guided RT, warranting further investigation regarding clinical performance for image guidance.

Published

2019

6. Robust motion tracking of deformable targets in the liver using binary feature libraries in 4D ultrasound

Author

Daniel Wulff, Ivo Kuhlemann, Achim Schweikard, Svenja Ipsen, and Floris Ernst

Subjects

Computer science, business.industry, deformation, Biomedical Engineering, feature detection, Binary number, radiation therapy, motion compensation, Match moving, Feature (computer vision), Medicine, Computer vision, image guidance, Artificial intelligence, business, 4d ultrasound

Abstract

In radiation therapy of abdominal targets, optimal tumor irradiation can be challenging due to intrafractional motion. Current target localization methods are mainly indirect, surrogate-based and the patient is exposed to additional radiation due to X-ray imaging. In contrast, 4D ultrasound (4DUS) imaging provides volumetric images of soft tissue tumors in real-time without ionizing radiation, facilitating a non-invasive, direct tracking method. In this study, the target was defined by features located in its local neighborhood. Features were extracted using the FAST detector and the BRISK descriptor, which were extended to 3D. To account for anatomical variability, a feature library was generated that contains manually annotated target information and relative locations of the features. During tracking, features were extracted from the current 4DUS volume and compared to the feature library. Recognized features are used to estimate feature position and shape. The developed method was evaluated in 4DUS sequences of the liver of three healthy subjects. For each dataset, a target was defined and manually contoured in a training and a test sequence. Training was used for library creation, the test sequence for target tracking. The target estimations are compared to the annotations to quantify a tracking error. The results show that binary feature libraries can be used for robust target localization in 4DUS data of the liver and could potentially serve as a tracking method less sensitive to target deformation.

Published

2019

7. Automation and robotics in ultrasound-guided radiotherapy

Author

Alexander Schlaefer, Svenja Ipsen, and Floris Ernst

Subjects

Radiation therapy, medicine.medical_specialty, Computer science, business.industry, medicine.medical_treatment, medicine, Robotics, Medical physics, Artificial intelligence, business, Automation, Ultrasound guided

Published

2021

8. Ultrasound for measuring intrafractional organ motion

Author

Svenja Ipsen and Alexander Grimwood

Subjects

Organ Motion, business.industry, Ultrasound, Medicine, business, Biomedical engineering

Published

2021

9. Learning Local Feature Descriptions in 3D Ultrasound

Author

Svenja Ipsen, Daniel Wulff, Floris Ernst, and Jannis Hagenah

Subjects

Modality (human–computer interaction), Cross-correlation, medicine.diagnostic_test, Computer science, business.industry, Deep learning, Pattern recognition, 02 engineering and technology, Autoencoder, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, Identification (information), 0302 clinical medicine, Feature (computer vision), 0202 electrical engineering, electronic engineering, information engineering, medicine, 020201 artificial intelligence & image processing, 3D ultrasound, Artificial intelligence, business, Feature learning

Abstract

Tools for automatic image analysis are gaining importance in the clinical workflow, ranging from time-saving tools in diagnostics to real-time methods in image-guided interventions. Over the last years, ultrasound (US) imaging has become a promising modality for image guidance due to its ability to provide volumetric images of soft tissue in real-time without using ionizing radiation. One key challenge in automatic US image analysis is the identification of suitable features to describe the image or regions within, e.g. for recognition, alignment or tracking tasks. In recent years, features that were learned data-drivenly provided promising results. Even though these approaches outperformed hand-crafted feature extractors in many applications, there is still a lack of feature learning for local description of three-dimensional US (3DUS) images. In this work, we present a completely data-driven feature learning approach for 3DUS images for usage in target tracking. To this end, we use a 3D convolutional autoencoder (AE) with a custom loss function to encode 3DUS image patches into a compact latent space that serves as a general feature description. For evaluation, we trained and tested the proposed architecture on 3DUS images of the liver and prostate of five different subjects and assessed the similarity between the decoded patches and the original ones. Subject-and organ-specific as well as general AEs are trained and evaluated. Specific AEs could reconstruct patches with a mean Normalized Cross Correlation of 0.85 and 0.81 at maximum in liver and prostate, respectively. It can also be shown that the AEs are transferable across subjects and organs, with a small accuracy decrease to 0.83 and 0.81 (liver, prostate) for general AEs. In addition, a first tracking study was performed to show feasibility of tracking in latent space. In this work, we could show that it is possible to train an AE that is transferable across two target regions and several subjects. Hence, convolutional AEs present a promising approach for creating a general feature extractor for 3DUS.

Published

2020

10. Simultaneous acquisition of 4D ultrasound and wireless electromagnetic tracking for in-vivo accuracy validation

Author

Svenja Ipsen, Esben S. Worm, Morten Høyer, Achim Schweikard, Rune Hansen, Ralf Bruder, and Per Rugaard Poulsen

Subjects

Computer science, Image guidance, Biomedical Engineering, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, In vivo, Wireless, Computer vision, image guidance, Electromagnetic tracking, radiotherapy, liver sbrt, Motion compensation, Radiotherapy, business.industry, motion compensation, 030220 oncology & carcinogenesis, Medicine, 4D ultrasound tracking, Liver SBRT, 4d ultrasound tracking, Artificial intelligence, business, 4d ultrasound

