Your search keyword '"Celicanin, Z."' showing total 19 results

1. EP-1944 Automated respiratory cycle binning for liver 4D-MR imaging

Author

L'Homel, B., Parent, L., Bieri, O., Celicanin, Z., Cattin, P., and Ken, S.

Published

2019

2. 47 Automated respiratory cycle binning for liver 4D-MR imaging

Author

L’homel, B., Parent, L., Bieri, O., Celicanin, Z., Cattin, P., and Ken, S.

Published

2018

3. EP-2190: Quantitative evaluation of a new 4D MRI sequence: a motion phantom study

Author

Parent, L., Nemtanu, T., Celicanin, Z., Bieri, O., Cattin, P., and Ken, S.

Published

2018

4. EP-2078: Experimental validation of a synthetic 4DCT-MRI approach using an anthropomorphic breathing phantom

Author

Krieger, M., Klucznik, K., Emma, C., Peroni, M., Bieri, O., Celicanin, Z., Weber, D.C., Lomax, A.J., and Zhang, Y.

Published

2018

5. EP-1966: Motion management in RT planning: 4D-MRI retrospective automatic sorting based on internal surrogate

Author

Ken, S., Celicanin, Z., Bieri, O., Cattin, P., and Parent, L.

Published

2018

6. 47 Automated respiratory cycle binning for liver 4D-MR imaging.

Author

L'homel, B., Parent, L., Bieri, O., Celicanin, Z., Cattin, P., and Ken, S.

Abstract

Introduction Stereotactic body radiation therapy (SBRT) has been validated for liver lesions [1]. Because high dose per fraction is delivered on small volume, very accurate lesion segmentation is necessary. MRI is the most relevant imaging for liver lesion contouring but it is prone to motion artifacts if breathing is not managed. Evaluation of liver lesion motion induced by breathing is necessary in radiotherapy to guide patient treatment planning (respiratory gating). A 4D-MRI sequence was previously validated for liver [2]. In this study, an automated method was developed to sort images according to the breathing cycle. Methods The 4D-MRI acquisition is performed with an experimental sequence (bSSFP TrueFISP [3]) on 1.5T Magnetom AeraTM (Siemens). This sequence allows very fast axial and sagittal 2D acquisition during free breathing. Axial slice positions (0.88 s/slice) are incremented to cover the liver volume. Sagittal slices (navigators) are acquired at a fixed position. The navigators are used to assign a phase for each axial slice which depend on an amplitude sequencing of the respiratory cycle (0% = inspiration, 16%, 33%, 50% = expiration, 66%, 83%). Lung volume is estimated on each navigator by automatic segmentation and allows to assign a phase for the coupled axial image in the breathing cycle. As the image number per respiratory cycle is low, the sequence is repeated 20 times in order to achieve satisfactory sampling. The sequence was evaluated on 4 volunteers with an audio coaching (5 and 6 s period) and 2 patients without audio coaching. Results Patient image sorting according to their position in the breathing cycle was realized by automated phase detection (Fig. 1) and images were imported into the treatment planning system Eclipse 13.7TM (Varian) in 6 phases. Audio coaching is not used here. It is required for patients with irregular breathing cycle. From axial images, Eclipse reconstructs slices in sagittal and coronal plans, and allows to display a cine view with the 6 breathing phases in order to analyze the dynamic behavior of the liver. Conclusions 4D-MRI images from volunteers and patients were acquired with bSSFP TrueFISP sequence. After automated sorting with the method developed in this study, 6 breathing cycle phases were imported into Eclipse. Patient 4D-MRI can be registered with 4D-CT to increase the physician's segmentation accuracy. [ABSTRACT FROM AUTHOR]

Published

2018

7. 4. Application of a novel retrospective method for liver 4D-MRI.

Author

Nemtanu, T., Celicanin, Z., Cattin, P., Bieri, O., Aziza, R., Mkhitaryan, K., Parent, L., and Ken, S.

