Your search keyword '"Winter, Lukas"' showing total 50 results

1. CoSimPy: An open-source python library for MRI radiofrequency Coil EM/Circuit Cosimulation

Author

Zanovello, Umberto, Seifert, Frank, Bottauscio, Oriano, Winter, Lukas, Zilberti, Luca, and Ittermann, Bernd

Published

2022

2. Open‐source magnetic resonance imaging: Improving access, science, and education through global collaboration.

Author

Winter, Lukas, Periquito, João, Kolbitsch, Christoph, Pellicer‐Guridi, Ruben, Nunes, Rita G., Häuer, Martin, Broche, Lionel, and O'Reilly, Tom

Subjects

MAGNETIC resonance imaging, IMAGE registration

Abstract

Open‐source practices and resources in magnetic resonance imaging (MRI) have increased substantially in recent years. This trend started with software and data being published open‐source and, more recently, open‐source hardware designs have become increasingly available. These developments towards a culture of sharing and establishing nonexclusive global collaborations have already improved the reproducibility and reusability of code and designs, while providing a more inclusive approach, especially for low‐income settings. Community‐driven standardization and documentation efforts are further strengthening and expanding these milestones. The future of open‐source MRI is bright and we have just started to discover its full collaborative potential. In this review we will give an overview of open‐source software and open‐source hardware projects in human MRI research. [ABSTRACT FROM AUTHOR]

Published

2024

3. Investigation of alternative RF power limit control methods for 0.5T, 1.5T, and 3T parallel transmission cardiac imaging: A simulation study.

Author

Petzold, Johannes, Schmitter, Sebastian, Silemek, Berk, Winter, Lukas, Speck, Oliver, Ittermann, Bernd, and Seifert, Frank

Subjects

CARDIAC imaging, IMAGE transmission, SAFETY factor in engineering, DIAGNOSTIC imaging, SUPPLY chain management

Abstract

Purpose: To investigate safety and performance aspects of parallel‐transmit (pTx) RF control‐modes for a body coil at B0≤3T$$ {B}_0\le 3\mathrm{T} $$. Methods: Electromagnetic simulations of 11 human voxel models in cardiac imaging position were conducted for B0=0.5T$$ {B}_0=0.5\mathrm{T} $$, 1.5T$$ 1.5\mathrm{T} $$ and 3T$$ 3\mathrm{T} $$ and a body coil with a configurable number of transmit channels (1, 2, 4, 8, 16). Three safety modes were considered: the 'SAR‐controlled mode' (SCM), where specific absorption rate (SAR) is limited directly, a 'phase agnostic SAR‐controlled mode' (PASCM), where phase information is neglected, and a 'power‐controlled mode' (PCM), where the voltage amplitude for each channel is limited. For either mode, safety limits were established based on a set of 'anchor' simulations and then evaluated in 'target' simulations on previously unseen models. The comparison allowed to derive safety factors accounting for varying patient anatomies. All control modes were compared in terms of the B1+$$ {B}_1^{+} $$ amplitude and homogeneity they permit under their respective safety requirements. Results: Large safety factors (approximately five) are needed if only one or two anchor models are investigated but they shrink with increasing number of anchors. The achievable B1+$$ {B}_1^{+} $$ is highest for SCM but this advantage is reduced when the safety factor is included. PCM appears to be more robust against variations of subjects. PASCM performance is mostly in between SCM and PCM. Compared to standard circularly polarized (CP) excitation, pTx offers minor B1+$$ {B}_1^{+} $$ improvements if local SAR limits are always enforced. Conclusion: PTx body coils can safely be used at B0≤3T$$ {B}_0\le 3\mathrm{T} $$. Uncertainties in patient anatomy must be accounted for, however, by simulating many models. [ABSTRACT FROM AUTHOR]

Published

2024

4. YidC from Escherichia coli Forms an Ion-Conducting Pore upon Activation by Ribosomes.

Author

Knyazev, Denis G., Winter, Lukas, Vogt, Andreas, Posch, Sandra, Öztürk, Yavuz, Siligan, Christine, Goessweiner-Mohr, Nikolaus, Hagleitner-Ertugrul, Nora, Koch, Hans-Georg, and Pohl, Peter

Subjects

*ESCHERICHIA coli, *FLUORESCENCE spectroscopy, *ARGININE, *POLYPEPTIDES, *MOLECULES

Abstract

The universally conserved protein YidC aids in the insertion and folding of transmembrane polypeptides. Supposedly, a charged arginine faces its hydrophobic lipid core, facilitating polypeptide sliding along YidC's surface. How the membrane barrier to other molecules may be maintained is unclear. Here, we show that the purified and reconstituted E. coli YidC forms an ion-conducting transmembrane pore upon ribosome or ribosome-nascent chain complex (RNC) binding. In contrast to monomeric YidC structures, an AlphaFold parallel YidC dimer model harbors a pore. Experimental evidence for a dimeric assembly comes from our BN-PAGE analysis of native vesicles, fluorescence correlation spectroscopy studies, single-molecule fluorescence photobleaching observations, and crosslinking experiments. In the dimeric model, the conserved arginine and other residues interacting with nascent chains point into the putative pore. This result suggests the possibility of a YidC-assisted insertion mode alternative to the insertase mechanism. [ABSTRACT FROM AUTHOR]

Published

2023

5. Wirelessly interfacing sensor‐equipped implants and MR scanners for improved safety and imaging.

Author

Silemek, Berk, Seifert, Frank, Petzold, Johannes, Brühl, Rüdiger, Ittermann, Bernd, and Winter, Lukas

Subjects

DEEP brain stimulation, SCANNING systems, MEDICAL equipment, PEARSON correlation (Statistics), ARTIFICIAL implants