Abstract

Ultrasound is being increasingly investigated for real-time target localization in image-guided interventions. Yet, in-vivo validation remains challenging due to the difficulty to obtain a reliable ground truth. For this purpose, real-time volumetric (4D) ultrasound imaging was performed simultaneously with electromagnetic localization of three wireless transponders implanted in the liver of a radiotherapy patient. 4D ultrasound and electromagnetic tracking were acquired at framerates of 12Hz and 8Hz, respectively, during free breathing over 8 min following treatment. The electromagnetic antenna was placed directly above and the ultrasound probe on the right side of the patient to visualize the liver transponders. It was possible to record 25.7 s of overlapping ultrasound and electromagnetic position data of one transponder. Good spatial alignment with 0.6 mm 3D root-mean-square error between both traces was achieved using a rigid landmark transform. However, data acquisition was impaired since the electromagnetic tracking highly influenced the ultrasound equipment and vice versa. High intensity noise streaks appeared in the ultrasound scan lines irrespective of the chosen frequency (1.7-3.3 MHz, 2/4 MHz harmonic). To allow for target visualization and tracking in the ultrasound volumes despite the artefacts, an online filter was designed where corrupted pixels in the newest ultrasound frame were replaced with non-corrupted pixels from preceding frames. Aside from these artefacts, the recorded electromagnetic tracking data was fragmented and only the transponder closest to the antenna could be detected over a limited period of six consecutive breathing cycles. This problem was most likely caused by interference from the metal holder of the ultrasound probe and was solved in a subsequent experiment using a 3D-printed non-metal probe fixation. Real-time wireless electromagnetic tracking was compared with 4D ultrasound imaging in-vivo for the first time. For stable tracking, large metal components need to be avoided during data acquisition and ultrasound filtering is required.

Published

2017

11. Towards automated ultrasound imaging—robotic image acquisition in liver and prostate for long-term motion monitoring

Author

Ivo Kuhlemann, Achim Schweikard, Daniel Wulff, Svenja Ipsen, and Floris Ernst

Subjects

Male, Motion analysis, Computer science, 030218 nuclear medicine & medical imaging, Contact force, Motion, 03 medical and health sciences, 0302 clinical medicine, Organ Motion, Robotic Surgical Procedures, Match moving, Humans, Radiology, Nuclear Medicine and imaging, Ultrasonography, Landmark, Radiological and Ultrasound Technology, business.industry, Ultrasound, Prostate, Robotics, Liver, Impedance control, 030220 oncology & carcinogenesis, Artificial intelligence, business, Biomedical engineering

Abstract

Real-time volumetric (4D) ultrasound has shown high potential for diagnostic and therapy guidance tasks. One of the main drawbacks of ultrasound imaging to date is the reliance on manual probe positioning and the resulting user dependence. Robotic assistance could help overcome this issue and facilitate the acquisition of long-term image data to observe dynamic processes in vivo over time. The aim of this study is to assess the feasibility of robotic probe manipulation and organ motion quantification during extended imaging sessions. The system consists of a collaborative robot and a 4D ultrasound system providing real-time data access. Five healthy volunteers received liver and prostate scans during free breathing over 30 min. Initial probe placement was performed with real-time remote control with a predefined contact force of 10 N. During scan acquisition, the probe position was continuously adjusted to the body surface motion using impedance control. Ultrasound volumes, the pose of the end-effector and the estimated contact forces were recorded. For motion analysis, one anatomical landmark was manually annotated in a subset of ultrasound frames for each experiment. Probe contact was uninterrupted over the entire scan duration in all ten sessions. Organ drift and imaging artefacts were successfully compensated using remote control. The median contact force along the probe’s longitudinal axis was 10.0 N with maximum values of 13.2 and 21.3 N for liver and prostate, respectively. Forces exceeding 11 N only occurred in 0.3% of the time. Probe and landmark motion were more pronounced in the liver, with median interquartile ranges of 1.5 and 9.6 mm, compared to 0.6 and 2.7 mm in the prostate. The results show that robotic ultrasound imaging with dynamic force control can be used for stable, long-term imaging of anatomical regions affected by motion. The system facilitates the acquisition of 4D image data in vivo over extended scanning periods for the first time and holds the potential to be used for motion monitoring for therapy guidance as well as diagnostic tasks.

Published

2021

12. Online 4D ultrasound guidance for real-time motion compensation by MLC tracking

Author

Rick O’Brien, Paul J. Keall, Ralf Bruder, Svenja Ipsen, Per Rugaard Poulsen, and Achim Schweikard

Subjects

Computer science, Aperture, medicine.medical_treatment, Radiotherapy image guided, Dose profile, Tracking (particle physics), Scintigraphy, Imaging phantom, 030218 nuclear medicine & medical imaging, Ionizing radiation, 03 medical and health sciences, 0302 clinical medicine, Prostate, medicine, Dosimetry, Motion compensation, Dosimeter, medicine.diagnostic_test, business.industry, Ultrasound, Cancer, Tracking system, General Medicine, medicine.disease, Radiation therapy, Multileaf collimator, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Ultrasound imaging, Ultrasonography, business, Nuclear medicine, 4d ultrasound, Biomedical engineering