Abstract

Introduction Liver imaging is challenging due to its constant movement with breathing. In Magnetic Resonance Imaging (MRI), different strategies have been developed for organ movement consideration [1–3] . These methods are limited by the temporal resolution, as well as image quality. A novel retrospective gating method for dynamic 3D MR imaging during free breathing was developed [1] and further improved by Celicanin et al. [4] . This work aims of assessing the method and the reconstruction technique for liver cases. The final clinical application is to improve liver lesion delineation for Stereotactic Body Radiation Therapy (SBRT). Methods The innovative 4D MRI approach has been evaluated for liver motion estimation during entire respiratory cycle on a healthy volunteer. It is based on simultaneous acquisition of 2D images and a navigator set using acceleration CAIPIRINHA technique [4] providing no temporal divergence between them. During the entire acquisition time, the navigator is fixed in the same position, while the image position is changing, in order to cover the entire organ during free breathing [1] . The entire respiratory cycle is acquired, using a modified balanced Steady State Free Precession sequence (bSSFP) and is reconstructed in a retrospective manner ( Fig. 1 ). Images are acquired with a 1.5T MRI (MAGNETOM Aera; Siemens Medical Solutions, Erlangen, Germany), using an 18-channel design body flex coil. The 3.5 mm 2D axial slices are obtained, using the following sequence parameters: TE = 2.27 ms, TR = 591.97 ms, FA = 70 °, FOV = 37 × 37 cm 2 , matrix = 256 × 246. Total acquisition time is 33.175 s (0.83 s per slice). Results The preliminary results obtained on a healthy volunteer are shown in Fig. 1 . Images are characterized by high resolution and great contrast, making this method promising for liver lesion examination. The reconstruction of 4D MRI and the sequence optimization to cover the entire respiration cycle with the appropriate time sampling is ongoing work. Conclusions The benefit of MRI acquisition in treatment position to improve lesion contouring for liver SBRT has already been demonstrated [5] . The presented 4D MRI method represents a highly time efficient technique for the free breathing liver motion registration, giving the possibility to sort and reconstruct the images according to the respiratory phases. It will allow registration with 4D CT planning, likely to improve delineation accuracy. The same approach can be applied to study moving organs others than liver. [ABSTRACT FROM AUTHOR]

Published

2017

8. Feasibility of interleaved multislice averaged magnetization inversion-recovery acquisitions of the spinal cord.

Author

Weigel M, Celicanin Z, Haas T, and Bieri O

Subjects

Humans, Magnetic Resonance Imaging methods, Reproducibility of Results, Image Enhancement methods, Sensitivity and Specificity, Image Interpretation, Computer-Assisted methods, Male, Adult, Image Processing, Computer-Assisted methods, Female, Spinal Cord diagnostic imaging, Feasibility Studies, Algorithms

Abstract

Purpose: To establish an interleaved multislice variant of the averaged magnetization inversion-recovery acquisitions (AMIRA) approach for 2D spinal cord imaging with increased acquisition efficiency compared with the conventional 2D single-slice approach(es), and to determine essential prerequisites for a working interleaved multislice AMIRA approach in practice., Methods: The general AMIRA concept is based on an inversion recovery-prepared, segmented, and time-limited cine balanced SSFP sequence, generating images of different contrast. For AMIRA imaging of multiple, independent slices in a 2D interleaved fashion, a slice loop within the acquisition loops was programmed. The former non-selective inversions were replaced with slice-selective inversions with user-definable slice thickness., Results: The thickness of the slice-selective inversion in 2D interleaved multislice AMIRA should be doubled compared with the manufacturer's standard setting to avoid an increased sensitivity to flow and pulsation effects particularly in the CSF. However, this solution also limits its practical applicability, as slices located at directly adjacent vertebrae cannot be imaged together. Successful interleaved two-slice AMIRA imaging for a "reference" in vivo protocol with 0.50 × 0.50 mm 2 in-plane resolution and 8-mm slice thickness is demonstrated, therefore halving its acquisition time per slice from 3 min down to 1.5 min., Conclusion: The investigated 2D interleaved two-slice AMIRA variant facilitates spinal cord imaging that maintains similar contrast and the same resolution as the conventional 2D single-slice AMIRA approach, but does so with a halved acquisition time., (© 2024 The Author(s). Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published

2024

9. The influence of daily imaging and target margin reduction on secondary cancer risk in image-guided and adaptive proton therapy.

