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1. A reusable 3D printed brain‐like phantom for benchmarking electrical properties tomography reconstructions.

Author

Meerbothe, T. G., Florczak, S., van den Berg, C. A. T., Levato, R., and Mandija, S.

Subjects
ELECTRIC conductivity, THREE-dimensional printing, DIELECTRIC properties, SALINE solutions, REFERENCE values
Abstract

Purpose: In MR electrical properties tomography (MR‐EPT), electrical properties (EPs, conductivity and permittivity) are reconstructed from MR measurements. Phantom measurements are important to characterize the performance of MR‐EPT reconstruction methods, since they allow knowledge of reference EPs values. To assess reconstruction methods in a more realistic scenario, it is important to test the methods using phantoms with realistic shapes, internal structures, and dielectric properties. In this work, we present a 3D printing procedure for the creation of realistic brain‐like phantoms to benchmark MR‐EPT reconstructions. Methods: We created two brain‐like geometries with three different compartments using 3D printing. The first geometry was filled once, while the second geometry was filled three times with different saline‐gelatin solutions, resulting in a total of four phantoms with different EPs. The saline solutions were characterized using a probe. 3D MR‐EPT reconstructions were performed from MR measurements at 3T. The reconstructed conductivity values were compared to reference values of the saline‐gelatin solutions. The measured fields were also compared to simulated fields using the same phantom geometry and electrical properties. Results: The measured fields were consistent with simulated fields. Reconstructed conductivity values were consistent with the reference (probe) conductivity values. This indicated the suitability of such phantoms for benchmarking MR‐EPT reconstructions. Conclusion: We presented a new workflow to 3D print realistic brain‐like phantoms in an easy and affordable way. These phantoms are suitable to benchmark MR‐EPT reconstructions, but can also be used for benchmarking other quantitative MR methods. [ABSTRACT FROM AUTHOR]

Published
2024
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4. A database for MR‐based electrical properties tomography with in silico brain data—ADEPT.

Author

Meerbothe, T. G., Meliado, E. F., Stijnman, P. R. S., van den Berg, C. A. T., and Mandija, S.

Subjects
DATABASES, BRAIN tomography, ELECTRIC fields, ELECTROMAGNETIC fields, MAGNETIC fields
Abstract

Purpose: Several reconstruction methods for MR‐based electrical properties tomography (EPT) have been developed. However, the lack of common data makes it difficult to objectively compare their performances. This is, however, a necessary precursor for standardizing and introducing this technique in the clinical setting. To enable objective comparison of the performances of reconstruction methods and provide common data for their training and testing, we created ADEPT, a database of simulated data for brain MR‐EPT reconstructions. Methods: ADEPT is a database containing in silico data for brain EPT reconstructions. This database was created from 25 different brain models, with and without tumors. Rigid geometric augmentations were applied, and different electrical properties were assigned to white matter, gray matter, CSF, and tumors to generate 120 different brain models. These models were used as input for finite‐difference time‐domain simulations in Sim4Life, used to compute the electromagnetic fields needed for MR‐EPT reconstructions. Results: Electromagnetic fields from 84 healthy and 36 tumor brain models were simulated. The simulated fields relevant for MR‐EPT reconstructions (transmit and receive RF fields and transceive phase) and their ground‐truth electrical properties are made publicly available through ADEPT. Additionally, nonattainable fields such as the total magnetic field and the electric field are available upon request. Conclusion: ADEPT will serve as reference database for objective comparisons of reconstruction methods and will be a first step toward standardization of MR‐EPT reconstructions. Furthermore, it provides a large amount of data that can be exploited to train data‐driven methods. It can be accessed from https://doi.org/10.34894/V0HBJ8. [ABSTRACT FROM AUTHOR]

Published
2024
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6. OC-0940 Assessment of cardiorespiratory motion for cardiac radioablation using a digital 17-segment model

Author

Stevens, R., primary, Hazelaar, C., additional, Bogowicz, M., additional, ter Bekke, R.M., additional, Volders, P.G., additional, Verhoeven, K., additional, de Ruysscher, D., additional, Verhoeff, J.J., additional, Fast, M.F., additional, Mandija, S., additional, Cvek, J., additional, Knybel, L., additional, Dvorak, P., additional, Blanck, O., additional, and van Elmpt, W., additional

Published
2023
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7. STereotactic Arrhythmia Radioablation (STAR): the Standardized Treatment and Outcome Platform for Stereotactic Therapy Of Re-entrant tachycardia by a Multidisciplinary consortium (STOPSTORM.eu) and review of current patterns of STAR practice in Europe

Author

Grehn, M., Mandija, S., Miszczyk, M., Krug, D., Tomasik, B., Stickney, K. E., Alcantara, P., Alongi, F., Anselmino, M., Aranda, R. S., Balgobind, B. V., Boda-Heggemann, J., Boldt, L.-H., Bottoni, N., Cvek, J., Elicin, O., Ferrari, G. M., Hassink, R. J., Hazelaar, C., Hindricks, G., Hurkmans, C., Iotti, C., Jadczyk, T., Jiravsky, O., Jumeau, R., Kristiansen, S. B., Levis, M., López, M. A., Martí-Almor, J., Mehrhof, F., Møller, D. S., Molon, G., Ouss, A., Peichl, P., Plasek, J., Postema, P. G., Quesada, A., Reichlin, T., Rordorf, R., Rudic, B., Saguner, A. M., Ter, B., Rachel, M. A., Torrecilla, J. L., (0000-0001-9550-9050) Troost, E. G. C., Vitolo, V., Andratschke, N., Zeppenfeld, K., Blamek, S., Fast, M., Panfilis, L., Blanck, O., Pruvot, E., Verhoeff, J. J. C., Grehn, M., Mandija, S., Miszczyk, M., Krug, D., Tomasik, B., Stickney, K. E., Alcantara, P., Alongi, F., Anselmino, M., Aranda, R. S., Balgobind, B. V., Boda-Heggemann, J., Boldt, L.-H., Bottoni, N., Cvek, J., Elicin, O., Ferrari, G. M., Hassink, R. J., Hazelaar, C., Hindricks, G., Hurkmans, C., Iotti, C., Jadczyk, T., Jiravsky, O., Jumeau, R., Kristiansen, S. B., Levis, M., López, M. A., Martí-Almor, J., Mehrhof, F., Møller, D. S., Molon, G., Ouss, A., Peichl, P., Plasek, J., Postema, P. G., Quesada, A., Reichlin, T., Rordorf, R., Rudic, B., Saguner, A. M., Ter, B., Rachel, M. A., Torrecilla, J. L., (0000-0001-9550-9050) Troost, E. G. C., Vitolo, V., Andratschke, N., Zeppenfeld, K., Blamek, S., Fast, M., Panfilis, L., Blanck, O., Pruvot, E., and Verhoeff, J. J. C.

Abstract

The EU Horizon 2020 Framework-funded Standardized Treatment and Outcome Platform for Stereotactic Therapy Of Re-entrant tachycardia by a Multidisciplinary (STOPSTORM) consortium has been established as a large research network for investigating STereotactic Arrhythmia Radioablation (STAR) for ventricular tachycardia (VT). The aim is to provide a pooled treatment database to evaluate patterns of practice and outcomes of STAR and finally to harmonize STAR within Europe. The consortium comprises 31 clinical and research institutions. The project is divided into nine work packages (WPs): (i) observational cohort; (ii) standardization and harmonization of target delineation; (iii) harmonized prospective cohort; (iv) quality assurance (QA); (v) analysis and evaluation; (vi, ix) ethics and regulations; and (vii, viii) project coordination and dissemination. To provide a review of current clinical STAR practice in Europe, a comprehensive questionnaire was performed at project start. The STOPSTORM Institutions' experience in VT catheter ablation (83% ≥ 20 ann.) and stereotactic body radiotherapy (59% > 200 ann.) was adequate, and 84 STAR treatments were performed until project launch, while 8/22 centres already recruited VT patients in national clinical trials. The majority currently base their target definition on mapping during VT (96%) and/or pace mapping (75%), reduced voltage areas (63%), or late ventricular potentials (75%) during sinus rhythm. The majority currently apply a single-fraction dose of 25 Gy while planning techniques and dose prescription methods vary greatly. The current clinical STAR practice in the STOPSTORM consortium highlights potential areas of optimization and harmonization for substrate mapping, target delineation, motion management, dosimetry, and QA, which will be addressed in the various WPs. © The Author(s) 2023. Published by Oxford University Press on behalf of the European Society of Cardiology.