Abstract

Purpose: With the trend in radiotherapy moving toward dose escalation and hypofractionation, the need for highly accurate targeting increases. While MLC tracking is already being successfully used for motion compensation of moving targets in the prostate, current real-time target localization methods rely on repeated x-ray imaging and implanted fiducial markers or electromagnetic transponders rather than direct target visualization. In contrast, ultrasound imaging can yield volumetric data in real-time (3D + time = 4D) without ionizing radiation. The authors report the first results of combining these promising techniques—online 4D ultrasound guidance and MLC tracking—in a phantom. Methods: A software framework for real-time target localization was installed directly on a 4D ultrasound station and used to detect a 2 mm spherical lead marker inside a water tank. The lead marker was rigidly attached to a motion stage programmed to reproduce nine characteristic tumor trajectories chosen from large databases (five prostate, four lung). The 3D marker position detected by ultrasound was transferred to a computer program for MLC tracking at a rate of 21.3 Hz and used for real-time MLC aperture adaption on a conventional linear accelerator. The tracking system latency was measured using sinusoidal trajectories and compensated for by applying a kernel density prediction algorithm for the lung traces. To measure geometric accuracy, static anterior and lateral conformal fields as well as a 358° arc with a 10 cm circular aperture were delivered for each trajectory. The two-dimensional (2D) geometric tracking error was measured as the difference between marker position and MLC aperture center in continuously acquired portal images. For dosimetric evaluation, VMAT treatment plans with high and low modulation were delivered to a biplanar diode array dosimeter using the same trajectories. Dose measurements with and without MLC tracking were compared to a static reference dose using 3%/3 mm and 2%/2 mm γ-tests. Results: The overall tracking system latency was 172 ms. The mean 2D root-mean-square tracking error was 1.03 mm (0.80 mm prostate, 1.31 mm lung). MLC tracking improved the dose delivery in all cases with an overall reduction in the γ-failure rate of 91.2% (3%/3 mm) and 89.9% (2%/2 mm) compared to no motion compensation. Low modulation VMAT plans had no (3%/3 mm) or minimal (2%/2 mm) residual γ-failures while tracking reduced the γ-failure rate from 17.4% to 2.8% (3%/3 mm) and from 33.9% to 6.5% (2%/2 mm) for plans with high modulation. Conclusions: Real-time 4D ultrasound tracking was successfully integrated with online MLC tracking for the first time. The developed framework showed an accuracy and latency comparable with other MLC tracking methods while holding the potential to measure and adapt to target motion, including rotation and deformation, noninvasively.

Published

2016

13. An improved tracking framework for ultrasound probe localization in image-guided radiosurgery

Author

Svenja Ipsen, Philipp Jauer, Floris Ernst, Oliver Blanck, Achim Schweikard, and Ralf Bruder

Subjects

medicine.medical_specialty, robotic radiosurgery, Image guided radiosurgery, Computer science, Biomedical Engineering, Tracking (particle physics), 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Ultrasound probe, ultrasound tracking, 030220 oncology & carcinogenesis, medicine, Robotic radiosurgery, real-time motion compensation, Medicine, Medical physics, image guidance, Image guidance

Abstract

Real-time target localization with ultrasound holds high potential for image guidance and motion compensation in radiosurgery due to its non-invasive image acquisition free from ionizing radiation. However, a two-step localization has to be performed when integrating ultrasound into the existing radiosurgery workflow. In addition to target localization inside the ultrasound volume, the probe itself has to be localized in order to transform the target position into treatment room coordinates. By adapting existing camera calibration tools, we have developed a method to extend the stereoscopic X-ray tracking system of a radiosurgery platform in order to locate objects such as marker geometries with six degrees of freedom. The calibration was performed with 0.1 mm reprojection error. By using the full area of the flat-panel detectors without pre-processing the extended software increased the tracking volume and resolution by up to 80%, substantially improving patient localization and marker detectability. Furthermore, marker-tracking showed sub-millimeter accuracy and rotational errors below 0.1°. This demonstrates that the developed extension framework can accurately localize marker geometries using an integrated X-ray system, establishing the link for the integration of real-time ultrasound image guidance into the existing system.

Published

2016

14. Robotic 4D ultrasound solution for real-time visualization and teleoperation

Author

Sven Böttger, Mohammed Al-Badri, Svenja Ipsen, and Floris Ernst

Subjects

Real time visualization, Telemedicine, business.industry, Computer science, Ultrasound, Teleoperation, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Biomedical Engineering, Computer vision, Artificial intelligence, business, 4d ultrasound

Abstract

Automation of the image acquisition process via robotic solutions offer a large leap towards resolving ultrasound’s user-dependency. This paper, as part of a larger project aimed to develop a multipurpose 4d-ultrasonic force-sensitive robot for medical applications, focuses on achieving real-time remote visualisation for 4d ultrasound image transfer. This was possible through implementing our software modification on a GE Vivid 7 Dimension workstation, which operates a matrix array probe controlled by a KUKA LBR iiwa 7 7-DOF robotic arm. With the help of robotic positioning and the matrix array probe, fast volumetric imaging of target regions was feasible. By testing ultrasound volumes, which were roughly 880 kB in size, while using gigabit Ethernet connection, a latency of ∼57 ms was achievable for volume transfer between the ultrasound station and a remote client application, which as a result allows a frame count of 17.4 fps. Our modification thus offers for the first time real-time remote visualization, recording and control of 4d ultrasound data, which can be implemented in teleoperation.