Author

Smolders A, Czerska K, Celicanin Z, Lomax A, and Albertini F

Subjects

Humans, Monte Carlo Method, Cone-Beam Computed Tomography, Radiotherapy Planning, Computer-Assisted methods, Neoplasms, Radiation-Induced prevention & control, Neoplasms, Radiation-Induced etiology, Radiotherapy Dosage, Time Factors, Risk, Proton Therapy adverse effects, Proton Therapy methods, Radiotherapy, Image-Guided methods, Radiotherapy, Image-Guided adverse effects, Head and Neck Neoplasms radiotherapy, Head and Neck Neoplasms diagnostic imaging

Abstract

Objective . Image-guided and adaptive proton therapy rely on daily CBCT or CT imaging, which increases radiation dose and radiation-induced cancer risk. Online adaptation however also reduces setup uncertainty, and the additional risk might be compensated by reducing the setup robustness margin. This work developed a framework to investigate how much this robustness margin should be reduced to offset the secondary cancer risk from additional imaging dose and applied it to proton therapy for head-and-neck cancer. Approach . For five patients with head-and-neck cancer, voxel-wise CT and CBCT imaging doses were estimated with Monte Carlo radiation transport simulations, calibrated with air and PMMA phantom measurements. The total dose of several image-guided and adaptive treatments protocols was calculated by summing the planning CT dose, daily and weekly CBCT or CT dose, and therapy dose, robustly optimized with setup margins between 0 and 4 mm. These were compared to a reference protocol with 4 mm setup margin without daily imaging. All plans further used 3% range robustness. Organ-wise excess absolute risk (EAR) of cancer was calculated with three models to determine at which setup margin the total EAR of image-guided and adaptive treatment protocols was equal to the total EAR of the reference. Results . The difference between the simulated and measured CT and CBCT doses was within 10%. Using the Monte Carlo models, we found that a 1 mm setup margin reduction was sufficient for most patients, treatment protocols, and cancer risk models to compensate the additional risk imposed by daily and weekly imaging. For some protocols, even a smaller reduction sufficed, depending on the imaging frequency and type. The risk reduction by reducing the margin was mainly due to reducing the risk for carcinomas in the brain and, for some patients, the oral cavity. Significance . Our framework allows to compare an increased imaging dose with the reduced treatment dose from margin reductions in terms of radiation-induced cancer risk. It is extendable to different treatment sites, modalities, and imaging protocols, in clinic-specific or even patient-specific assessments., (Creative Commons Attribution license.)

Published

2024

10. Impact of internal target volume definition for pencil beam scanned proton treatment planning in the presence of respiratory motion variability for lung cancer: A proof of concept.

Author

Krieger M, Giger A, Salomir R, Bieri O, Celicanin Z, Cattin PC, Lomax AJ, Weber DC, and Zhang Y

Subjects

Four-Dimensional Computed Tomography, Humans, Protons, Radiotherapy Planning, Computer-Assisted, Respiration, Lung Neoplasms diagnostic imaging, Lung Neoplasms radiotherapy, Proton Therapy

Abstract

Purpose: Motion management is crucial in scanned proton therapy for mobile tumours. Current motion mitigation approaches rely on single 4DCTs before treatment, ignoring respiratory variability. We investigate the consequences of respiratory variations on internal target volumes (ITV) definition and motion mitigation efficacy, and propose a probabilistic ITV based on 4DMRI., Materials and Methods: Four 4DCT(MRI) datasets, each containing 40 variable cycles of synthetic 4DCTs, were generated by warping single-phase CTs of two lung patients with motion fields extracted from two 4DMRI datasets. Two-field proton treatment plans were optimised on ITVs based on different parts of the 4DCT(MRI)s. 4D dose distributions were calculated by considering variable respiratory patterns. Different probabilistic ITVs were created by incorporating the voxels covered by the CTV in at least 25%, 50%, or 75% (ITV25, ITV50, ITV75) of the cycles, and compared with the conservative ITV encompassing all possible CTV positions., Results: Depending on the selected planning 4DCT, ITV volumes vary up to 20%, resulting in significant variation in CTV coverage for 4D treatments. Target coverage and homogeneity improved with the conservative ITV, but was associated with significantly increased lung dose (~1%). ITV25 and ITV50 led to acceptable plan quality in most cases without lung dose increments. ITV75 best minimised lung dose, but was insufficient to ensure coverage under all motion scenarios., Conclusion: Irregular respiration significantly affects CTV coverage when ITVs are only defined by single 4DCTs. A probabilistic ITV50 provides an adequate compromise between target coverage and lung dose for most motion and patient scenarios investigated., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2020

11. Micron-sized PFOB liquid core droplets stabilized with tailored-made perfluorinated surfactants as a new class of endovascular sono-sensitizers for focused ultrasound thermotherapy.