Published
2023

8. Activity-dependent spinal cord neuromodulation rapidly restores trunk and leg motor functions after complete paralysis

Author

Rowald, A., Komi, S., Demesmaeker, R., Baaklini, E., Hernandez-Charpak, S.D., Paoles, E., Montanaro, H., Cassara, A., Becce, F., Lloyd, B., Newton, T., Ravier, J., Kinany, N., D'Ercole, M., Paley, A., Hankov, N., Varescon, C., McCracken, L., Vat, M., Caban, M., Watrin, A., Jacquet, C., Bole-Feysot, L., Harte, Cathal, Lorach, H., Galvez, A., Tschopp, M., Herrmann, N., Wacker, M., Geernaert, L., Fodor, I., Radevich, V., Keybus, K. Van Den, Eberle, G., Pralong, E., Roulet, M., Ledoux, J.B., Fornari, E., Mandija, S., Mattera, L., Martuzzi, R., Nazarian, B., Benkler, S., Callegari, S., Greiner, N., Fuhrer, B., Froeling, M., Buse, N., Denison, T., Buschman, R., Wende, C., Ganty, D., Bakker, Jurriaan, Delattre, V., Lambert, H., Minassian, K., Berg, C.A.T. van den, Kavounoudias, A., Micera, S., Ville, D. Van De, Barraud, Q., Kurt, E., Kuster, N., Neufeld, E., Capogrosso, M., Asboth, L., Wagner, F.B., Bloch, J., Courtine, G., Rowald, A., Komi, S., Demesmaeker, R., Baaklini, E., Hernandez-Charpak, S.D., Paoles, E., Montanaro, H., Cassara, A., Becce, F., Lloyd, B., Newton, T., Ravier, J., Kinany, N., D'Ercole, M., Paley, A., Hankov, N., Varescon, C., McCracken, L., Vat, M., Caban, M., Watrin, A., Jacquet, C., Bole-Feysot, L., Harte, Cathal, Lorach, H., Galvez, A., Tschopp, M., Herrmann, N., Wacker, M., Geernaert, L., Fodor, I., Radevich, V., Keybus, K. Van Den, Eberle, G., Pralong, E., Roulet, M., Ledoux, J.B., Fornari, E., Mandija, S., Mattera, L., Martuzzi, R., Nazarian, B., Benkler, S., Callegari, S., Greiner, N., Fuhrer, B., Froeling, M., Buse, N., Denison, T., Buschman, R., Wende, C., Ganty, D., Bakker, Jurriaan, Delattre, V., Lambert, H., Minassian, K., Berg, C.A.T. van den, Kavounoudias, A., Micera, S., Ville, D. Van De, Barraud, Q., Kurt, E., Kuster, N., Neufeld, E., Capogrosso, M., Asboth, L., Wagner, F.B., Bloch, J., and Courtine, G.

Abstract

Item does not contain fulltext, Epidural electrical stimulation (EES) targeting the dorsal roots of lumbosacral segments restores walking in people with spinal cord injury (SCI). However, EES is delivered with multielectrode paddle leads that were originally designed to target the dorsal column of the spinal cord. Here, we hypothesized that an arrangement of electrodes targeting the ensemble of dorsal roots involved in leg and trunk movements would result in superior efficacy, restoring more diverse motor activities after the most severe SCI. To test this hypothesis, we established a computational framework that informed the optimal arrangement of electrodes on a new paddle lead and guided its neurosurgical positioning. We also developed software supporting the rapid configuration of activity-specific stimulation programs that reproduced the natural activation of motor neurons underlying each activity. We tested these neurotechnologies in three individuals with complete sensorimotor paralysis as part of an ongoing clinical trial ( www.clinicaltrials.gov identifier NCT02936453). Within a single day, activity-specific stimulation programs enabled these three individuals to stand, walk, cycle, swim and control trunk movements. Neurorehabilitation mediated sufficient improvement to restore these activities in community settings, opening a realistic path to support everyday mobility with EES in people with SCI.

Published
2022

9. Dynamic Contrast-enhanced and Diffusion-weighted Magnetic Resonance Imaging for Response Evaluation After Single-Dose Ablative Neoadjuvant Partial Breast Irradiation

Author

Vasmel, J.E., Groot Koerkamp, M.L., Mandija, S., Veldhuis, W.B., Moman, M.R., Froeling, M., Velden, B.H.M. van der, Charaghvandi, R., Vreuls, C.P.H., Diest, P.J. van, Leeuwen, A.M.G. van, Gorp, J. van, Philippens, M.E., Asselen, B. van, Lagendijk, J.J., Verkooijen, H.M., Bongard, H. van den, Houweling, A.C., Vasmel, J.E., Groot Koerkamp, M.L., Mandija, S., Veldhuis, W.B., Moman, M.R., Froeling, M., Velden, B.H.M. van der, Charaghvandi, R., Vreuls, C.P.H., Diest, P.J. van, Leeuwen, A.M.G. van, Gorp, J. van, Philippens, M.E., Asselen, B. van, Lagendijk, J.J., Verkooijen, H.M., Bongard, H. van den, and Houweling, A.C.

Abstract

Item does not contain fulltext, PURPOSE: We aimed to evaluate changes in dynamic contrast-enhanced (DCE) and diffusion-weighted (DW) magnetic resonance imaging (MRI) scans acquired before and after single-dose ablative neoadjuvant partial breast irradiation (NA-PBI), and explore the relation between semiquantitative MRI parameters and radiologic and pathologic responses. METHODS AND MATERIALS: We analyzed 3.0T DCE and DW-MRI of 36 patients with low-risk breast cancer who were treated with single-dose NA-PBI, followed by breast-conserving surgery 6 or 8 months later. MRI was acquired before NA-PBI and 1 week, 2, 4, and 6 months after NA-PBI. Breast radiologists assessed the radiologic response and breast pathologists scored the pathologic response after surgery. Patients were grouped as either pathologic responders or nonresponders (<10% vs ≥10% residual tumor cells). The semiquantitative MRI parameters evaluated were time to enhancement (TTE), 1-minute relative enhancement (RE(1min)), percentage of enhancing voxels (%EV), distribution of washout curve types, and apparent diffusion coefficient (ADC). RESULTS: In general, the enhancement increased 1 week after NA-PBI (baseline vs 1 week median - TTE: 15s vs 10s; RE(1min): 161% vs 197%; %EV: 47% vs 67%) and decreased from 2 months onward (6 months median - TTE: 25s; RE(1min): 86%; %EV: 12%). Median ADC increased from 0.83 × 10(-3) mm(2)/s at baseline to 1.28 × 10(-3) mm(2)/s at 6 months. TTE, RE(1min), and %EV showed the most potential to differentiate between radiologic responses, and TTE, RE(1min), and ADC between pathologic responses. CONCLUSIONS: Semiquantitative analyses of DCE and DW-MRI showed changes in relative enhancement and ADC 1 week after NA-PBI, indicating acute inflammation, followed by changes indicating tumor regression from 2 to 6 months after radiation therapy. A relation between the MRI parameters and radiologic and pathologic responses could not be proven in this exploratory study.