Published

2017

15. A visual probe positioning tool for 4D ultrasound-guided radiotherapy

Author

Ralf Bruder, Svenja Ipsen, Ivo Kuhlemann, Floris Ernst, Achim Schweikard, Laura Motisi, Philipp Jauer, and F. Cremers

Subjects

Computer science, medicine.medical_treatment, Computed tomography, 030218 nuclear medicine & medical imaging, Motion, 03 medical and health sciences, Imaging, Three-Dimensional, 0302 clinical medicine, Calibration, medicine, Computer vision, Ultrasonography, Motion compensation, medicine.diagnostic_test, business.industry, Ultrasound, Reproducibility of Results, Window (computing), Visualization, Visual probe, Radiation therapy, 030220 oncology & carcinogenesis, Artificial intelligence, business, 4d ultrasound, Radiotherapy, Image-Guided

Abstract

Ultrasound (US) guidance is a rapidly growing area in image-guided radiotherapy. For motion compensation, the therapy target needs to be visualized with the US probe to continuously determine its position and adapt for shifts. While US has obvious benefits such as real-time capability and proven safety, one of the main drawbacks to date is its user dependency - high quality results require long years of clinical experience. To provide positioning assistance for the setup of US equipment by non-experts, we developed a visual guidance tool combining real-time US volume and CT visualization in a geometrically calibrated setup. By using a 4D US station with real-time data access and an optical tracking system, we achieved a calibration accuracy of 1.2 mm and a mean 2D contour distance of 1.7 mm between organ boundaries identified in US and CT. With this low calibration error as well as the good visual alignment of the structures, the developed probe positioning tool could be a valuable aid for ultrasound-guided radiotherapy and other interventions by guiding the user to a suitable acoustic window while potentially improving setup reproducibility.

Published

2018

16. Investigation of the XCAT phantom as a validation tool in cardiac MRI tracking algorithms

Author

Paul J. Keall, Oliver Blanck, N. Lowther, Svenja Ipsen, and S. H. Marsh

Subjects

Time Factors, Computer science, Biophysics, General Physics and Astronomy, Radiosurgery, Tracking (particle physics), Signal, Imaging phantom, 030218 nuclear medicine & medical imaging, 029903 - Medical Physics [FoR], Breath Holding, Tracking error, Motion, 03 medical and health sciences, 0302 clinical medicine, Heart Rate, medicine, Humans, Computer Simulation, Radiology, Nuclear Medicine and imaging, Euclidean vector, real-time imaging, medicine.diagnostic_test, Phantoms, Imaging, Respiration, Heart, Magnetic resonance imaging, General Medicine, Torso, Magnetic Resonance Imaging, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Algorithm design, Algorithm, Algorithms, Software, Radiotherapy, Image-Guided, MRI

Abstract

Purpose To describe our magnetic resonance imaging (MRI) simulated implementation of the 4D digital extended cardio torso (XCAT) phantom to validate our previously developed cardiac tracking techniques. Real-time tracking will play an important role in the non-invasive treatment of atrial fibrillation with MRI-guided radiosurgery. In addition, to show how quantifiable measures of tracking accuracy and patient-specific physiology could influence MRI tracking algorithm design. Methods Twenty virtual patients were subjected to simulated MRI scans that closely model the proposed real-world scenario to allow verification of the tracking technique’s algorithm. The generated phantoms provide ground-truth motions which were compared to the target motions output from our tracking algorithm. The patient-specific tracking error, ep, was the 3D difference (vector length) between the ground-truth and algorithm trajectories. The tracking errors of two combinations of new tracking algorithm functions that were anticipated to improve tracking accuracy were studied. Additionally, the correlation of key physiological parameters with tracking accuracy was investigated. Results Our original cardiac tracking algorithm resulted in a mean tracking error of 3.7 ± 0.6 mm over all virtual patients. The two combinations of tracking functions demonstrated comparable mean tracking errors however indicating that the optimal tracking algorithm may be patient-specific. Conclusions Current and future MRI tracking strategies are likely to benefit from this virtual validation method since no time-resolved 4D ground-truth signal can currently be derived from purely image-based studies.

Published

2018

17. Poster session 4. Image guided, robotic and miniaturised systems for intervention and therapy I

Author

Svenja Ipsen, Floris Ernst, Mohammed Al-Badri, Sven Böttger, and Achim Schweikard

Subjects

medicine.medical_specialty, Computer science, Intervention (counseling), Biomedical Engineering, Physical therapy, medicine, Medical physics, Session (computer science)

Published

2017

18. Towards real-time MRI-guided 3D localization of deforming targets for non-invasive cardiac radiosurgery

Author

Oliver Blanck, Juergen Dunst, Robba Rai, Frank Bode, Svenja Ipsen, Achim Schweikard, Paul J. Keall, N. Lowther, and Gary P Liney

Subjects

Male, medicine.medical_treatment, cardiac radiosurgery, Radiosurgery, Imaging phantom, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, Motion, 0302 clinical medicine, Imaging, Three-Dimensional, Magnetic resonance imaging, Atrial Fibrillation, medicine, Humans, Radiology, Nuclear Medicine and imaging, Mathematics, Retrospective Studies, Motion compensation, Radiological and Ultrasound Technology, medicine.diagnostic_test, Cardiac cycle, business.industry, Phantoms, Imaging, Template matching, Respiration, Heart, Real-time MRI, Magnetic Resonance Imaging, Myocardial Contraction, Sagittal plane, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Nuclear medicine, business, Algorithms