Abstract

Purpose: To investigate a novel reduced RF heating method for imaging in the presence of active implanted medical devices (AIMDs) which employs a sensor‐equipped implant that provides wireless feedback. Methods: The implant, consisting of a generator case and a lead, measures RF‐induced E$$ E $$‐fields at the implant tip using a simple sensor in the generator case and transmits these values wirelessly to the MR scanner. Based on the sensor signal alone, parallel transmission (pTx) excitation vectors were calculated to suppress tip heating and maintain image quality. A sensor‐based imaging metric was introduced to assess the image quality. The methodology was studied at 7T in testbed experiments, and at a 3T scanner in an ASTM phantom containing AIMDs instrumented with six realistic deep brain stimulation (DBS) lead configurations adapted from patients. Results: The implant successfully measured RF‐induced E$$ E $$‐fields (Pearson correlation coefficient squared [R2] = 0.93) and temperature rises (R2 = 0.95) at the implant tip. The implant acquired the relevant data needed to calculate the pTx excitation vectors and transmitted them wirelessly to the MR scanner within a single shot RF sequence (<60 ms). Temperature rises for six realistic DBS lead configurations were reduced to 0.03–0.14 K for heating suppression modes compared to 0.52–3.33 K for the worst‐case heating, while imaging quality remained comparable (five of six lead imaging scores were ≥0.80/1.00) to conventional circular polarization (CP) images. Conclusion: Implants with sensors that can communicate with an MR scanner can substantially improve safety for patients in a fast and automated manner, easing the current burden for MR personnel. [ABSTRACT FROM AUTHOR]

Published

2023

6. Radiofrequency applicator concepts for simultaneous MR imaging and hyperthermia treatment of glioblastoma multiforme

Author

Oberacker Eva, Kuehne Andre, Nadobny Jacek, Zschaeck Sebastian, Weihrauch Mirko, Waiczies Helmar, Ghadjar Pirus, Wust Peter, Niendorf Thoralf, and Winter Lukas

Subjects

thermal magnetic resonance, rf heating, hyperthermia, glioblastoma multiforme, rf applicator, Medicine

Abstract

Glioblastoma multiforme is the most frequent and most aggressive malignant brain tumor with de facto no long term curation by the use of current multimodal therapeutic approaches. The efficacy of brachytherapy and enhancing interstitial hyperthermia has been demonstrated. RF heating at ultrahigh fields (B0=7.0T, f=298MHz) has the potential of delivering sufficiently large thermal dosage for hyperthermia of relatively large tumor areas. This work focuses on electromagnetic field (EMF) simulations and provides realistic applicator designs tailored for simultaneous RF heating and MRI. Our simulations took advantage of target volumes derived from patient data, and our preliminary results suggest that RF power can be focused to both a small tumor area and a large clinical target volume.

Published

2017

7. Retrospectively-gated CINE 23Na imaging of the heart at 7.0 Tesla using density-adapted 3D projection reconstruction

Author

Resetar, Ana, Hoffmann, Stefan H., Graessl, Andreas, Winter, Lukas, Waiczies, Helmar, Ladd, Mark E., Niendorf, Thoralf, and Nagel, Armin M.

Published

2015

8. Towards an integrated radiofrequency safety concept for implant carriers in MRI based on sensor‐equipped implants and parallel transmission.

Author

Petzold, Johannes, Schmitter, Sebastian, Silemek, Berk, Winter, Lukas, Speck, Oliver, Ittermann, Bernd, and Seifert, Frank

Subjects

OPTIMIZATION algorithms, RADIO frequency, MAGNETIC resonance imaging, VECTOR spaces, TEMPERATURE sensors, SPINAL implants

Abstract

To protect implant carriers in MRI from excessive radiofrequency (RF) heating it has previously been suggested to assess that hazard via sensors on the implant. Other work recommended parallel transmission (pTx) to actively mitigate implant‐related heating. Here, both ideas are integrated into one comprehensive safety concept where native pTx safety (without implant) is ensured by state‐of‐the‐art field simulations and the implant‐specific hazard is quantified in situ using physical sensors. The concept is demonstrated by electromagnetic simulations performed on a human voxel model with a simplified spinal‐cord implant in an eight‐channel pTx body coil at 3T. To integrate implant and native safety, the sensor signal must be calibrated in terms of an established safety metric (e.g., specific absorption rate [SAR]). Virtual experiments show that E‐field and implant‐current sensors are well suited for this purpose, while temperature sensors require some caution, and B1 probes are inadequate. Based on an implant sensor matrix Qs, constructed in situ from sensor readings, and precomputed native SAR limits, a vector space of safe RF excitations is determined where both global (native) and local (implant‐related) safety requirements are satisfied. Within this safe‐excitation subspace, the solution with the best image quality in terms of B1+ magnitude and homogeneity is then found by a straightforward optimization algorithm. In the investigated example, the optimized pTx shim provides a 3‐fold higher meanB1+ magnitude compared with circularly polarized excitation for a maximum implant‐related temperature increase ∆Timp≤1K. To date, sensor‐equipped implants interfaced to a pTx scanner exist as demonstrator items in research labs, but commercial devices are not yet within sight. This paper aims to demonstrate the significant benefits of such an approach and how this could impact implant‐related RF safety in MRI. Today, the responsibility for safe implant scanning lies with the implant manufacturer and the MRI operator; within the sensor concept, the MRI manufacturer would assume much of the operator's current responsibility. [ABSTRACT FROM AUTHOR]

Published

2023

9. Electrodynamics and radiofrequency antenna concepts for human magnetic resonance at 23.5 T (1 GHz) and beyond

Author

Winter, Lukas and Niendorf, Thoralf

Published

2016

10. Design, evaluation and application of an eight channel transmit/receive coil array for cardiac MRI at 7.0 T

Author

Gräßl, Andreas, Winter, Lukas, Thalhammer, Christof, Renz, Wolfgang, Kellman, Peter, Martin, Conrad, von Knobelsdorff-Brenkenhoff, Florian, Tkachenko, Valeriy, Schulz-Menger, Jeanette, and Niendorf, Thoralf