Author

Desgranges S, Lorton O, Gui-Levy L, Guillemin P, Celicanin Z, Hyacinthe JN, Breguet R, Crowe LA, Becker CD, Soulié M, Taulier N, Contino-Pépin C, and Salomir R

Subjects

Biocompatible Materials chemistry, Contrast Media chemistry, High-Intensity Focused Ultrasound Ablation methods, Humans, Hydrophobic and Hydrophilic Interactions, Hyperthermia, Induced, Magnetic Resonance Imaging, Neoplasms therapy, Particle Size, Temperature, Ultrasonography, Fluorocarbons chemistry, Surface-Active Agents chemistry

Abstract

The purpose of this study was to develop micron-sized droplet emulsions able to increase the heat deposition of high intensity focused ultrasound (HIFU), aiming to accelerate the tumour ablation in highly perfused organs with reduced side effects. The investigated droplets consisted of a perfluorooctyl bromide (PFOB) core coated with a biocompatible fluorinated surfactant called F-TAC. The novelty of this work relies on the use, for this application, of a high boiling point perfluorocarbon core (142 °C), combined with an in-house fluorinated surfactant to formulate the emulsion, yielding quasi-reversible strong interactions between the HIFU beam and the droplets. In order to fine-tune the emulsion size, surfactants with different hydrophobic/hydrophilic ratios were screened. Different concentrations of PFOB droplets were homogeneously embedded in two different MRI compatible materials, exhibiting either ultrasound (US) absorbing or non-absorbing properties. For the US absorbing TMM, the speed of sound at each droplet concentration was also assessed. These TMM were sonicated by 1 MHz HIFU with acoustical power of 94 W at two different duty cycles. The temperature elevation was monitored accurately by MRI proton shift resonance frequency in near real-time. The presence of sono-sensitive droplets induced a significant increase of the HIFU thermal effect that persisted under repeated sonication of the same locus. Optimal enhancement was observed at the lowest concentration tested (0.1%) with an additional temperature rise at the focal point of approximately 4 °C per applied kJ of acoustic energy corresponding to one order of magnitude augmentation of the thermal dose. Furthermore, no deformation of the heating pattern pre- or post-focal was observed.

Published

2019

12. Molecular oxygen loading in candidate theranostic droplets stabilized with biocompatible fluorinated surfactants: Particle size effect and application to in situ 19 F MRI mapping of oxygen partial pressure.

Author

Lorton O, Hyacinthe JN, Desgranges S, Gui L, Klauser A, Celicanin Z, Crowe LA, Lazeyras F, Allémann E, Taulier N, Contino-Pépin C, and Salomir R

Abstract

Objective: Perfluorocarbon nano- and micron-sized emulsions are a new field of investigation in cancer treatment due to their ability to be used as imaging contrast agents, or as delivery vectors for pharmaceuticals. They also demonstrated capability to enhance the efficiency of high intensity focused ultrasound thermo-therapy. In the context of new biomedical applications we investigated perfluorooctyl bromide (PFOB) theranostic droplets using 19 F NMR. Each droplet contains biocompatible fluorinated surfactants composed of a polar Tris(hydroxymethyl)aminomethane head unit and hydrophobic perfluorinated tail (abbreviated as F-TAC). The influence of the droplet size on the oxygen loading capacity was determined from longitudinal relaxation (T 1 ) data of 19 F NMR signal., Material and Methods: Liquid PFOB and five samples of PFOB droplets of average diameter 0.177, 0.259, 1.43, 3.12 and 4.53 µm were tested with different oxygen levels. A dedicated gas exchange system was validated to maintain steady state oxygen concentrations, including a spatial gradient of oxygen concentration. A prototyped transmit-receive switchable 19 F/ 1 H quadrature coil was integrated on a 3 T clinical scanner. The coil is compatible with focused ultrasound sonication for future application. A spectroscopy FID inversion-recovery (IR) sequence was used to measure the T 1 value per sample and per value of equilibrium oxygen pressure. Pixel wise, spatial T 1 mapping was performed with magnetization prepared 2D gradient echo sequences in tissue mimicking gels doped with theranostic droplets., Results: Experimental data indicated that the longitudinal relaxation rate of 19 F signal of the investigated theranostic droplets depended approximately linearly on the oxygen level and its slope decreased with the particle size according to a second order polynomial over the investigated range. This semi-empirical model was derived from general thermodynamics and weak electrostatic forces theory and fitted the experimental data within 0.75% precision. The capacity of oxygen transportation for the described theranostic droplets tended to that of pure PFOB, while micron-sized droplets lost up to 50% of this capacity. In a specific setup producing a steady state gradient of oxygen concentration, we demonstrated spatial mapping of oxygen pressure gradient of 6 kPa/mm with 1 mm in-plane resolution., Conclusion: The size-tunable PFOB theranostic droplets stabilized with F-TAC surfactants could be characterized by 19 F MRI in a clinical setup readily compatible with interventional in vivo studies under MR guidance. Current precision and spatial resolution of T 1 mapping are promising. A potential challenge for further in vivo studies is the reduction of the imaging time., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2018