Abstract

Radiosurgery to the pulmonary vein antrum in the left atrium (LA) has recently been proposed for non-invasive treatment of atrial fibrillation (AF). Precise real-time target localization during treatment is necessary due to complex respiratory and cardiac motion and high radiation doses. To determine the 3D position of the LA for motion compensation during radiosurgery, a tracking method based on orthogonal real-time MRI planes was developed for AF treatments with an MRI-guided radiotherapy system. Four healthy volunteers underwent cardiac MRI of the LA. Contractile motion was quantified on 3D LA models derived from 4D scans with 10 phases acquired in end-exhalation. Three localization strategies were developed and tested retrospectively on 2D real-time scans (sagittal, temporal resolution 100 ms, free breathing). The best-performing method was then used to measure 3D target positions in 2D-2D orthogonal planes (sagittal-coronal, temporal resolution 200-252 ms, free breathing) in 20 configurations of a digital phantom and in the volunteer data. The 3D target localization accuracy was quantified in the phantom and qualitatively assessed in the real data. Mean cardiac contraction was ⩽ 3.9 mm between maximum dilation and contraction but anisotropic. A template matching approach with two distinct template phases and ECG-based selection yielded the highest 2D accuracy of 1.2 mm. 3D target localization showed a mean error of 3.2 mm in the customized digital phantoms. Our algorithms were successfully applied to the 2D-2D volunteer data in which we measured a mean 3D LA motion extent of 16.5 mm (SI), 5.8 mm (AP) and 3.1 mm (LR). Real-time target localization on orthogonal MRI planes was successfully implemented for highly deformable targets treated in cardiac radiosurgery. The developed method measures target shifts caused by respiration and cardiac contraction. If the detected motion can be compensated accordingly, an MRI-guided radiotherapy system could potentially enable completely non-invasive treatment of AF.

Published

2016

19. Online 4D ultrasound guidance for real-time motion compensation by MLC tracking

Author

Svenja, Ipsen, Ralf, Bruder, Rick, O'Brien, Paul J, Keall, Achim, Schweikard, and Per R, Poulsen

Subjects

Imaging, Three-Dimensional, Time Factors, Movement, Radiotherapy Planning, Computer-Assisted, Feasibility Studies, Humans, Radiometry, Radiotherapy, Image-Guided, Ultrasonography

Abstract

With the trend in radiotherapy moving toward dose escalation and hypofractionation, the need for highly accurate targeting increases. While MLC tracking is already being successfully used for motion compensation of moving targets in the prostate, current real-time target localization methods rely on repeated x-ray imaging and implanted fiducial markers or electromagnetic transponders rather than direct target visualization. In contrast, ultrasound imaging can yield volumetric data in real-time (3D + time = 4D) without ionizing radiation. The authors report the first results of combining these promising techniques-online 4D ultrasound guidance and MLC tracking-in a phantom.A software framework for real-time target localization was installed directly on a 4D ultrasound station and used to detect a 2 mm spherical lead marker inside a water tank. The lead marker was rigidly attached to a motion stage programmed to reproduce nine characteristic tumor trajectories chosen from large databases (five prostate, four lung). The 3D marker position detected by ultrasound was transferred to a computer program for MLC tracking at a rate of 21.3 Hz and used for real-time MLC aperture adaption on a conventional linear accelerator. The tracking system latency was measured using sinusoidal trajectories and compensated for by applying a kernel density prediction algorithm for the lung traces. To measure geometric accuracy, static anterior and lateral conformal fields as well as a 358° arc with a 10 cm circular aperture were delivered for each trajectory. The two-dimensional (2D) geometric tracking error was measured as the difference between marker position and MLC aperture center in continuously acquired portal images. For dosimetric evaluation, VMAT treatment plans with high and low modulation were delivered to a biplanar diode array dosimeter using the same trajectories. Dose measurements with and without MLC tracking were compared to a static reference dose using 3%/3 mm and 2%/2 mm γ-tests.The overall tracking system latency was 172 ms. The mean 2D root-mean-square tracking error was 1.03 mm (0.80 mm prostate, 1.31 mm lung). MLC tracking improved the dose delivery in all cases with an overall reduction in the γ-failure rate of 91.2% (3%/3 mm) and 89.9% (2%/2 mm) compared to no motion compensation. Low modulation VMAT plans had no (3%/3 mm) or minimal (2%/2 mm) residual γ-failures while tracking reduced the γ-failure rate from 17.4% to 2.8% (3%/3 mm) and from 33.9% to 6.5% (2%/2 mm) for plans with high modulation.Real-time 4D ultrasound tracking was successfully integrated with online MLC tracking for the first time. The developed framework showed an accuracy and latency comparable with other MLC tracking methods while holding the potential to measure and adapt to target motion, including rotation and deformation, noninvasively.

Published

2016

20. Treatment Planning Considerations for Robotic Guided Cardiac Radiosurgery for Atrial Fibrillation

Author

Dirk Rades, Ralf Bruder, Matthias Kerl, Thomas J. Vogl, Ralf W. Bauer, Peter Hunold, Jürgen Dunst, Oliver Blanck, Volkmar Jacobi, Svenja Ipsen, Mark K. H. Chan, Frank Bode, Achim Schweikard, and Peter Kleine

Subjects

medicine.medical_specialty, treatment planning, Medical Physics, Stereotactic body radiation therapy, medicine.medical_treatment, Cardiology, stereotactic body radiation therapy, Radiosurgery, dose rate optimization, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Medicine, Medical physics, atrial fibrillation, Radiation treatment planning, pulmonary vein isolation, business.industry, General Engineering, Atrial fibrillation, medicine.disease, 4d dose calculation, cyberknife cardiac radiosurgery, 030220 oncology & carcinogenesis, Radiation Oncology, Radiology, business