Published
2022

10. Combining deep learning and 3D contrast source inversion in MR-based electrical properties tomography.

Author

Leijsen, R, van den Berg, C, Webb, A, Remis, R, Mandija, S, Leijsen, R, van den Berg, C, Webb, A, Remis, R, and Mandija, S

Abstract

Magnetic resonance electrical properties tomography (MR-EPT) is a technique used to estimate the conductivity and permittivity of tissues from MR measurements of the transmit magnetic field. Different reconstruction methods are available; however, all these methods present several limitations, which hamper the clinical applicability. Standard Helmholtz-based MR-EPT methods are severely affected by noise. Iterative reconstruction methods such as contrast source inversion electrical properties tomography (CSI-EPT) are typically time-consuming and are dependent on their initialization. Deep learning (DL) based methods require a large amount of training data before sufficient generalization can be achieved. Here, we investigate the benefits achievable using a hybrid approach, that is, using MR-EPT or DL-EPT as initialization guesses for standard 3D CSI-EPT. Using realistic electromagnetic simulations at 3 and 7 T, the accuracy and precision of hybrid CSI reconstructions are compared with those of standard 3D CSI-EPT reconstructions. Our results indicate that a hybrid method consisting of an initial DL-EPT reconstruction followed by a 3D CSI-EPT reconstruction would be beneficial. DL-EPT combined with standard 3D CSI-EPT exploits the power of data-driven DL-based EPT reconstructions, while the subsequent CSI-EPT facilitates a better generalization by providing data consistency.

Published
2022

17. Synthetic CT for single-fraction neoadjuvant partial breast irradiation on an MRI-linac

Author

Koerkamp, M.L. Groot, Hond, Y.J.M. de, Maspero, M., Kontaxis, C., Mandija, S., Vasmel, J.E., Charaghvandi, R., Philippens, M.E., Asselen, B. van, Bongard, H. van den, Hackett, S.S., Houweling, A.C., Koerkamp, M.L. Groot, Hond, Y.J.M. de, Maspero, M., Kontaxis, C., Mandija, S., Vasmel, J.E., Charaghvandi, R., Philippens, M.E., Asselen, B. van, Bongard, H. van den, Hackett, S.S., and Houweling, A.C.

Abstract

Item does not contain fulltext, A synthetic computed tomography (sCT) is required for daily plan optimization on an MRI-linac. Yet, only limited information is available on the accuracy of dose calculations on sCT for breast radiotherapy. This work aimed to (1) evaluate dosimetric accuracy of treatment plans for single-fraction neoadjuvant partial breast irradiation (PBI) on a 1.5 T MRI-linac calculated on a) bulk-density sCT mimicking the current MRI-linac workflow and b) deep learning-generated sCT, and (2) investigate the number of bulk-density levels required. For ten breast cancer patients we created three bulk-density sCTs of increasing complexity from the planning-CT, using bulk-density for: (1) body, lungs, and GTV (sCT(BD1)); (2) volumes for sCT(BD1)plus chest wall and ipsilateral breast (sCT(BD2)); (3) volumes for sCT(BD2)plus ribs (sCT(BD3)); and a deep learning-generated sCT (sCT(DL)) from a 1.5 T MRI in supine position. Single-fraction neoadjuvant PBI treatment plans for a 1.5 T MRI-linac were optimized on each sCT and recalculated on the planning-CT. Image evaluation was performed by assessing mean absolute error (MAE) and mean error (ME) in Hounsfield Units (HU) between the sCTs and the planning-CT. Dosimetric evaluation was performed by assessing dose differences, gamma pass rates, and dose-volume histogram (DVH) differences. The following results were obtained (median across patients for sCT(BD1)/sCT(BD2)/sCT(BD3)/sCT(DL)respectively): MAE inside the body contour was 106/104/104/75 HU and ME was 8/9/6/28 HU, mean dose difference in the PTV(GTV)was 0.15/0.00/0.00/-0.07 Gy, median gamma pass rate (2%/2 mm, 10% dose threshold) was 98.9/98.9/98.7/99.4%, and differences in DVH parameters were well below 2% for all structures except for the skin in the sCT(DL). Accurate dose calculations for single-fraction neoadjuvant PBI on an MRI-linac could be performed on both bulk-density and deep learning sCT, facilitating further implementation of MRI-guided radiotherapy for breast cancer. Balan

Published
2021

18. Cardiac-Synchronized T1 mapping on the Unity MR-linac to guide STereotactic Arrhythmia Radioablation

Author

Computational Imaging, Cancer, Experimentele klinische fysica, Klinische Fysica RT, Team Medisch, Circulatory Health, MS Radiotherapie, MS Radiologie, Mandija, S., Akdag, O., van Lier, A., Borman, P., Schakel, T., Alberts, E., van der Heide, O., Hassink, R., Alings, M., Verhoeff, J., Mohamed Hoesein, F., Fast, M., Computational Imaging, Cancer, Experimentele klinische fysica, Klinische Fysica RT, Team Medisch, Circulatory Health, MS Radiotherapie, MS Radiologie, Mandija, S., Akdag, O., van Lier, A., Borman, P., Schakel, T., Alberts, E., van der Heide, O., Hassink, R., Alings, M., Verhoeff, J., Mohamed Hoesein, F., and Fast, M.

Published
2021

23. The noise navigator: a surrogate for respiratory-correlated 4D-MRI for motion characterization in radiotherapy

Author

Cancer, Computational Imaging, Circulatory Health, Fysica Radiotherapie Research, Klinische Fysica RT, Navest, R J M, Mandija, S, Bruijnen, T, Stemkens, B, Tijssen, R H N, Andreychenko, A, Lagendijk, J J W, van den Berg, C A T, Cancer, Computational Imaging, Circulatory Health, Fysica Radiotherapie Research, Klinische Fysica RT, Navest, R J M, Mandija, S, Bruijnen, T, Stemkens, B, Tijssen, R H N, Andreychenko, A, Lagendijk, J J W, and van den Berg, C A T

Published
2020

24. The noise navigator for MRI-guided radiotherapy: an independent method to detect physiological motion

Author

Computational Imaging, Cancer, Circulatory Health, Klinische Fysica RT, Fysica Radiotherapie Research, Navest, R J M, Mandija, S, Zijlema, S E, Stemkens, B, Andreychenko, A, Lagendijk, J J W, van den Berg, C A T, Computational Imaging, Cancer, Circulatory Health, Klinische Fysica RT, Fysica Radiotherapie Research, Navest, R J M, Mandija, S, Zijlema, S E, Stemkens, B, Andreychenko, A, Lagendijk, J J W, and van den Berg, C A T

Published
2020

25. OC-0586: Can MRI predict pathologic response after single dose neoadjuvant partial breast irradiation?

Author

Vasmel, J., primary, Groot Koerkamp, M., additional, Charaghvandi, R., additional, Vreuls, C., additional, Van Diest, P., additional, Witkamp, A., additional, Koelemij, R., additional, Doeksen, A., additional, Van Dalen, T., additional, Van der Wall, E., additional, Wijnen, J., additional, Van der Velden, B., additional, Moman, M., additional, Veldhuis, W., additional, Philippens, M., additional, Mandija, S., additional, Lagendijk, J., additional, Verkooijen, H., additional, Houweling, A., additional, and Van den Bongard, D., additional

Published
2020
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28. Visualization of gold fiducial markers in the prostate using phase-cycled bSSFP imaging for MRI-only radiotherapy

Author

Shcherbakova, Y., Bartels, L.W., Mandija, S., Beld, E., Seevinck, P.R., Voort van Zyp, J.R.N. van der, Kerkmeijer, L.G.W., Moonen, C.T., Lagendijk, J.J., Berg, C.A.T. van den, Shcherbakova, Y., Bartels, L.W., Mandija, S., Beld, E., Seevinck, P.R., Voort van Zyp, J.R.N. van der, Kerkmeijer, L.G.W., Moonen, C.T., Lagendijk, J.J., and Berg, C.A.T. van den