Published

2013

11. Progress and promises of human cardiac magnetic resonance at ultrahigh fields: A physics perspective

Author

Niendorf, Thoralf, Graessl, Andreas, Thalhammer, Christof, Dieringer, Matthias A., Kraus, Oliver, Santoro, Davide, Fuchs, Katharina, Hezel, Fabian, Waiczies, Sonia, Ittermann, Bernd, and Winter, Lukas

Published

2013

12. Magnetic resonance safety and compatibility of tantalum markers used in proton beam therapy for intraocular tumors: A 7.0 Tesla study

Author

Oberacker, Eva, Paul, Katharina, Huelnhagen, Till, Oezerdem, Celal, Winter, Lukas, Pohlmann, Andreas, Boehmert, Laura, Stachs, Oliver, Heufelder, Jens, Weber, Andreas, Rehak, Matus, Seibel, Ira, and Niendorf, Thoralf

Published

2017

13. 16-channel bow tie antenna transceiver array for cardiac MR at 7.0 tesla

Author

Oezerdem, Celal, Winter, Lukas, Graessl, Andreas, Paul, Katharina, Els, Antje, Weinberger, Oliver, Rieger, Jan, Kuehne, Andre, Dieringer, Matthias, Hezel, Fabian, Voit, Dirk, Frahm, Jens, and Niendorf, Thoralf

Published

2016

14. On the RF Heating of Coronary Stents at 7.0 Tesla MRI

Author

Winter, Lukas, Oberacker, Eva, Özerdem, Celal, Ji, Yiyi, von Knobelsdorff-Brenkenhoff, Florian, Weidemann, Gerd, Ittermann, Bernd, Seifert, Frank, and Niendorf, Thoralf

Published

2015

15. Comparison of three multichannel transmit/receive radiofrequency coil configurations for anatomic and functional cardiac MRI at 7.0T: implications for clinical imaging

Author

Winter, Lukas, Kellman, Peter, Renz, Wolfgang, Gräßl, Andreas, Hezel, Fabian, Thalhammer, Christof, von Knobelsdorff-Brenkenhoff, Florian, Tkachenko, Valeriy, Schulz-Menger, Jeanette, and Niendorf, Thoralf

Published

2012

16. Modular 32-channel transceiver coil array for cardiac MRI at 7.0T

Author

Graessl, Andreas, Renz, Wolfgang, Hezel, Fabian, Dieringer, Matthias A., Winter, Lukas, Oezerdem, Celal, Rieger, Jan, Kellman, Peter, Santoro, Davide, Lindel, Tomasz D., Frauenrath, Tobias, Pfeiffer, Harald, and Niendorf, Thoralf

Published

2014

17. Two-Dimensional Sixteen Channel Transmit/Receive Coil Array for Cardiac MRI at 7.0 T: Design, Evaluation, and Application

Author

Thalhammer, Christof, Renz, Wolfgang, Winter, Lukas, Hezel, Fabian, Rieger, Jan, Pfeiffer, Harald, Graessl, Andreas, Seifert, Frank, Hoffmann, Werner, von Knobelsdorff-Brenkenhoff, Florian, Tkachenko, Valeriy, Schulz-Menger, Jeanette, Kellman, Peter, and Niendorf, Thoralf

Published

2012

18. Experimental and computational evaluation of capacitive hyperthermia.

Author

Beck, Marcus, Wust, Peter, Oberacker, Eva, Rattunde, Alexander, Päßler, Tom, Chrzon, Benjamin, Veltsista, Paraskevi Danai, Nadobny, Jacek, Pellicer, Ruben, Herz, Enrico, Winter, Lukas, Budach, Volker, Zschaeck, Sebastian, and Ghadjar, Pirus

Subjects

FEVER, CANCELLOUS bone, ADIPOSE tissues, ABDOMINAL tumors, PELVIC tumors, PELVIC bones

Abstract

Objective: Hyperthermia as an enhancer of radio- and/or chemotherapy has been confirmed by various trials. Quite a few positive randomized trials have been carried out with capacitive hyperthermia systems (CHS), even though specific absorption rates (SAR) in deep regions are known to be inferior to the established annular-phased array techniques. Due to a lack of systematic SAR measurements for current capacitive technology, we performed phantom measurements in combination with simulation studies. Materials and Methods: According to the current guidelines, homogeneous and inhomogeneous agarose phantoms were manufactured for the commercial CHS Celsius42. Temperature/time curves were registered, and specific absorption rate (SAR) profiles and distributions were derived using the temperature gradient method. We implemented models for electrodes and phantom setups for simulation studies using Sim4Life. Results: For a standard total power of 200 W, we measured effective SAR until depths of 6–8 cm in a homogeneous phantom, which indicates fair heating conditions for tumor diseases in superficial and intermediate depths. A fat layer of 1 cm strongly weakens the SAR, but 10–20 W/kg are still achieved in intermediate to deep regions (2–10 cm). In the phantom setup with integrated bone, we measured low SAR of 5–10 W/kg in the cancellous bone. Our simulations could fairly describe the measured SAR distributions, but predict tendentially higher SAR than measured. Additional simulations suggest that we would achieve higher SAR with vital fatty tissue and bone metastases in clinical situations. Conclusion: Capacitive systems are suitable to heat superficial and medium-deep tumors as well as some bone metastases, and CHS application is feasible for a specific class of patients with pelvic and abdominal tumors. These findings are consistent with positive clinical studies. [ABSTRACT FROM AUTHOR]

Published

2022

19. Rapid safety assessment and mitigation of radiofrequency induced implant heating using small root mean square sensors and the sensor matrix Qs.