Abstract

Purpose Robotic guided stereotactic radiosurgery has recently been investigated for the treatment of atrial fibrillation (AF). Before moving into human treatments, multiple implications for treatment planning given a potential target tracking approach have to be considered. Materials & Methods Theoretical AF radiosurgery treatment plans for twenty-four patients were generated for baseline comparison. Eighteen patients were investigated under ideal tracking conditions, twelve patients under regional dose rate (RDR = applied dose over a certain time window) optimized conditions (beam delivery sequence sorting according to regional beam targeting), four patients under ultrasound tracking conditions (beam block of the ultrasound probe) and four patients with temporary single fiducial tracking conditions (differential surrogate-to-target respiratory and cardiac motion). Results With currently known guidelines on dose limitations of critical structures, treatment planning for AF radiosurgery with 25 Gy under ideal tracking conditions with a 3 mm safety margin may only be feasible in less than 40% of the patients due to the unfavorable esophagus and bronchial tree location relative to the left atrial antrum (target area). Beam delivery sequence sorting showed a large increase in RDR coverage (% of voxels having a larger dose rate for a given time window) of 10.8-92.4% (median, 38.0%) for a 40-50 min time window, which may be significant for non-malignant targets. For ultrasound tracking, blocking beams through the ultrasound probe was found to have no visible impact on plan quality given previous optimal ultrasound window estimation for the planning CT. For fiducial tracking in the right atrial septum, the differential motion may reduce target coverage by up to -24.9% which could be reduced to a median of -0.8% (maximum, -12.0%) by using 4D dose optimization. The cardiac motion was also found to have an impact on the dose distribution, at the anterior left atrial wall; however, the results need to be verified. Conclusion Robotic AF radiosurgery with 25 Gy may be feasible in a subgroup of patients under ideal tracking conditions. Ultrasound tracking was found to have the lowest impact on treatment planning and given its real-time imaging capability should be considered for AF robotic radiosurgery. Nevertheless, advanced treatment planning using RDR or 4D respiratory and cardiac dose optimization may be still advised despite using ideal tracking methods.

Published

2016

21. Investigating multi-leaf collimator tracking in stereotactic arrhythmic radioablation (STAR) treatments for atrial fibrillation

Author

Svenja Ipsen, Per Rugaard Poulsen, Paul J. Keall, Suzanne Lydiard, Ricky O'Brien, Vincent Caillet, Jeremy T. Booth, and Oliver Blanck

Subjects

Ablation Techniques, Time Factors, Movement, chemical and pharmacologic phenomena, macromolecular substances, Tracking (particle physics), Intracardiac injection, 029903 - Medical Physics [FoR], 030218 nuclear medicine & medical imaging, law.invention, 03 medical and health sciences, 0302 clinical medicine, law, Cardiac motion, Atrial Fibrillation, medicine, Humans, Radiology, Nuclear Medicine and imaging, Motion compensation, Radiological and Ultrasound Technology, business.industry, Radiotherapy Planning, Computer-Assisted, Radioablation, Radiotherapy Dosage, Collimator, Atrial fibrillation, Multi leaf collimator, medicine.disease, Target dose, 030220 oncology & carcinogenesis, Particle Accelerators, Nuclear medicine, business

Abstract

Stereotactic arrhythmia radioablation (STAR) is an emerging treatment option for atrial fibrillation (AF). However, it faces possibly the most challenging motion compensation scenario: both respiratory and cardiac motion. Multi-leaf collimator (MLC) tracking is clinically used for lung cancer treatments but its capabilities with intracardiac targets is unknown. We report the first experimental results of MLC tracking for intracardiac targets. Five AF STAR plans of varying complexity were created. All delivered 5 × 10 Gy to both pulmonary vein antra. Three healthy human target motion trajectories were acquired with ultrasound and programmed into a motion platform. Plans were delivered with a linac to a dosimeter placed on the motion platform. For each motion trace, each plan was delivered with no MLC tracking and with MLC tracking with and without motion prediction. Dosimetric accuracy was assessed with γ-tests and dose metrics. MLC tracking improved the dosimetric accuracy in all measurements compared to non-tracking experiments. The average 2%/2 mm γ-failure rate was improved from 13.1% with no MLC tracking to 5.9% with MLC tracking (p

Published

2018

22. [I094] Ultrasound guidance in radiotherapy - renaissance through innovation

Author

Svenja Ipsen

Subjects

Motion compensation, Modality (human–computer interaction), medicine.diagnostic_test, business.industry, Computer science, Image quality, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Biophysics, General Physics and Astronomy, Image processing, General Medicine, Visualization, Software, medicine, Radiology, Nuclear Medicine and imaging, Computer vision, Augmented reality, 3D ultrasound, Artificial intelligence, business