Abstract

Contains fulltext : 215740.pdf (publisher's version ) (Open Access), In this work, we present a new method for visualization of fiducial markers (FMs) in the prostate for MRI-only radiotherapy with a positive contrast directly at the MR console. The method is based on high bandwidth phase-cycled balanced steady-state free precession (bSSFP) sequence, which is available on many clinical scanners, does not require any additional post-processing or software, and has a higher signal-to-noise (SNR) compared to conventional gradient-echo (GE) imaging. Complex phase-cycled bSSFP data is acquired with different RF phase increment settings such that the manifestation of the artifacts around FMs in the acquired complex images is different for each dynamic acquisition and depends on the RF phase increment used. First, we performed numerical simulations to investigate the complex-valued phase-cycled bSSFP signal in the presence of a gold FM, and to investigate the relation of the true physical location of the FM with the geometrical manifestation of the artifacts. Next, to validate the simulations, we performed phantoms and in vivo studies and compared the experimentally obtained artifacts with those predicted in simulations. The accuracy of the method was assessed by comparing the distances between the FM's centers and the center of mass of FMs system measured using phase-cycled bSSFP MR images and using reference CT (or MRI-only) images. The results show accurate (within 1 mm) matching of FMs localization between CT and MR images on five patients, proving the feasibility of in vivo FMs detection on MR images only. The FMs show a positive contrast with respect to the prostate background on real/imaginary phase-cycled bSSFP images, which was confirmed by simulations. The proposed method facilitates robust FMs visualization with positive contrast directly at the MR console, allowing RT technicians to obtain immediate feedback on the anticipated feasibility of accurate FMs localization while the patient is being scanned.

Published
2019

30. Understanding the physical relations governing the noise navigator

Author

Navest, R.J.M., Mandija, S., Andreychenko, A., Raaijmakers, Aalexander J.E., Lagendijk, J.J.W., van den Berg, C.A.T., Navest, R.J.M., Mandija, S., Andreychenko, A., Raaijmakers, Aalexander J.E., Lagendijk, J.J.W., and van den Berg, C.A.T.

Abstract

Purpose: The noise navigator is a passive way to detect physiological motion occurring in a patient through thermal noise modulations measured by standard clinical radiofrequency receive coils. The aim is to gain a deeper understanding of the potential and applications of physiologically induced thermal noise modulations. Methods: Numerical electromagnetic simulations and MR measurements were performed to investigate the relative contribution of tissue displacement versus modulation of the dielectric lung properties over the respiratory cycle, the impact of coil diameter and position with respect to the body. Furthermore, the spatial motion sensitivity of specific noise covariance matrix elements of a receive array was investigated. Results: The influence of dielectric lung property variations on the noise variance is negligible compared to tissue displacement. Coil size affected the thermal noise variance modulation, but the location of the coil with respect to the body had a larger impact. The modulation depth of a 15 cm diameter stationary coil approximately 3 cm away from the chest (i.e. radiotherapy setup) was 39.7% compared to 4.2% for a coil of the same size on the chest, moving along with respiratory motion. A combination of particular noise covariance matrix elements creates a specific spatial sensitivity for motion. Conclusions: The insight gained on the physical relations governing the noise navigator will allow for optimized use and development of new applications. An optimized combination of elements from the noise covariance matrix offer new ways of performing, e.g. motion tracking.

Published
2019

31. Understanding the physical relations governing the noise navigator

Author

Computational Imaging, Cancer, Circulatory Health, Klinische Fysica RT, Fysica Radiotherapie Research, Navest, R J M, Mandija, S, Andreychenko, A, Raaijmakers, A J E, Lagendijk, J J W, van den Berg, C A T, Computational Imaging, Cancer, Circulatory Health, Klinische Fysica RT, Fysica Radiotherapie Research, Navest, R J M, Mandija, S, Andreychenko, A, Raaijmakers, A J E, Lagendijk, J J W, and van den Berg, C A T

Published
2019

35. Synthetic CT for single-fraction neoadjuvant partial breast irradiation on an MRI-linac.

Author

Koerkamp, M L Groot, Hond, Y J M de, Maspero, M, Kontaxis, C, Mandija, S, Vasmel, J E, Charaghvandi, R K, Philippens, M E P, van Asselen, B, Bongard, H J G D van den, Hackett, S S, and Houweling, A C

Subjects
SUPINE position, LINEAR accelerators, IRRADIATION, DEEP learning, RIB cage, COMPUTED tomography, BREAST cancer
Abstract

A synthetic computed tomography (sCT) is required for daily plan optimization on an MRI-linac. Yet, only limited information is available on the accuracy of dose calculations on sCT for breast radiotherapy. This work aimed to (1) evaluate dosimetric accuracy of treatment plans for single-fraction neoadjuvant partial breast irradiation (PBI) on a 1.5 T MRI-linac calculated on a) bulk-density sCT mimicking the current MRI-linac workflow and b) deep learning-generated sCT, and (2) investigate the number of bulk-density levels required. For ten breast cancer patients we created three bulk-density sCTs of increasing complexity from the planning-CT, using bulk-density for: (1) body, lungs, and GTV (sCTBD1); (2) volumes for sCTBD1 plus chest wall and ipsilateral breast (sCTBD2); (3) volumes for sCTBD2 plus ribs (sCTBD3); and a deep learning-generated sCT (sCTDL) from a 1.5 T MRI in supine position. Single-fraction neoadjuvant PBI treatment plans for a 1.5 T MRI-linac were optimized on each sCT and recalculated on the planning-CT. Image evaluation was performed by assessing mean absolute error (MAE) and mean error (ME) in Hounsfield Units (HU) between the sCTs and the planning-CT. Dosimetric evaluation was performed by assessing dose differences, gamma pass rates, and dose-volume histogram (DVH) differences. The following results were obtained (median across patients for sCTBD1/sCTBD2/sCTBD3/sCTDL respectively): MAE inside the body contour was 106/104/104/75 HU and ME was 8/9/6/28 HU, mean dose difference in the PTVGTV was 0.15/0.00/0.00/−0.07 Gy, median gamma pass rate (2%/2 mm, 10% dose threshold) was 98.9/98.9/98.7/99.4%, and differences in DVH parameters were well below 2% for all structures except for the skin in the sCTDL. Accurate dose calculations for single-fraction neoadjuvant PBI on an MRI-linac could be performed on both bulk-density and deep learning sCT, facilitating further implementation of MRI-guided radiotherapy for breast cancer. Balancing simplicity and accuracy, sCTBD2 showed the optimal number of bulk-density levels for a bulk-density approach. [ABSTRACT FROM AUTHOR]

Published
2021
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37. the Noise Navigator: exploiting thermal noise to detect physiological motion in MRI

Author

Navest, Robin Johannes Marinus, Lagendijk, J.J.W., van den Berg, C.A.T., Mandija, S., Andreychenko, A., and University Utrecht

Subjects
MRI, thermische ruis, radiologie, radiotherapie, fysiologische beweging
Abstract

MRI is increasingly being used in radiotherapy, because of its superior contrast between the different organs and tumors in comparison to other imaging techniques. For diagnosis, MRI is already standardly used and with the recent clinical availability of hybrid MRI-linac systems, which can acquire MR images during irradiation, the role of MRI is expected to increase even further. There are three stages in which MRI is used, i.e. diagnosis, generation of a treatment plan and treatment guidance. During all three stages, physiological motion (e.g. breathing) is a problem. Due to physiological motion during MRI, a false representation of the anatomy is generated with distortions in the images. As a consequence, these MR images cannot be used for clinical diagnosis or treatment plan generation. During radiotherapy, physiological motion could lead to an underdosage of the tumor and/or overdosage of healthy organs. When motion during MRI and MRI-guided radiotherapy can be measured, the negative effects can be corrected for. For diagnostic scans, the distortions in the images can be reduced. Periodic motion, such as breathing, could be incorporated into the treatment plan by estimating the motion from a 4D-MRI, which describes the anatomy during a full cycle of the periodic motion. During radiotherapy, the treatment could be altered based on the measured motion. In this thesis a novel method to detect motion during MRI and MRI-guided radiotherapy was investigated. This method is based on thermal noise that is measured simultaneous with the MR images and is called the noise navigator. First the physics behind the noise navigator was investigated through numerical electromagnetic simulation on a realistic 4D digital human phantom containing respiratory and cardiac motion. These simulations were validated with measurements on healthy volunteers. Insight was gained on the effect of the setup on the sensitivity of the noise navigator to motion. The second step was to investigate the behavior of the noise navigator during MRI. Practical considerations such as the effect of the number of thermal noise samples and the combination of noise measured by the different channels within an RF receive array were evaluated. Furthermore, a Kalman filter was designed that could enable prospective motion correction based on the noise navigator. Next, the feasibility of respiratory-correlated 4D-MRI generation based on the noise navigator was demonstrated for cartesian and radial readout strategies. These 4D-MR images were compared to 4D-MRI generated with conventional methods. The noise navigator would be valuable for this application as there are at the moment no comparable methods for cartesian acquisitions. Finally, the detection a variety of motion types with the noise navigator for three different anatomical applications of MRI-guided radiotherapy were investigated. It was feasible to simultaneously detection bulk body movement and respiration in the torso, swallowing for head-and-neck, and cardiac activity. Although the latter requires more research.