Author

Silemek, Berk, Seifert, Frank, Petzold, Johannes, Hoffmann, Werner, Pfeiffer, Harald, Speck, Oliver, Rose, Georg, Ittermann, Bernd, and Winter, Lukas

Subjects

ROOT-mean-squares, RADIO frequency, DETECTORS, ORTHOGRAPHIC projection

Abstract

Purpose: Rapid detection and mitigation of radiofrequency (RF)‐induced implant heating during MRI based on small and low‐cost embedded sensors. Theory and Methods: A diode and a thermistor are embedded at the tip of an elongated mock implant. RF‐induced voltages or temperature change measured by these root mean square (RMS) sensors are used to construct the sensor Q‐Matrix (QS). Hazard prediction, monitoring and parallel transmit (pTx)‐based mitigation using these sensors is demonstrated in benchtop measurements at 300 MHz and within a 3T MRI. Results: QS acquisition and mitigation can be performed in <20 ms demonstrating real‐time capability. The acquisitions can be performed using safe low powers (<3 W) due to the high reading precision of the diode (126 µV) and thermistor (26 µK). The orthogonal projection method used for pTx mitigation was able to reduce the induced signals and temperatures in all 155 investigated locations. Using the QS approach in a pTx capable 3T MRI with either a two‐channel body coil or an eight‐channel head coil, RF‐induced heating was successfully assessed, monitored and mitigated while the image quality outside the implant region was preserved. Conclusion: Small (<1.5 mm3) and low‐cost (<1 €) RMS sensors embedded in an implant can provide all relevant information to predict, monitor and mitigate RF‐induced heating in implants, while preserving image quality. The proposed pTx‐based QS approach is independent of simulations or in vitro testing and therefore complements these existing safety assessments. [ABSTRACT FROM AUTHOR]

Published

2022

20. MRI-Related Heating of Implants and Devices: A Review.

Author

Winter, Lukas, Seifert, Frank, Zilberti, Luca, Murbach, Manuel, and Ittermann, Bernd

Subjects

MAGNETIC resonance imaging, ELECTRICAL impedance tomography, POPULATION aging

Abstract

During an MRI scan, the radiofrequency field from the scanner's transmit coil, but also the switched gradient fields, induce currents in any conductive object in the bore. This makes any metallic medical implant an additional risk for an MRI patient, because those currents can heat up the surrounding tissues to dangerous levels. This is one of the reasons why implants are, until today, considered a contraindication for MRI; for example, by scanner manufacturers. Due to the increasing prevalence of medical implants in our aging societies, such general exclusion is no longer acceptable. Also, it should be no longer needed, because of a much-improved safety-assessment methodology, in particular in the field of numerical simulations. The present article reviews existing literature on implant-related heating effects in MRI. Concepts for risk assessment and quantification are presented and also some first attempts towards an active safety management and risk mitigation. LEVEL OF EVIDENCE: 5 TECHNICAL EFFICACY: Stage 5. [ABSTRACT FROM AUTHOR]

Published

2021

21. Parallel transmission medical implant safety testbed: Real‐time mitigation of RF induced tip heating using time‐domain E‐field sensors.

Author

Winter, Lukas, Silemek, Berk, Petzold, Johannes, Pfeiffer, Harald, Hoffmann, Werner, Seifert, Frank, and Ittermann, Bernd

Subjects

ORTHOGRAPHIC projection, STANDARD deviations, POWER amplifiers, RADIO frequency, HEATING

Abstract

Purpose: To implement a modular, flexible, open‐source hardware configuration for parallel transmission (pTx) experiments on medical implant safety and to demonstrate real‐time mitigation strategies for radio frequency (RF) induced implant heating based on sensor measurements. Methods: The hardware comprises a home‐built 8‐channel pTx system (scalable to 32‐channels), wideband power amplifiers and a positioning system with submillimeter precision. The orthogonal projection (OP) method is used to mitigate RF induced tip heating and to maintain sufficient B1+ for imaging. Experiments are performed at 297MHz and inside a clinical 3T MRI using 8‐channel pTx RF coils, a guidewire substitute inside a phantom with attached thermistor and time‐domain E‐field probes. Results: Repeatability and precision are ~3% for E‐field measurements including guidewire repositioning, ~3% for temperature slopes and an ~6% root‐mean‐square deviation between B1+ measurements and simulations. Real‐time pTx mitigation with the OP mode reduces the E‐fields everywhere within the investigated area with a maximum reduction factor of 26 compared to the circularly polarized mode. Tip heating was measured with ~100 μK resolution and ~14 Hz sampling frequency and showed substantial reduction for the OP vs CP mode. Conclusion: The pTx medical implant safety testbed presents a much‐needed flexible and modular hardware configuration for the in‐vitro assessment of implant safety, covering all field strengths from 0.5‐7 T. Sensor based real‐time mitigation strategies utilizing pTx and the OP method allow to substantially reduce RF induced implant heating while maintaining sufficient image quality without the need for a priori knowledge based on simulations or in‐vitro testing. [ABSTRACT FROM AUTHOR]

Published

2020

22. Wideband Self‐Grounded Bow‐Tie Antenna for Thermal MR.

Author

Eigentler, Thomas Wilhelm, Winter, Lukas, Han, Haopeng, Oberacker, Eva, Kuehne, Andre, Waiczies, Helmar, Schmitter, Sebastian, Boehmert, Laura, Prinz, Christian, Trefna, Hana Dobsicek, and Niendorf, Thoralf

Subjects

BOW-tie antennas, PROTON magnetic resonance, RADIO frequency therapy, ELECTROMAGNETIC fields, WHOLE body imaging, BROADBAND antennas, ANTENNAS (Electronics)