Abstract

Ultrasound imaging has been used for motion compensation in radiotherapy since the late 1990s. It does not utilize ionizing radiation and can provide real-time visualization and localization at a low cost. Early systems relied on freehand 2D imaging and facilitated soft-tissue image guidance in radiotherapy for the first time. However, they suffered from strong user dependency and limited positioning accuracy, slowing their widespread utilization. Many of their drawbacks were overcome when 3D ultrasound was introduced. 3D imaging is now commonly used for prostate treatment setup and under investigation for other sites. Innovations in hard- and software have led to the latest generation of ultrasound systems which can provide extremely high volumetric framerates with superior image quality by using matrix array transducers. Due to the large field-of-view and the high spatiotemporal resolution, these new systems are ideally suited for real-time motion compensation tasks. By accessing the volume data directly, it has now become possible to implement fast image processing for target detection. This information can then be used for gating the treatment beam or dynamic tracking techniques such as MLC or robotic systems to follow tumor motion with low latency and good dosimetric results. To aid less experienced, non-expert users with the setup, tools have been developed to calculate the ideal probe position and guide the user through the anatomy with real-time visual feedback, potentially further aided by augmented reality applications in the future. Furthermore, robotic solutions for probe positioning and stabilization are currently being investigated in order to eliminate user dependency, one of the biggest challenges in ultrasound imaging to date. Recent developments in technology have facilitated such new approaches and helped overcome some of the previous drawbacks. The evident benefits of ultrasound imaging make it a promising modality for real-time motion compensation in radiotherapy of soft tissues.

Published

2018

23. TH-AB-202-05: BEST IN PHYSICS (JOINT IMAGING-THERAPY): First Online Ultrasound-Guided MLC Tracking for Real-Time Motion Compensation in Radiotherapy

Author

Svenja Ipsen, Paul J. Keall, Achim Schweikard, Ralf Bruder, Per Rugaard Poulsen, and Ricky O'Brien

Subjects

Physics, Motion compensation, business.industry, Dose profile, Tracking system, General Medicine, Tracking (particle physics), Frame rate, Imaging phantom, Tracking error, Dosimetry, business, Nuclear medicine, Biomedical engineering

Abstract

Purpose: While MLC tracking has been successfully used for motion compensation of moving targets, current real-time target localization methods rely on correlation models with x-ray imaging or implanted electromagnetic transponders rather than direct target visualization. In contrast, ultrasound imaging yields volumetric data in real-time (4D) without ionizing radiation. We report the first results of online 4D ultrasound-guided MLC tracking in a phantom. Methods: A real-time tracking framework was installed on a 4D ultrasound station (Vivid7 dimension, GE) and used to detect a 2mm spherical lead marker inside a water tank. The volumetric frame rate was 21.3Hz (47ms). The marker was rigidly attached to a motion stage programmed to reproduce nine tumor trajectories (five prostate, four lung). The 3D marker position from ultrasound was used for real-time MLC aperture adaption. The tracking system latency was measured and compensated by prediction for lung trajectories. To measure geometric accuracy, anterior and lateral conformal fields with 10cm circular aperture were delivered for each trajectory. The tracking error was measured as the difference between marker position and MLC aperture in continuous portal imaging. For dosimetric evaluation, 358° VMAT fields were delivered to a biplanar diode array dosimeter using the same trajectories. Dose measurements with and without MLC tracking were compared to a static reference dose using a 3%/3 mm γ-test. Results: The tracking system latency was 170ms. The mean root-mean-square tracking error was 1.01mm (0.75mm prostate, 1.33mm lung). Tracking reduced the mean γ-failure rate from 13.9% to 4.6% for prostate and from 21.8% to 0.6% for lung with high-modulation VMAT plans and from 5% (prostate) and 18% (lung) to 0% with low modulation. Conclusion: Real-time ultrasound tracking was successfully integrated with MLC tracking for the first time and showed similar accuracy and latency as other methods while holding the potential to measure target motion non-invasively. SI was supported by the Graduate School for Computing in Medicine and Life Science, German Excellence Initiative [grant DFG GSC 235/1].

Published

2016

24. Radiotherapy beyond cancer: Target localization in real-time MRI and treatment planning for cardiac radiosurgery

Author

Svenja Ipsen, Gary P Liney, Paul J. Keall, Bradley M Oborn, Achim Schweikard, Frank Bode, Oliver Blanck, Dirk Rades, and Peter Hunold

Subjects

medicine.medical_specialty, medicine.diagnostic_test, business.industry, medicine.medical_treatment, Cardiac arrhythmia, Catheter ablation, Magnetic resonance imaging, General Medicine, Real-time MRI, Radiosurgery, Cardiac magnetic resonance imaging, Medical imaging, medicine, Radiology, Radiation treatment planning, business, Nuclear medicine

Abstract

Purpose: Atrial fibrillation (AFib) is the most common cardiac arrhythmia that affects millions of patients world-wide. AFib is usually treated with minimally invasive, time consuming catheter ablation techniques. While recently noninvasive radiosurgery to the pulmonary vein antrum (PVA) in the left atrium has been proposed for AFib treatment, precise target location during treatment is challenging due to complex respiratory and cardiac motion. A MRI linear accelerator (MRI-Linac) could solve the problems of motion tracking and compensation using real-time image guidance. In this study, the authors quantified target motion ranges on cardiac magnetic resonance imaging (MRI) and analyzed the dosimetric benefits of margin reduction assuming real-time motion compensation was applied. Methods: For the imaging study, six human subjects underwent real-time cardiac MRI under free breathing. The target motion was analyzed retrospectively using a template matching algorithm. The planning study was conducted on a CT of an AFib patient with a centrally located esophagus undergoing catheter ablation, representing an ideal case for cardiac radiosurgery. The target definition was similar to the ablation lesions at the PVA created during catheter treatment. Safety margins of 0 mm (perfect tracking) to 8 mm (untracked respiratory motion) were added to the target, defining the planning target volume (PTV). For each margin, a 30 Gy single fraction IMRT plan was generated. Additionally, the influence of 1 and 3 T magnetic fields on the treatment beam delivery was simulated using Monte Carlo calculations to determine the dosimetric impact of MRI guidance for two different Linac positions. Results: Real-time cardiac MRI showed mean respiratory target motion of 10.2 mm (superior–inferior), 2.4 mm (anterior–posterior), and 2 mm (left–right). The planning study showed that increasing safety margins to encompass untracked respiratory motion leads to overlapping structures even in the ideal scenario, compromising either normal tissue dose constraints or PTV coverage. The magnetic field caused a slight increase in the PTV dose with the in-line MRI-Linac configuration. Conclusions: The authors’ results indicate that real-time tracking and motion compensation are mandatory for cardiac radiosurgery and MRI-guidance is feasible, opening the possibility of treating cardiac arrhythmia patients completely noninvasively.