Published
2020

38. Auto-contouring of cardiac substructures for Stereotactic arrhythmia radioablation (STAR): A STOPSTORM.eu consortium study.

Author

van der Pol LHG, Blanck O, Grehn M, Blazek T, Knybel L, Balgobind BV, Verhoeff JJC, Miszczyk M, Blamek S, Reichl S, Andratschke N, Mehrhof F, Boda-Heggemann J, Tomasik B, Mandija S, and Fast MF

Abstract

Background/purpose: High doses to healthy cardiac substructures (CS) in stereotactic arrhythmia radioablation (STAR) raise concerns regarding potential treatment-induced cardio-toxicity. However, CS contours are not routinely created, hindering the understanding of the CS dose-effect relationships. To address this issue, the alignment of CS contouring was initiated within the STOPSTORM consortium. In this study, we developed and evaluated auto-contouring models trained to delineate CS and major vessels in ventricular tachycardia (VT) patients., Methods: Eight centres provided standard treatment planning computed tomography (CT) and/or contrast-enhanced CT datasets of 55 VT patients, each including 16 CS. Auto-contouring models were trained to contour either large structures or small structures. Dice Similarity Coefficient (DSC), 95 % Hausdorff distance (HD95) and volume ratio (VR) were used to evaluate model performance versus inter-observer variation (IOV) on seven VT patient test cases. Significant differences were tested using the Mann-Whitney U test., Results: The performance on the four chambers and the major vessels (median DSC: 0.88; HD95: 5.8-19.4 mm; VR: 1.09) was similar to the IOV (median DSC: 0.89; HD95: 4.8-14.0 mm; VR: 1.20). For the valves, model performance (median DSC: 0.37; HD95: 11.6 mm; VR: 1.63) was similar to the IOV (median DSC: 0.41; HD95: 12.4 mm; VR: 3.42), but slightly worse for the coronary arteries (median DSC: 0.33 vs 0.42; HD95: 24.4 mm vs 16.9 mm; VR: 1.93 vs 3.30). The IOV for these small structures remains large despite using contouring guidelines., Conclusion: CS auto-contouring models trained on VT patient data perform similarly to IOV. This allows for time-efficient evaluation of CS as possible organs-at-risk., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Author(s). Published by Elsevier B.V. All rights reserved.)

Published
2024
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39. Improving the lesion appearance on FLAIR images synthetized from quantitative MRI: a fast, hybrid approach.

Author

Xu F, Mandija S, Kleinloog JPD, Liu H, van der Heide O, van der Kolk AG, Dankbaar JW, van den Berg CAT, and Sbrizzi A

Abstract

Objective: The image quality of synthetized FLAIR (fluid attenuated inversion recovery) images is generally inferior to its conventional counterpart, especially regarding the lesion contrast mismatch. This work aimed to improve the lesion appearance through a hybrid methodology., Materials and Methods: We combined a full brain 5-min MR-STAT acquisition followed by FLAIR synthetization step with an ultra-under sampled conventional FLAIR sequence and performed the retrospective and prospective analysis of the proposed method on the patient datasets and a healthy volunteer., Results: All performance metrics of the proposed hybrid FLAIR images on patient datasets were significantly higher than those of the physics-based FLAIR images (p < 0.005), and comparable to those of conventional FLAIR images. The small difference between prospective and retrospective analysis on a healthy volunteer demonstrated the validity of the retrospective analysis of the hybrid method as presented for the patient datasets., Discussion: The proposed hybrid FLAIR achieved an improved lesion appearance in the clinical cases with neurological diseases compared to the physics-based FLAIR images, Future prospective work on patient data will address the validation of the method from a diagnostic perspective by radiological inspection of the new images over a larger patient cohort., (© 2024. The Author(s).)

Published
2024
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40. Color Maps: Facilitating the Clinical Impact of Quantitative MRI.

Author

Sollmann N, Fuderer M, Crameri F, Weingärtner S, Baeßler B, Gulani V, Keenan KE, Mandija S, Golay X, and deSouza NM

Abstract

Presenting quantitative data using non-standardized color maps potentially results in unrecognized misinterpretation of data. Clinically meaningful color maps should intuitively and inclusively represent data without misleading interpretation. Uniformity of the color gradient for color maps is critically important. Maximal color and lightness contrast, readability for color vision-impaired individuals, and recognizability of the color scheme are highly desirable features. This article describes the use of color maps in five key quantitative MRI techniques: relaxometry, diffusion-weighted imaging (DWI), dynamic contrast-enhanced (DCE)-MRI, MR elastography (MRE), and water-fat MRI. Current display practice of color maps is reviewed and shortcomings against desirable features are highlighted. EVIDENCE LEVEL: 5 TECHNICAL EFFICACY: Stage 2., (© 2024 The Author(s). Journal of Magnetic Resonance Imaging published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine. This article has been contributed to by U.S. Government employees and their work is in the public domain in the USA.)

Published
2024
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41. Unrolled Optimization via Physics-Assisted Convolutional Neural Network for MR-Based Electrical Properties Tomography: A Numerical Investigation.

Author

Zumbo S, Mandija S, Meliado EF, Stijnman P, Meerbothe TG, van den Berg CAT, Isernia T, and Bevacqua MT

Abstract

Magnetic Resonance imaging based Electrical Properties Tomography (MR-EPT) is a non-invasive technique that measures the electrical properties (EPs) of biological tissues. In this work, we present and numerically investigate the performance of an unrolled, physics-assisted method for 2D MR-EPT reconstructions, where a cascade of Convolutional Neural Networks is used to compute the contrast update. Each network takes in input the EPs and the gradient descent direction (encoding the physics underlying the adopted scattering model) and returns as output the updated contrast function. The network is trained and tested in silico using 2D slices of realistic brain models at 128 MHz. Results show the capability of the proposed procedure to reconstruct EPs maps with quality comparable to that of the popular Contrast Source Inversion-EPT, while significantly reducing the computational time., (© 2024 The Authors.)

Published
2024
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42. Generalizable synthetic MRI with physics-informed convolutional networks.