Abstract

The objective of this study was the design, implementation, evaluation and application of a compact wideband self‐grounded bow‐tie (SGBT) radiofrequency (RF) antenna building block that supports anatomical proton (1H) MRI, fluorine (19F) MRI, MR thermometry and broadband thermal intervention integrated in a whole‐body 7.0 T system. Design considerations and optimizations were conducted with numerical electromagnetic field (EMF) simulations to facilitate a broadband thermal intervention frequency of the RF antenna building block. RF transmission (B1+) field efficiency and specific absorption rate (SAR) were obtained in a phantom, and the thigh of human voxel models (Ella, Duke) for 1H and 19F MRI at 7.0 T. B1+ efficiency simulations were validated with actual flip‐angle imaging measurements. The feasibility of thermal intervention was examined by temperature simulations (f = 300, 400 and 500 MHz) in a phantom. The RF heating intervention (Pin = 100 W, t = 120 seconds) was validated experimentally using the proton resonance shift method and fiberoptic probes for temperature monitoring. The applicability of the SGBT RF antenna building block for in vivo 1H and 19F MRI was demonstrated for the thigh and forearm of a healthy volunteer. The SGBT RF antenna building block facilitated 19F and 1H MRI at 7.0 T as well as broadband thermal intervention (234‐561 MHz). For the thigh of the human voxel models, a B1+ efficiency ≥11.8 μT/√kW was achieved at a depth of 50 mm. Temperature simulations and heating experiments in a phantom demonstrated a temperature increase ΔT >7 K at a depth of 10 mm. The compact SGBT antenna building block provides technology for the design of integrated high‐density RF applicators and for the study of the role of temperature in (patho‐) physiological processes by adding a thermal intervention dimension to an MRI device (Thermal MR). [ABSTRACT FROM AUTHOR]

Published

2020

23. Radiofrequency applicator concepts for thermal magnetic resonance of brain tumors at 297 MHz (7.0 Tesla)

Author

Oberacker, Eva, Kuehne, Andre, Oezerdem, Celal, Nadobny, Jacek, Weihrauch, Mirko, Beck, Marcus, Zschaeck, Sebastian, Diesch, Cecilia, Eigentler, Thomas Wilhelm, Waiczies, Helmar, Ghadjar, Pirus, Wust, Peter, Winter, Lukas, and Niendorf, Thoralf

Abstract

Thermal intervention is a potent sensitizer of cells to chemo- and radiotherapy in cancer treatment. Glioblastoma multiforme (GBM) is a potential clinical target, given the cancer’s aggressive nature and resistance to current treatment options. The annular phased array (APA) technique employing electromagnetic waves in the radiofrequency (RF) range allows for localized temperature increase in deep seated target volumes (TVs). Reports on clinical applications of the APA technique in the brain are still missing. Ultrahigh field magnetic resonance (MR) employs higher frequencies than conventional MR and has potential to provide focal temperature manipulation, high resolution imaging and noninvasive temperature monitoring using an integrated RF applicator (ThermalMR). This work examines the applicability of RF applicator concepts for ThermalMR of brain tumors at 297 MHz (7.0 Tesla). Electromagnetic field (EMF) simulations are performed for clinically realistic data based on GBM patients. Two algorithms are used for specific RF energy absorption rate based thermal intervention planning for small and large TVs in the brain, aiming at maximum RF power deposition or RF power uniformity in the TV for 10 RF applicator designs. For both TVs , the power optimization outperformed the uniformity optimization. The best results for the small TV are obtained for the 16 element interleaved RF applicator using an elliptical antenna arrangement with water bolus. The two row elliptical RF applicator yielded the best result for the large TV. This work investigates the capacity of ThermalMR to achieve targeted thermal interventions in model systems resembling human brain tissue and brain tumors. [ABSTRACT FROM AUTHOR]

Published

2020

24. Physical analysis of temperature-dependent effects of amplitude-modulated electromagnetic hyperthermia.

Author

Wust, Peter, Ghadjar, Pirus, Nadobny, Jacek, Beck, Marcus, Kaul, David, Winter, Lukas, and Zschaeck, Sebastian

Published

2019

25. High peak and high average radiofrequency power transmit/receive switch for thermal magnetic resonance.

Author

Ji, Yiyi, Hoffmann, Werner, Pham, Michal, Dunn, Alexander E., Han, Haopeng, Özerdem, Celal, Waiczies, Helmar, Rohloff, Michael, Endemann, Beate, Boyer, Cyrille, Lim, May, Niendorf, Thoralf, and Winter, Lukas

Abstract

Purpose: To study the role of temperature in biological systems, diagnostic contrasts and thermal therapies, RF pulses for MR spin excitation can be deliberately used to apply a thermal stimulus. This application requires dedicated transmit/receive (Tx/Rx) switches that support high peak powers for MRI and high average powers for RF heating. To meet this goal, we propose a high‐performance Tx/Rx switch based on positive‐intrinsic‐negative diodes and quarter‐wavelength (λ/4) stubs. Methods: The λ/4 stubs in the proposed Tx/Rx switch design route the transmitted RF signal directly to the RF coil/antenna without passing through any electronic components (e.g., positive‐intrinsic‐negative diodes). Bench measurements, MRI, MR thermometry, and RF heating experiments were performed at f = 297 MHz (B0 = 7 T) to examine the characteristics and applicability of the switch. Results: The proposed design provided an isolation of −35.7dB/−41.5dB during transmission/reception. The insertion loss was −0.41dB/−0.27dB during transmission/reception. The switch supports high peak (3.9 kW) and high average (120 W) RF powers for MRI and RF heating at f = 297 MHz. High‐resolution MRI of the wrist yielded image quality competitive with that obtained with a conventional Tx/Rx switch. Radiofrequency heating in phantom monitored by MR thermometry demonstrated the switch applicability for thermal modulation. Upon these findings, thermally activated release of a model drug attached to thermoresponsive polymers was demonstrated. Conclusion: The high‐power Tx/Rx switch enables thermal MR applications at 7 T, contributing to the study of the role of temperature in biological systems and diseases. All design files of the switch will be made available open source at www.opensourceimaging.org. [ABSTRACT FROM AUTHOR]

Published

2018

26. Local Multi-Channel RF Surface Coil versus Body RF Coil Transmission for Cardiac Magnetic Resonance at 3 Tesla: Which Configuration Is Winning the Game?