13. Simultaneous multislice triple-echo steady-state (SMS-TESS) T 1 , T 2 , PD, and off-resonance mapping in the human brain.

Author

Heule R, Celicanin Z, Kozerke S, and Bieri O

Subjects

Echo-Planar Imaging methods, Equipment Design, Healthy Volunteers, Humans, Image Processing, Computer-Assisted methods, Motion, Phantoms, Imaging, Protons, Reference Values, Reproducibility of Results, Brain diagnostic imaging, Brain Mapping, Magnetic Resonance Imaging

Published

2018

14. Ultrasound-driven 4D MRI.

Author

Giger A, Stadelmann M, Preiswerk F, Jud C, De Luca V, Celicanin Z, Bieri O, Salomir R, and Cattin PC

Subjects

Humans, Movement, Respiration, Retrospective Studies, Abdomen diagnostic imaging, Four-Dimensional Computed Tomography methods, Image Processing, Computer-Assisted methods, Liver diagnostic imaging, Magnetic Resonance Imaging methods, Thorax diagnostic imaging, Ultrasonography methods

Abstract

We present an ultrasound-driven 4D magnetic resonance imaging (US-4DMRI) method for respiratory motion imaging in the thorax and abdomen. The proposed US-4DMRI comes along with a high temporal resolution, and allows for organ motion imaging beyond a single respiratory cycle. With the availability of the US surrogate both inside and outside the MR bore, 4D MR images can be reconstructed for 4D treatment planning and online respiratory motion prediction during radiotherapy. US-4DMRI relies on simultaneously acquired 2D liver US images and abdominal 2D MR multi-slice scans under free respiration. MR volumes are retrospectively composed by grouping the MR slices corresponding to the most similar US images. We present two different US similarity metrics: an intensity-based approach, and a similarity measure relying on predefined fiducials which are being tracked over time. The proposed method is demonstrated on MR liver scans of eight volunteers acquired over a duration of 5.5 min each at a temporal resolution of 2.6 Hz with synchronous US imaging at 14 Hz-17 Hz. Visual inspection of the reconstructed MR volumes revealed satisfactory results in terms of continuity in organ boundaries and blood vessels. In quantitative leave-one-out experiments, both US similarity metrics reach the performance level of state-of-the-art navigator-based approaches.

Published

2018

15. Hybrid ultrasound-MR guided HIFU treatment method with 3D motion compensation.

Author

Celicanin Z, Manasseh G, Petrusca L, Scheffler K, Auboiroux V, Crowe LA, Hyacinthe JN, Natsuaki Y, Santini F, Becker CD, Terraz S, Bieri O, and Salomir R

Subjects

Adult, Algorithms, Animals, Cattle, Female, Humans, Liver diagnostic imaging, Liver surgery, Male, Thermometry methods, High-Intensity Focused Ultrasound Ablation methods, Imaging, Three-Dimensional methods, Magnetic Resonance Imaging methods, Surgery, Computer-Assisted methods

Abstract

Purpose: Treatments using high-intensity focused ultrasound (HIFU) in the abdominal region remain challenging as a result of respiratory organ motion. A novel method is described here to achieve 3D motion-compensated ultrasound (US) MR-guided HIFU therapy using simultaneous ultrasound and MRI., Methods: A truly hybrid US-MR-guided HIFU method was used to plan and control the treatment. Two-dimensional ultrasound was used in real time to enable tracking of the motion in the coronal plane, whereas an MR pencil-beam navigator was used to detect anterior-posterior motion. Prospective motion compensation of proton resonance frequency shift (PRFS) thermometry and HIFU electronic beam steering were achieved., Results: The 3D prospective motion-corrected PRFS temperature maps showed reduced intrascan ghosting artifacts, a high signal-to-noise ratio, and low geometric distortion. The k-space data yielded a consistent temperature-dependent PRFS effect, matching the gold standard thermometry within approximately 1°C. The maximum in-plane temperature elevation ex vivo was improved by a factor of 2. Baseline thermometry acquired in volunteers indicated reduction of residual motion, together with an accuracy/precision of near-harmonic referenceless PRFS thermometry on the order of 0.5/1.0°C., Conclusions: Hybrid US-MR-guided HIFU ablation with 3D motion compensation was demonstrated ex vivo together with a stable referenceless PRFS thermometry baseline in healthy volunteer liver acquisitions. Magn Reson Med 79:2511-2523, 2018. © 2017 International Society for Magnetic Resonance in Medicine., (© 2017 International Society for Magnetic Resonance in Medicine.)