Author

Jacobs L, Mandija S, Liu H, van den Berg CAT, Sbrizzi A, and Maspero M

Subjects
Humans, Brain diagnostic imaging, Neural Networks, Computer, Signal-To-Noise Ratio, Magnetic Resonance Imaging methods, Image Processing, Computer-Assisted methods, Deep Learning
Abstract

Background: Magnetic resonance imaging (MRI) provides state-of-the-art image quality for neuroimaging, consisting of multiple separately acquired contrasts. Synthetic MRI aims to accelerate examinations by synthesizing any desirable contrast from a single acquisition., Purpose: We developed a physics-informed deep learning-based method to synthesize multiple brain MRI contrasts from a single 5-min acquisition and investigate its ability to generalize to arbitrary contrasts., Methods: A dataset of 55 subjects acquired with a clinical MRI protocol and a 5-min transient-state sequence was used. The model, based on a generative adversarial network, maps data acquired from the five-minute scan to "effective" quantitative parameter maps (q*-maps), feeding the generated PD, T 1 , and T 2 maps into a signal model to synthesize four clinical contrasts (proton density-weighted, T 1 -weighted, T 2 -weighted, and T 2 -weighted fluid-attenuated inversion recovery), from which losses are computed. The synthetic contrasts are compared to an end-to-end deep learning-based method proposed by literature. The generalizability of the proposed method is investigated for five volunteers by synthesizing three contrasts unseen during training and comparing these to ground truth acquisitions via qualitative assessment and contrast-to-noise ratio (CNR) assessment., Results: The physics-informed method matched the quality of the end-to-end method for the four standard contrasts, with structural similarity metrics above 0.75 ± 0.08 $0.75\pm 0.08$ ( ± $\pm$ std), peak signal-to-noise ratios above 22.4 ± 1.9 $22.4\pm 1.9$ , representing a portion of compact lesions comparable to standard MRI. Additionally, the physics-informed method enabled contrast adjustment, and similar signal contrast and comparable CNRs to the ground truth acquisitions for three sequences unseen during model training., Conclusions: The study demonstrated the feasibility of physics-informed, deep learning-based synthetic MRI to generate high-quality contrasts and generalize to contrasts beyond the training data. This technology has the potential to accelerate neuroimaging protocols., (© 2023 The Authors. Medical Physics published by Wiley Periodicals LLC on behalf of American Association of Physicists in Medicine.)

Published
2024
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43. Experimental demonstration of real-time cardiac physiology-based radiotherapy gating for improved cardiac radioablation on an MR-linac.

Author

Akdag O, Borman PTS, Mandija S, Woodhead PL, Uijtewaal P, Raaymakers BW, and Fast MF

Subjects
Humans, Adult, Magnetic Resonance Imaging, Breath Holding, Motion, Software, Radiotherapy Planning, Computer-Assisted methods, Radiotherapy Dosage, Radiosurgery, Radiotherapy, Intensity-Modulated methods
Abstract

Background: Cardiac radioablation is a noninvasive stereotactic body radiation therapy (SBRT) technique to treat patients with refractory ventricular tachycardia (VT) by delivering a single high-dose fraction to the VT isthmus. Cardiorespiratory motion induces position uncertainties resulting in decreased dose conformality. Electocardiograms (ECG) are typically used during cardiac MRI (CMR) to acquire images in a predefined cardiac phase, thus mitigating cardiac motion during image acquisition., Purpose: We demonstrate real-time cardiac physiology-based radiotherapy beam gating within a preset cardiac phase on an MR-linac., Methods: MR images were acquired in healthy volunteers (n = 5, mean age = 29.6 years, mean heart-rate (HR) = 56.2 bpm) on the 1.5 T Unity MR-linac (Elekta AB, Stockholm, Sweden) after obtaining written informed consent. The images were acquired using a single-slice balance steady-state free precession (bSSFP) sequence in the coronal or sagittal plane (TR/TE = 3/1.48 ms, flip angle = 48 ∘ $^{\circ }$ , SENSE = 1.5, field-of-view = 400 × 207 $\text{field-of-view} = {400}\times {207}$ mm 2 ${\text{mm}}^{2}$ , voxel size = 3 × 3 × 15 $3\times 3\times 15$ mm 3 ${\rm mm}^{3}$ , partial Fourier factor = 0.65, frame rate = 13.3 Hz). In parallel, a 4-lead ECG-signal was acquired using MR-compatible equipment. The feasibility of ECG-based beam gating was demonstrated with a prototype gating workflow using a Quasar MRI 4D motion phantom (IBA Quasar, London, ON, Canada), which was deployed in the bore of the MR-linac. Two volunteer-derived combined ECG-motion traces (n = 2, mean age = 26 years, mean HR = 57.4 bpm, peak-to-peak amplitude = 14.7 mm) were programmed into the phantom to mimic dose delivery on a cardiac target in breath-hold. Clinical ECG-equipment was connected to the phantom for ECG-voltage-streaming in real-time using research software. Treatment beam gating was performed in the quiescent phase (end-diastole). System latencies were compensated by delay time correction. A previously developed MRI-based gating workflow was used as a benchmark in this study. A 15-beam intensity-modulated radiotherapy (IMRT) plan ( 1 × 6.25 ${1}\times {6.25}$ Gy) was delivered for different motion scenarios onto radiochromic films. Next, cardiac motion was then estimated at the basal anterolateral myocardial wall via normalized cross-correlation-based template matching. The estimated motion signal was temporally aligned with the ECG-signal, which were then used for position- and ECG-based gating simulations in the cranial-caudal (CC), anterior-posterior (AP), and right-left (RL) directions. The effect of gating was investigated by analyzing the differences in residual motion at 30, 50, and 70% treatment beam duty cycles., Results: ECG-based (MRI-based) beam gating was performed with effective duty cycles of 60.5% (68.8%) and 47.7% (50.4%) with residual motion reductions of 62.5% (44.7%) and 43.9% (59.3%). Local gamma analyses (1%/1 mm) returned pass rates of 97.6% (94.1%) and 90.5% (98.3%) for gated scenarios, which exceed the pass rates of 70.3% and 82.0% for nongated scenarios, respectively. In average, the gating simulations returned maximum residual motion reductions of 88%, 74%, and 81% at 30%, 50%, and 70% duty cycles, respectively, in favor of MRI-based gating., Conclusions: Real-time ECG-based beam gating is a feasible alternative to MRI-based gating, resulting in improved dose delivery in terms of high γ -pass $\gamma {\text{-pass}}$ rates, decreased dose deposition outside the PTV and residual motion reduction, while by-passing cardiac MRI challenges., (© 2024 The Authors. Medical Physics published by Wiley Periodicals LLC on behalf of American Association of Physicists in Medicine.)

Published
2024
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44. A Framework for Assessing the Effect of Cardiac and Respiratory Motion for Stereotactic Arrhythmia Radioablation Using a Digital Phantom With a 17-Segment Model: A STOPSTORM.eu Consortium Study.

Author

Stevens RRF, Hazelaar C, Bogowicz M, Ter Bekke RMA, Volders PGA, Verhoeven K, de Ruysscher D, Verhoeff JJC, Fast MF, Mandija S, Cvek J, Knybel L, Dvorak P, Blanck O, and van Elmpt W

Subjects
Humans, Heart Ventricles diagnostic imaging, Heart Ventricles radiation effects, Motion, Four-Dimensional Computed Tomography, Arrhythmias, Cardiac, Phantoms, Imaging, Heart diagnostic imaging, Heart radiation effects, Respiration
Abstract

Purpose: The optimal motion management strategy for patients receiving stereotactic arrhythmia radioablation (STAR) for the treatment of ventricular tachycardia (VT) is not fully known. We developed a framework using a digital phantom to simulate cardiorespiratory motion in combination with different motion management strategies to gain insight into the effect of cardiorespiratory motion on STAR., Methods and Materials: The 4-dimensional (4D) extended cardiac-torso (XCAT) phantom was expanded with the 17-segment left ventricular (LV) model, which allowed placement of STAR targets in standardized ventricular regions. Cardiac- and respiratory-binned 4D computed tomography (CT) scans were simulated for free-breathing, reduced free-breathing, respiratory-gating, and breath-hold scenarios. Respiratory motion of the heart was set to population-averaged values of patients with VT: 6, 2, and 1 mm in the superior-inferior, posterior-anterior, and left-right direction, respectively. Cardiac contraction was adjusted by reducing LV ejection fraction to 35%. Target displacement was evaluated for all segments using envelopes encompassing the cardiorespiratory motion. Envelopes incorporating only the diastole plus respiratory motion were created to simulate the scenario where cardiac motion is not fully captured on 4D respiratory CT scans used for radiation therapy planning., Results: The average volume of the 17 segments was 6 cm 3 (1-9 cm 3 ). Cardiac contraction-relaxation resulted in maximum segment (centroid) motion of 4, 6, and 3.5 mm in the superior-inferior, posterior-anterior, and left-right direction, respectively. Cardiac contraction-relaxation resulted in a motion envelope increase of 49% (24%-79%) compared with individual segment volumes, whereas envelopes increased by 126% (79%-167%) if respiratory motion also was considered. Envelopes incorporating only the diastole and respiration motion covered on average 68% to 75% of the motion envelope., Conclusions: The developed LV-segmental XCAT framework showed that free-wall regions display the most cardiorespiratory displacement. Our framework supports the optimization of STAR by evaluating the effect of (cardio)respiratory motion and motion management strategies for patients with VT., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2024
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45. Stereotactic Arrhythmia Radioablation (STAR): Assessment of cardiac and respiratory heart motion in ventricular tachycardia patients - A STOPSTORM.eu consortium review.