Author

Weinberger, Oliver, Winter, Lukas, Dieringer, Matthias A., Els, Antje, Oezerdem, Celal, Rieger, Jan, Kuehne, Andre, Cassara, Antonino M., Pfeiffer, Harald, Wetterling, Friedrich, and Niendorf, Thoralf

Subjects

*CARDIAC magnetic resonance imaging, *ELECTROMAGNETIC fields, *RADIO frequency, *CARDIAC patients, *HEART transplantation

Abstract

Introduction: The purpose of this study was to demonstrate the feasibility and efficiency of cardiac MR at 3 Tesla using local four-channel RF coil transmission and benchmark it against large volume body RF coil excitation. Methods: Electromagnetic field simulations are conducted to detail RF power deposition, transmission field uniformity and efficiency for local and body RF coil transmission. For both excitation regimes transmission field maps are acquired in a human torso phantom. For each transmission regime flip angle distributions and blood-myocardium contrast are examined in a volunteer study of 12 subjects. The feasibility of the local transceiver RF coil array for cardiac chamber quantification at 3 Tesla is demonstrated. Results: Our simulations and experiments demonstrate that cardiac MR at 3 Tesla using four-channel surface RF coil transmission is competitive versus current clinical CMR practice of large volume body RF coil transmission. The efficiency advantage of the 4TX/4RX setup facilitates shorter repetition times governed by local SAR limits versus body RF coil transmission at whole-body SAR limit. No statistically significant difference was found for cardiac chamber quantification derived with body RF coil versus four-channel surface RF coil transmission. Our simulation also show that the body RF coil exceeds local SAR limits by a factor of ~2 when driven at maximum applicable input power to reach the whole-body SAR limit. Conclusion: Pursuing local surface RF coil arrays for transmission in cardiac MR is a conceptually appealing alternative to body RF coil transmission, especially for patients with implants. [ABSTRACT FROM AUTHOR]

Published

2016

27. W(h)ither human cardiac and body magnetic resonance at ultrahigh fields? technical advances, practical considerations, applications, and clinical opportunities.

Author

Niendorf, Thoralf, Paul, Katharina, Oezerdem, Celal, Graessl, Andreas, Klix, Sabrina, Huelnhagen, Till, Hezel, Fabian, Rieger, Jan, Waiczies, Helmar, Frahm, Jens, Nagel, Armin M., Oberacker, Eva, and Winter, Lukas

Abstract

The objective of this study was to document and review advances and groundbreaking progress in cardiac and body MR at ultrahigh fields (UHF, B0 ≥ 7.0 T) with the goal to attract talent, clinical adopters, collaborations and resources to the biomedical and diagnostic imaging communities. This review surveys traits, advantages and challenges of cardiac and body MR at 7.0 T. The considerations run the gamut from technical advances to clinical opportunities. Key concepts, emerging technologies, practical considerations, frontier applications and future directions of UHF body and cardiac MR are provided. Examples of UHF cardiac and body imaging strategies are demonstrated. Their added value over the kindred counterparts at lower fields is explored along with an outline of research promises. The achievements of cardiac and body UHF-MR are powerful motivators and enablers, since extra speed, signal and imaging capabilities may be invested to overcome the fundamental constraints that continue to hamper traditional cardiac and body MR applications. If practical obstacles, concomitant physics effects and technical impediments can be overcome in equal measure, sophisticated cardiac and body UHF-MR will help to open the door to new MRI and MRS approaches for basic research and clinical science, with the lessons learned at 7.0 T being transferred into broad clinical use including diagnostics and therapy guiding at lower fields. Copyright © 2015 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2016

28. Magnetic resonance thermometry: Methodology, pitfalls and practical solutions.

Author

Winter, Lukas, Oberacker, Eva, Paul, Katharina, Ji, Yiyi, Oezerdem, Celal, Ghadjar, Pirus, Thieme, Alexander, Budach, Volker, Wust, Peter, and Niendorf, Thoralf

Subjects

*CANCER research, *ABLATION techniques, *ONCOLOGY research, *RADIOTHERAPY, *THERMOMETRY

Abstract

Clinically established thermal therapies such as thermoablative approaches or adjuvant hyperthermia treatment rely on accurate thermal dose information for the evaluation and adaptation of the thermal therapy. Intratumoural temperature measurements have been correlated successfully with clinical end points. Magnetic resonance imaging is the most suitable technique for non-invasive thermometry avoiding complications related to invasive temperature measurements. Since the advent of MR thermometry two decades ago, numerous MR thermometry techniques have been developed, continuously increasing accuracy and robustness forin vivoapplications. While this progress was primarily focused on relative temperature mapping, current and future efforts will likely close the gap towards quantitative temperature readings. These efforts are essential to benchmark thermal therapy efficiency, to understand temperature-related biophysical and physiological processes and to use these insights to set new landmarks for diagnostic and therapeutic applications. With that in mind, this review summarises and discusses advances in MR thermometry, providing practical considerations, pitfalls and technical obstacles constraining temperature measurement accuracy, spatial and temporal resolutionin vivo. Established approaches and current trends in thermal therapy hardware are surveyed with respect to potential benefits for MR thermometry. [ABSTRACT FROM AUTHOR]