Published

2018

16. Simultaneous acquisition of image and navigator slices using CAIPIRINHA for 4D MRI.

Author

Celicanin Z, Bieri O, Preiswerk F, Cattin P, Scheffler K, and Santini F

Subjects

Algorithms, Evoked Potentials physiology, Feasibility Studies, Humans, Image Enhancement methods, Image Interpretation, Computer-Assisted methods, Reproducibility of Results, Sensitivity and Specificity, Artifacts, Brain Mapping methods, Imaging, Three-Dimensional methods, Magnetic Resonance Imaging methods, Motor Cortex physiology, Movement physiology

Abstract

Purpose: Respiratory organ motion is still the major challenge of various image-guided treatments in the abdomen. Dynamic organ motion tracking, necessary for the treatment control, can be performed with volumetric time-resolved MRI that sequentially acquires one image and one navigator slice. Here, a novel imaging method is proposed for truly simultaneous high temporal resolution acquisition., Methods: A standard balanced steady state free precession sequence was modified to simultaneously acquire two superimposed slices with different phase cycles, namely an image and a navigator slice. Instead of multiband RF pulses, two separate RF pulses were used for the excitation. Images were reconstructed using offline CAIPIRINHA reconstruction. Phantom and in vivo measurements of healthy volunteers were performed and evaluated., Results: Phantom and in vivo measurements showed good image quality with high signal-to-noise ratio (SNR) and no reconstruction issues., Conclusion: We present a novel imaging method for truly simultaneous acquisition of image and navigator slices for four-dimensional (4D) MRI of organ motion. In this method, the time lag between the sequential acquisitions is eliminated, leading to an improved accuracy of organ motion models, while CAIPIRINHA reconstruction results in an improved SNR compared with an existing 4D MRI approach., (© 2014 Wiley Periodicals, Inc.)

Published

2015

17. Real-time method for motion-compensated MR thermometry and MRgHIFU treatment in abdominal organs.

Author

Celicanin Z, Auboiroux V, Bieri O, Petrusca L, Santini F, Viallon M, Scheffler K, and Salomir R

Subjects

Abdomen physiology, Abdomen radiation effects, Abdomen surgery, Animals, Body Temperature physiology, Body Temperature radiation effects, Computer Systems, High-Energy Shock Waves, Image Enhancement methods, In Vitro Techniques, Motion, Reproducibility of Results, Sensitivity and Specificity, Sheep, Surgery, Computer-Assisted methods, Turkey, Viscera radiation effects, Artifacts, High-Intensity Focused Ultrasound Ablation methods, Magnetic Resonance Imaging methods, Thermography methods, Viscera physiology, Viscera surgery

Abstract

Purpose: Magnetic resonance-guided high-intensity focused ultrasound is considered to be a promising treatment for localized cancer in abdominal organs such as liver, pancreas, or kidney. Abdominal motion, anatomical arrangement, and required sustained sonication are the main challenges., Methods: MR acquisition consisted of thermometry performed with segmented gradient-recalled echo echo-planar imaging, and a segment-based one-dimensional MR navigator parallel to the main axis of motion to track the organ motion. This tracking information was used in real-time for: (i) prospective motion correction of MR thermometry and (ii) HIFU focal point position lock-on target. Ex vivo experiments were performed on a sheep liver and a turkey pectoral muscle using a motion demonstrator, while in vivo experiments were conducted on two sheep liver., Results: Prospective motion correction of MR thermometry yielded good signal-to-noise ratio (range, 25 to 35) and low geometric distortion due to the use of segmented EPI. HIFU focal point lock-on target yielded isotropic in-plane thermal build-up. The feasibility of in vivo intercostal liver treatment was demonstrated in sheep., Conclusion: The presented method demonstrated in moving phantoms and breathing sheep accurate motion-compensated MR thermometry and precise HIFU focal point lock-on target using only real-time pencil-beam navigator tracking information, making it applicable without any pretreatment data acquisition or organ motion modeling., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2014