Author

Stevens RRF, Hazelaar C, Fast MF, Mandija S, Grehn M, Cvek J, Knybel L, Dvorak P, Pruvot E, Verhoeff JJC, Blanck O, and van Elmpt W

Abstract

Aim: To identify the optimal STereotactic Arrhythmia Radioablation (STAR) strategy for individual patients, cardiorespiratory motion of the target volume in combination with different treatment methodologies needs to be evaluated. However, an authoritative overview of the amount of cardiorespiratory motion in ventricular tachycardia (VT) patients is missing., Methods: In this STOPSTORM consortium study, we performed a literature review to gain insight into cardiorespiratory motion of target volumes for STAR. Motion data and target volumes were extracted and summarized., Results: Out of the 232 studies screened, 56 provided data on cardiorespiratory motion, of which 8 provided motion amplitudes in VT patients (n = 94) and 10 described (cardiac/cardiorespiratory) internal target volumes (ITVs) obtained in VT patients (n = 59). Average cardiac motion of target volumes was < 5 mm in all directions, with maximum values of 8.0, 5.2 and 6.5 mm in Superior-Inferior (SI), Left-Right (LR), Anterior-Posterior (AP) direction, respectively. Cardiorespiratory motion of cardiac (sub)structures showed average motion between 5-8 mm in the SI direction, whereas, LR and AP motions were comparable to the cardiac motion of the target volumes. Cardiorespiratory ITVs were on average 120-284% of the gross target volume. Healthy subjects showed average cardiorespiratory motion of 10-17 mm in SI and 2.4-7 mm in the AP direction., Conclusion: This review suggests that despite growing numbers of patients being treated, detailed data on cardiorespiratory motion for STAR is still limited. Moreover, data comparison between studies is difficult due to inconsistency in parameters reported. Cardiorespiratory motion is highly patient-specific even under motion-compensation techniques. Therefore, individual motion management strategies during imaging, planning, and treatment for STAR are highly recommended., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Authors. Published by Elsevier B.V. All rights reserved.)

Published
2023
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46. Data-driven electrical conductivity brain imaging using 3 T MRI.

Author

Jung KJ, Mandija S, Cui C, Kim JH, Al-Masni MA, Meerbothe TG, Park M, van den Berg CAT, and Kim DH

Subjects
Humans, Brain diagnostic imaging, Electric Conductivity, Phantoms, Imaging, Neuroimaging, Algorithms, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging methods
Abstract

Magnetic resonance electrical properties tomography (MR-EPT) is a non-invasive measurement technique that derives the electrical properties (EPs, e.g., conductivity or permittivity) of tissues in the radiofrequency range (64 MHz for 1.5 T and 128 MHz for 3 T MR systems). Clinical studies have shown the potential of tissue conductivity as a biomarker. To date, model-based conductivity reconstructions rely on numerical assumptions and approximations, leading to inaccuracies in the reconstructed maps. To address such limitations, we propose an artificial neural network (ANN)-based non-linear conductivity estimator trained on simulated data for conductivity brain imaging. Network training was performed on 201 synthesized T2-weighted spin-echo (SE) data obtained from the finite-difference time-domain (FDTD) electromagnetic (EM) simulation. The dataset was composed of an approximated T2-w SE magnitude and transceive phase information. The proposed method was tested three in-silico and in-vivo on two volunteers and three patients' data. For comparison purposes, various conventional phase-based EPT reconstruction methods were used that ignore B 1 + magnitude information, such as Savitzky-Golay kernel combined with Gaussian filter (S-G Kernel), phase-based convection-reaction EPT (cr-EPT), magnitude-weighted polynomial-fitting phase-based EPT (Poly-Fit), and integral-based phase-based EPT (Integral-based). From the in-silico experiments, quantitative analysis showed that the proposed method provides more accurate and improved quality (e.g., high structural preservation) conductivity maps compared to conventional reconstruction methods. Representatively, in the healthy brain in-silico phantom experiment, the proposed method yielded mean conductivity values of 1.97 ± 0.20 S/m for CSF, 0.33 ± 0.04 S/m for WM, and 0.52 ± 0.08 S/m for GM, which were closer to the ground-truth conductivity (2.00, 0.30, 0.50 S/m) than the integral-based method (2.56 ± 2.31, 0.39 ± 0.12, 0.68 ± 0.33 S/m). In-vivo ANN-based conductivity reconstructions were also of improved quality compared to conventional reconstructions and demonstrated network generalizability and robustness to in-vivo data and pathologies. The reported in-vivo brain conductivity values were in agreement with literatures. In addition, the proposed method was observed for various SNR levels (SNR levels = 10, 20, 40, and 58) and repeatability conditions (the eight acquisitions with the number of signal averages = 1). The preliminary investigations on brain tumor patient datasets suggest that the network trained on simulated dataset can generalize to unforeseen in-vivo pathologies, thus demonstrating its potential for clinical applications., (© 2023 The Authors. Human Brain Mapping published by Wiley Periodicals LLC.)

Published
2023
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47. Real-time myocardial landmark tracking for MRI-guided cardiac radio-ablation using Gaussian Processes.

Author

Huttinga NRF, Akdag O, Fast MF, Verhoeff JJC, Mohamed Hoesein FAA, van den Berg CAT, Sbrizzi A, and Mandija S

Subjects
Humans, Heart diagnostic imaging, Myocardium, Imaging, Three-Dimensional methods, Motion, Magnetic Resonance Imaging methods, Radiotherapy, Image-Guided methods
Abstract

Objective. The high speed of cardiorespiratory motion introduces a unique challenge for cardiac stereotactic radio-ablation (STAR) treatments with the MR-linac. Such treatments require tracking myocardial landmarks with a maximum latency of 100 ms, which includes the acquisition of the required data. The aim of this study is to present a new method that allows to track myocardial landmarks from few readouts of MRI data, thereby achieving a latency sufficient for STAR treatments. Approach. We present a tracking framework that requires only few readouts of k-space data as input, which can be acquired at least an order of magnitude faster than MR-images. Combined with the real-time tracking speed of a probabilistic machine learning framework called Gaussian Processes, this allows to track myocardial landmarks with a sufficiently low latency for cardiac STAR guidance, including both the acquisition of required data, and the tracking inference. Main results. The framework is demonstrated in 2D on a motion phantom, and in vivo on volunteers and a ventricular tachycardia (arrhythmia) patient. Moreover, the feasibility of an extension to 3D was demonstrated by in silico 3D experiments with a digital motion phantom. The framework was compared with template matching-a reference, image-based, method-and linear regression methods. Results indicate an order of magnitude lower total latency (<10 ms) for the proposed framework in comparison with alternative methods. The root-mean-square-distances and mean end-point-distance with the reference tracking method was less than 0.8 mm for all experiments, showing excellent (sub-voxel) agreement. Significance. The high accuracy in combination with a total latency of less than 10 ms-including data acquisition and processing-make the proposed method a suitable candidate for tracking during STAR treatments. Additionally, the probabilistic nature of the Gaussian Processes also gives access to real-time prediction uncertainties, which could prove useful for real-time quality assurance during treatments., (© 2023 Institute of Physics and Engineering in Medicine.)