Published

2014

25. MO-A-BRD-08: Radiosurgery Beyond Cancer: Real-Time Target Localization and Treatment Planning for Cardiac Radiosurgery Under MRI Guidance

Author

Svenja Ipsen, Paul J. Keall, Gary P Liney, B Oborn, Oliver Blanck, and Frank Bode

Subjects

medicine.diagnostic_test, business.industry, medicine.medical_treatment, Cardiac arrhythmia, Magnetic resonance imaging, Catheter ablation, General Medicine, Ablation, Radiosurgery, Radiation therapy, Coronal plane, Medicine, business, Radiation treatment planning, Nuclear medicine

Abstract

Purpose: Atrial fibrillation (AF) is the most common cardiac arrhythmia, affecting >2.5M Americans and >4.5M Europeans. AF is usually treated with minimally-invasive, time consuming catheter ablation techniques. Radiosurgery of the pulmonary veins (PV) has been proposed for AF treatment, however is challenging due to the complex respiratory and cardiac motion patterns. We hypothesize that an MRI-linac could solve the difficult real-time targeting and adaptation problem. In this study we quantified target motion ranges on cardiac MRI and analyzed the dosimetric benefits of margin reduction assuming real-time MRI tracking was applied. Methods: For the motion study, four human subjects underwent real-time cardiac MRI under free breathing. The target motion on coronal and axial cine planes was analyzed using a template matching algorithm. For the planning study, an ablation line at each PV antrum was defined as target on an AF patient scheduled for catheter ablation. Various safety margins ranging from 0mm (perfect tracking) to 8mm (untracked motion) were added to the target defining the PTV. 30Gy single fraction IMRT plans were then generated. Finally, the influence of a 1T magnetic field on treatment beam delivery was calculated using the Geant4 Monte Carlo algorithm to simulate the dosimetric impact of MRI guidance. Results: The motion study showed the mean respiratory motion of the target area on MRI was 8.4mm (SI), 1.7mm (AP) and 0.3mm (LR). Cardiac motion was small ( 100%. The magnetic field had little impact on the dose distribution. Conclusion: Our results indicate that real-time MRI tracking of the PVs seems feasible. Accurate image guidance for high-dose AF radiosurgery is essential since safety margins covering untracked target motion will result in unacceptable treatment plans.

Published

2014

26. MO-D-144-02: Ultrasound Transducer Localization Using the CyberKnife's X-Ray System

Author

Oliver Blanck, Svenja Ipsen, Ralf Bruder, Philipp Jauer, Floris Ernst, and Achim Schweikard

Subjects

Physics, Motion compensation, business.industry, Ultrasound, General Medicine, Transducer, Medical imaging, Calibration, Ultrasonic sensor, Fiducial marker, business, Nuclear medicine, Stereo camera, Biomedical engineering

Abstract

Purpose: 4D ultrasound has become an alternative for image guidance and motion compensation in radiosurgery. Nevertheless, a two‐step localization has to be performed when using ultrasound. In addition to target localization inside the ultrasound volume, the transducer itself has to be localized and the target position has to be transformed into treatment coordinates. Methods: The CyberKnife (Accuray Inc.) features a stereo X‐ray system which is used for patient and fiducial marker localization. Accessing only the raw X‐ray images, we designed a software package for additional marker detection. To measure the physical camera parameters, X‐ray phantoms were designed and a non‐orthogonal stereo camera calibration was performed on 50 calibration X‐ray pairs. Algorithms were developed for three‐dimensional single marker localization and six‐dimensional localization of marker geometries. Different X‐ray marker geometries were designed and attached to the ultrasound transducer. The final system was evaluated and compared to the on‐board localization system using a 6‐axis industrial robot to position different marker geometries at 150 randomly distributed positions over the acquisition volume. Results: Two marker geometries with 20 and 50mm base lengths were localized using the on‐board and newly developed software. The mean translational error for the on‐board localization is 0.202mm, for the new system 0.218mm. The rotational error of the on‐board system could be reduced from 0.212 to 0.053 degrees for the 50mm marker and from 0.272 to 0.076 degrees for the 20mm marker geometry. Conclusion: We have shown that ultrasound transducers can be localized using the CyberKnife x‐ray system. The rotational accuracy of the localization could be increased by a factor of four, which is important for high marker‐to‐ultrasound‐target distances. Furthermore, using the full area of the flat‐panel detectors without pre‐processing steps the tracking volume was increased by 70 percent, which helps detecting patient/fiducials and transducer at the same time.

Published

2013