18. Model-guided respiratory organ motion prediction of the liver from 2D ultrasound.

Author

Preiswerk F, De Luca V, Arnold P, Celicanin Z, Petrusca L, Tanner C, Bieri O, Salomir R, and Cattin PC

Subjects

Adolescent, Adult, Aged, Anatomic Landmarks diagnostic imaging, Computer Simulation, Female, Humans, Male, Middle Aged, Models, Statistical, Movement physiology, Reproducibility of Results, Sensitivity and Specificity, Young Adult, Image Enhancement methods, Liver diagnostic imaging, Liver physiology, Models, Biological, Respiratory Mechanics physiology, Respiratory-Gated Imaging Techniques methods, Ultrasonography methods

Abstract

With the availability of new and more accurate tumour treatment modalities such as high-intensity focused ultrasound or proton therapy, accurate target location prediction has become a key issue. Various approaches for diverse application scenarios have been proposed over the last decade. Whereas external surrogate markers such as a breathing belt work to some extent, knowledge about the internal motion of the organs inherently provides more accurate results. In this paper, we combine a population-based statistical motion model and information from 2d ultrasound sequences in order to predict the respiratory motion of the right liver lobe. For this, the motion model is fitted to a 3d exhalation breath-hold scan of the liver acquired before prediction. Anatomical landmarks tracked in the ultrasound images together with the model are then used to reconstruct the complete organ position over time. The prediction is both spatial and temporal, can be computed in real-time and is evaluated on ground truth over long time scales (5.5 min). The method is quantitatively validated on eight volunteers where the ultrasound images are synchronously acquired with 4D-MRI, which provides ground-truth motion. With an average spatial prediction accuracy of 2.4 mm, we can predict tumour locations within clinically acceptable margins., (Copyright © 2014 Elsevier B.V. All rights reserved.)

Published

2014

19. Hybrid ultrasound/magnetic resonance simultaneous acquisition and image fusion for motion monitoring in the upper abdomen.

Author

Petrusca L, Cattin P, De Luca V, Preiswerk F, Celicanin Z, Auboiroux V, Viallon M, Arnold P, Santini F, Terraz S, Scheffler K, Becker CD, and Salomir R

Subjects

Feasibility Studies, Humans, Image Processing, Computer-Assisted methods, Imaging, Three-Dimensional methods, Phantoms, Imaging, Reference Values, Reproducibility of Results, Liver anatomy & histology, Magnetic Resonance Imaging methods, Motion, Ultrasonography methods

Abstract

Objectives: The combination of ultrasound (US) and magnetic resonance imaging (MRI) may provide a complementary description of the investigated anatomy, together with improved guidance and assessment of image-guided therapies. The aim of the present study was to integrate a clinical setup for simultaneous US and magnetic resonance (MR) acquisition to obtain synchronized monitoring of liver motion. The feasibility of this hybrid imaging and the precision of image fusion were evaluated., Materials and Methods: Ultrasound imaging was achieved using a clinical US scanner modified to be MR compatible, whereas MRI was achieved on 1.5- and 3-T clinical scanners. Multimodal registration was performed between a high-resolution T1 3-dimensional (3D) gradient echo (volume interpolated gradient echo) during breath-hold and a simultaneously acquired 2D US image, or equivalent, retrospective registration of US imaging probe in the coordinate frame of MRI. A preliminary phantom study was followed by 4 healthy volunteer acquisitions, performing simultaneous 4D MRI and 2D US harmonic imaging (Fo = 2.2 MHz) under free breathing., Results: No characterized radiofrequency mutual interferences were detected under the tested conditions with commonly used MR sequences in clinical routine, during simultaneous US/MRI acquisition. Accurate spatial matching between the 2D US and the corresponding MRI plane was obtained during breath-hold. In situ fused images were delivered. Our 4D MRI sequence permitted the dynamic reconstruction of the intra-abdominal motion and the calculation of high temporal resolution motion field vectors., Conclusions: This study demonstrates that, truly, simultaneous US/MR dynamic acquisition in the abdomen is achievable using clinical instruments. A potential application is the US/MR hybrid guidance of high-intensity focused US therapy in the liver.

Published

2013