Published
2023
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49. Synthetic MRI with Magnetic Resonance Spin TomogrAphy in Time-Domain (MR-STAT): Results from a Prospective Cross-Sectional Clinical Trial.

Author

Kleinloog JPD, Mandija S, D'Agata F, Liu H, van der Heide O, Koktas B, Dankbaar JW, Keil VC, Vonken EJ, Jacobs SM, van den Berg CAT, Hendrikse J, van der Kolk AG, and Sbrizzi A

Subjects
Adult, Aged, Humans, Middle Aged, Young Adult, Cross-Sectional Studies, Magnetic Resonance Spectroscopy, Prospective Studies, Brain pathology, Magnetic Resonance Imaging methods
Abstract

Background: Magnetic Resonance Spin TomogrAphy in Time-domain (MR-STAT) can reconstruct whole-brain multi-parametric quantitative maps (eg, T 1 , T 2 ) from a 5-minute MR acquisition. These quantitative maps can be leveraged for synthetization of clinical image contrasts., Purpose: The objective was to assess image quality and overall diagnostic accuracy of synthetic MR-STAT contrasts compared to conventional contrast-weighted images., Study Type: Prospective cross-sectional clinical trial., Population: Fifty participants with a median age of 45 years (range: 21-79 years) consisting of 10 healthy participants and 40 patients with neurological diseases (brain tumor, epilepsy, multiple sclerosis or stroke)., Field Strength/sequence: 3T/Conventional contrast-weighted imaging (T 1 /T 2 weighted, proton density [PD] weighted, and fluid-attenuated inversion recovery [FLAIR]) and a MR-STAT acquisition (2D Cartesian spoiled gradient echo with varying flip angle preceded by a non-selective inversion pulse)., Assessment: Quantitative T 1 , T 2 , and PD maps were computed from the MR-STAT acquisition, from which synthetic contrasts were generated. Three neuroradiologists blinded for image type and disease randomly and independently evaluated synthetic and conventional datasets for image quality and diagnostic accuracy, which was assessed by comparison with the clinically confirmed diagnosis., Statistical Tests: Image quality and consequent acceptability for diagnostic use was assessed with a McNemar's test (one-sided α = 0.025). Wilcoxon signed rank test with a one-sided α = 0.025 and a margin of Δ = 0.5 on the 5-level Likert scale was used to assess non-inferiority., Results: All data sets were similar in acceptability for diagnostic use (≥3 Likert-scale) between techniques (T 1 w:P = 0.105, PDw:P = 1.000, FLAIR:P = 0.564). However, only the synthetic MR-STAT T 2 weighted images were significantly non-inferior to their conventional counterpart; all other synthetic datasets were inferior (T 1 w:P = 0.260, PDw:P = 1.000, FLAIR:P = 1.000). Moreover, true positive/negative rates were similar between techniques (conventional: 88%, MR-STAT: 84%)., Data Conclusion: MR-STAT is a quantitative technique that may provide radiologists with clinically useful synthetic contrast images within substantially reduced scan time., Evidence Level: 1 Technical Efficacy: Stage 2., (© 2022 The Authors. Journal of Magnetic Resonance Imaging published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published
2023
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50. STereotactic Arrhythmia Radioablation (STAR): the Standardized Treatment and Outcome Platform for Stereotactic Therapy Of Re-entrant tachycardia by a Multidisciplinary consortium (STOPSTORM.eu) and review of current patterns of STAR practice in Europe.

Author

Grehn M, Mandija S, Miszczyk M, Krug D, Tomasik B, Stickney KE, Alcantara P, Alongi F, Anselmino M, Aranda RS, Balgobind BV, Boda-Heggemann J, Boldt LH, Bottoni N, Cvek J, Elicin O, De Ferrari GM, Hassink RJ, Hazelaar C, Hindricks G, Hurkmans C, Iotti C, Jadczyk T, Jiravsky O, Jumeau R, Kristiansen SB, Levis M, López MA, Martí-Almor J, Mehrhof F, Møller DS, Molon G, Ouss A, Peichl P, Plasek J, Postema PG, Quesada A, Reichlin T, Rordorf R, Rudic B, Saguner AM, Ter Bekke RMA, Torrecilla JL, Troost EGC, Vitolo V, Andratschke N, Zeppenfeld K, Blamek S, Fast M, de Panfilis L, Blanck O, Pruvot E, and Verhoeff JJC

Subjects
Humans, Prospective Studies, Arrhythmias, Cardiac, Heart Ventricles, Treatment Outcome, Tachycardia, Ventricular, Catheter Ablation adverse effects, Catheter Ablation methods
Abstract

The EU Horizon 2020 Framework-funded Standardized Treatment and Outcome Platform for Stereotactic Therapy Of Re-entrant tachycardia by a Multidisciplinary (STOPSTORM) consortium has been established as a large research network for investigating STereotactic Arrhythmia Radioablation (STAR) for ventricular tachycardia (VT). The aim is to provide a pooled treatment database to evaluate patterns of practice and outcomes of STAR and finally to harmonize STAR within Europe. The consortium comprises 31 clinical and research institutions. The project is divided into nine work packages (WPs): (i) observational cohort; (ii) standardization and harmonization of target delineation; (iii) harmonized prospective cohort; (iv) quality assurance (QA); (v) analysis and evaluation; (vi, ix) ethics and regulations; and (vii, viii) project coordination and dissemination. To provide a review of current clinical STAR practice in Europe, a comprehensive questionnaire was performed at project start. The STOPSTORM Institutions' experience in VT catheter ablation (83% ≥ 20 ann.) and stereotactic body radiotherapy (59% > 200 ann.) was adequate, and 84 STAR treatments were performed until project launch, while 8/22 centres already recruited VT patients in national clinical trials. The majority currently base their target definition on mapping during VT (96%) and/or pace mapping (75%), reduced voltage areas (63%), or late ventricular potentials (75%) during sinus rhythm. The majority currently apply a single-fraction dose of 25 Gy while planning techniques and dose prescription methods vary greatly. The current clinical STAR practice in the STOPSTORM consortium highlights potential areas of optimization and harmonization for substrate mapping, target delineation, motion management, dosimetry, and QA, which will be addressed in the various WPs., Competing Interests: Conflict of interests: D.K. has received honoraria from Merck Sharp & Dohme and Pfizer, as well as research funding from Merck KGaA, all outside of the submitted work. M.A. is a consultant for Biosense Webster and Boston Scientific, has received educational grants from Abbott, and is a proctor for Medtronic. J.B.-H. received personal fees from EBAMed SA, Switzerland, outside the submitted work. O.E. received honoraries for participation on advisory board meetings from Merck Serono, MSD, and AstraZeneca concerning oncologic treatments and also received project funding for clinical trials from non-profit organizations, all outside of the submitted work. T.R. gets research grants from the Swiss National Science Foundation, the Swiss Heart Foundation, and the Sitem Insel support fund. Speaker/consulting honoraria or travel support from Abbott/SJM, Bayer, Biosense Webster, Biotronik, Boston Scientific, Daiichi Sankyo, Farapulse, Medtronic, and Pfizer-BMS. Support for the institution’s fellowship programme from Abbott/SJM, Biosense Webster, Biotronik, Boston Scientific and Medtronic. A.S. received educational grants through his institution from Abbott, Bayer Healthcare, Biosense Webster, Biotronik, Boston Scientific, BMS/Pfizer, and Medtronic; and speaker/advisory board fees from Abbott, Bayer Healthcare, Daiichi Sankyo, Medtronic and Novartis. All other authors declare no conflict of interests., (© The Author(s) 2023. Published by Oxford University Press on behalf of the European Society of Cardiology.)

Published
2023
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