Published

2016

29. Thermal magnetic resonance: physics considerations and electromagnetic field simulations up to 23.5 Tesla (1GHz).

Author

Winter, Lukas, Oezerdem, Celal, Hoffmann, Werner, van de Lindt, Tessa, Periquito, Joao, Ji, Yiyi, Ghadjar, Pirus, Budach, Volker, Wust, Peter, and Niendorf, Thoralf

Subjects

*RADIO wave therapy, *NUCLEAR magnetic resonance spectroscopy equipment, *ELECTROMAGNETIC fields, *MAGNETIC resonance imaging, *MATHEMATICAL models, *NUCLEAR magnetic resonance spectroscopy, *PHYSICS, *THERMOTHERAPY, *THEORY, *THERAPEUTICS

Abstract

Background: Glioblastoma multiforme is the most common and most aggressive malign brain tumor. The 5-year survival rate after tumor resection and adjuvant chemoradiation is only 10 %, with almost all recurrences occurring in the initially treated site. Attempts to improve local control using a higher radiation dose were not successful so that alternative additive treatments are urgently needed. Given the strong rationale for hyperthermia as part of a multimodal treatment for patients with glioblastoma, non-invasive radio frequency (RF) hyperthermia might significantly improve treatment results.Methods: A non-invasive applicator was constructed utilizing the magnetic resonance (MR) spin excitation frequency for controlled RF hyperthermia and MR imaging in an integrated system, which we refer to as thermal MR. Applicator designs at RF frequencies 300 MHz, 500 MHz and 1GHz were investigated and examined for absolute applicable thermal dose and temperature hotspot size. Electromagnetic field (EMF) and temperature simulations were performed in human voxel models. RF heating experiments were conducted at 300 MHz and 500 MHz to characterize the applicator performance and validate the simulations.Results: The feasibility of thermal MR was demonstrated at 7.0 T. The temperature could be increased by ~11 °C in 3 min in the center of a head sized phantom. Modification of the RF phases allowed steering of a temperature hotspot to a deliberately selected location. RF heating was monitored using the integrated system for MR thermometry and high spatial resolution MRI. EMF and thermal simulations demonstrated that local RF hyperthermia using the integrated system is feasible to reach a maximum temperature in the center of the human brain of 46.8 °C after 3 min of RF heating while surface temperatures stayed below 41 °C. Using higher RF frequencies reduces the size of the temperature hotspot significantly.Conclusion: The opportunities and capabilities of thermal magnetic resonance for RF hyperthermia interventions of intracranial lesions are intriguing. Employing such systems as an alternative additive treatment for glioblastoma multiforme might be able to improve local control by "fighting fire with fire". Interventions are not limited to the human brain and might include temperature driven targeted drug and MR contrast agent delivery and help to understand temperature dependent bio- and physiological processes in-vivo. [ABSTRACT FROM AUTHOR]

Published

2015

30. Sodium MRI of the human heart at 7.0 T: preliminary results.

Author

Graessl, Andreas, Ruehle, Anjuli, Waiczies, Helmar, Resetar, Ana, Hoffmann, Stefan H., Rieger, Jan, Wetterling, Friedrich, Winter, Lukas, Nagel, Armin M., and Niendorf, Thoralf

Abstract

The objective of this work was to examine the feasibility of three-dimensional (3D) and whole heart coverage 23Na cardiac MRI at 7.0 T including single-cardiac-phase and cinematic (cine) regimes. A four-channel transceiver RF coil array tailored for 23Na MRI of the heart at 7.0 T ( f = 78.5 MHz) is proposed. An integrated bow-tie antenna building block is used for 1H MR to support shimming, localization and planning in a clinical workflow. Signal absorption rate simulations and assessment of RF power deposition were performed to meet the RF safety requirements. 23Na cardiac MR was conducted in an in vivo feasibility study. 3D gradient echo (GRE) imaging in conjunction with Cartesian phase encoding (total acquisition time TAQ = 6 min 16 s) and whole heart coverage imaging employing a density-adapted 3D radial acquisition technique ( TAQ = 18 min 20 s) were used. For 3D GRE-based 23Na MRI, acquisition of standard views of the heart using a nominal in-plane resolution of (5.0 × 5.0) mm2 and a slice thickness of 15 mm were feasible. For whole heart coverage 3D density-adapted radial 23Na acquisitions a nominal isotropic spatial resolution of 6 mm was accomplished. This improvement versus 3D conventional GRE acquisitions reduced partial volume effects along the slice direction and enabled retrospective image reconstruction of standard or arbitrary views of the heart. Sodium cine imaging capabilities were achieved with the proposed RF coil configuration in conjunction with 3D radial acquisitions and cardiac gating. Cardiac-gated reconstruction provided an enhancement in blood-myocardium contrast of 20% versus the same data reconstructed without cardiac gating. The proposed transceiver array enables 23Na MR of the human heart at 7.0 T within clinical acceptable scan times. This capability is in positive alignment with the needs of explorations that are designed to examine the potential of 23Na MRI for the assessment of cardiovascular and metabolic diseases. Copyright © 2015 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2015

31. Eight-channel transceiver RF coil array tailored for 1H/19F MR of the human knee and fluorinated drugs at 7.0 T.

Author

Ji, Yiyi, Waiczies, Helmar, Winter, Lukas, Neumanova, Pavla, Hofmann, Daniela, Rieger, Jan, Mekle, Ralf, Waiczies, Sonia, and Niendorf, Thoralf

Abstract

The purpose of this study was to evaluate the feasibility of an eight-channel dual-tuned transceiver surface RF coil array for combined 1H/19F MR of the human knee at 7.0 T following application of 19F-containing drugs. The 1H/19F RF coil array includes a posterior module with two 1H loop elements and two anterior modules, each consisting of one 1H and two 19F elements. The decoupling of neighbor elements is achieved by a shared capacitor. Electromagnetic field simulations were performed to afford uniform transmission fields and to be in accordance with RF safety guidelines. Localized 19F MRS was conducted with 47 and 101 mmol/L of flufenamic acid (FA) - a 19F-containing non-steroidal anti-inflammatory drug - to determine T1 and T2 and to study the 19F signal-to-dose relationship. The suitability of the proposed approach for 1H/19F MR was examined in healthy subjects. Reflection coefficients of each channel were less than −17 dB and coupling between channels was less than −11 dB. QL/ QU was less than 0.5 for all elements. MRS results demonstrated signal stability with 1% variation. T1 and T2 relaxation times changed with concentration of FA: T1/ T2 = 673/31 ms at 101 mmol/L and T1/ T2 = 616/26 ms at 47 mmol/L. A uniform signal and contrast across the patella could be observed in proton imaging. The sensitivity of the RF coil enabled localization of FA ointment administrated to the knee with an in-plane spatial resolution of (1.5 × 1.5) mm2 achieved in a total scan time of approximately three minutes, which is well suited for translational human studies. This study shows the feasibility of combined 1H/19F MRI of the knee at 7.0 T and proposes T1 and T2 mapping methods for quantifying fluorinated drugs in vivo. Further technological developments are necessary to promote real-time bioavailability studies and quantification of 19F-containing medicinal compounds in vivo. Copyright © 2015 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2015

32. Diffusion-Sensitized Ophthalmic Magnetic Resonance Imaging Free of Geometric Distortion at 3.0 and 7.0 T.

Author

Paul, Katharina, Graessl, Andreas, Rieger, Jan, Lysiak, Darius, Huelnhagen, Till, Winter, Lukas, Heidemann, Robin, Lindner, Tobias, Hadlich, Stefan, Zimpfer, Annette, Pohlmann, Andreas, Endemann, Beate, Krüger, Paul-Christian, Langner, Sönke, Stachs, Oliver, and Niendorf, Thoralf

Published

2015

33. On the Subjective Acceptance during Cardiovascular Magnetic Resonance Imaging at 7.0 Tesla.

Author

Klix, Sabrina, Els, Antje, Paul, Katharina, Graessl, Andreas, Oezerdem, Celal, Weinberger, Oliver, Winter, Lukas, Thalhammer, Christof, Huelnhagen, Till, Rieger, Jan, Mehling, Heidrun, Schulz-Menger, Jeanette, and Niendorf, Thoralf

Subjects

CARDIAC magnetic resonance imaging, HEART diseases, MUSCLE contraction, COLOSSAL magnetoresistance, MAGNETIC fields

Abstract

Purpose: This study examines the subjective acceptance during UHF-CMR in a cohort of healthy volunteers who underwent a cardiac MR examination at 7.0T. Methods: Within a period of two-and-a-half years (January 2012 to June 2014) a total of 165 healthy volunteers (41 female, 124 male) without any known history of cardiac disease underwent UHF-CMR. For the assessment of the subjective acceptance a questionnaire was used to examine the participants experience prior, during and after the UHF-CMR examination. For this purpose, subjects were asked to respond to the questionnaire in an exit interview held immediately after the completion of the UHF-CMR examination under supervision of a study nurse to ensure accurate understanding of the questions. All questions were answered with “yes” or “no” including space for additional comments. Results: Transient muscular contraction was documented in 12.7% of the questionnaires. Muscular contraction was reported to occur only during periods of scanning with the magnetic field gradients being rapidly switched. Dizziness during the study was reported by 12.7% of the subjects. Taste of metal was reported by 10.1% of the study population. Light flashes were reported by 3.6% of the entire cohort. 13% of the subjects reported side effects/observations which were not explicitly listed in the questionnaire but covered by the question about other side effects. No severe side effects as vomiting or syncope after scanning occurred. No increase in heart rate was observed during the UHF-CMR exam versus the baseline clinical examination. Conclusions: This study adds to the literature by detailing the subjective acceptance of cardiovascular magnetic resonance imaging examinations at a magnetic field strength of 7.0T. Cardiac MR examinations at 7.0T are well tolerated by healthy subjects. Broader observational and multi-center studies including patient cohorts with cardiac diseases are required to gain further insights into the subjective acceptance of UHF-CMR examinations. [ABSTRACT FROM AUTHOR]

Published

2015

34. Ion Conductivity of the Bacterial Translocation Channel SecYEG Engaged in Translocation.

Author

Knyazev, Denis G., Winter, Lukas, Bauer, Benedikt W., Siligan, Christine, and Pohl, Peter

Subjects

*IONS, *PHYSIOLOGICAL effects of ions, *CHROMOSOMAL translocation, *PHYSIOLOGICAL effects of protons, *ELECTRIC admittance, *THERAPEUTICS

Abstract

While engaged in protein transport, the bacterial translocon SecYEG must maintain the membrane barrier to small ions. The preservation of the proton motif force was attributed to (i) cation exclusion, (ii) engulfment of the nascent chain by the hydrophobic pore ring, and (iii) a half-helix partly plugging the channel. In contrast, we show here that preservation of the proton motif force is due to a voltage-driven conformational change. Preprotein or signal peptide binding to the purified and reconstituted SecYEG results in large cation and anion conductivities only when the membrane potential is small. Physiological values of membrane potential close the activated channel. This voltage- dependent closure is not dependent on the presence of the plug domain and is not affected by mutation of 3 of the 6 constriction residues to glycines. Cellular ion homeostasis is not challenged by the small remaining leak conductance. [ABSTRACT FROM AUTHOR]

Published

2014

35. Ophthalmic Magnetic Resonance Imaging at 7 T Using a 6-Channel Transceiver Radiofrequency Coil Array in Healthy Subjects and Patients With Intraocular Masses.

Author

Graessl, Andreas, Muhle, Maximilian, Schwerter, Michael, Rieger, Jan, Oezerdem, Celal, Santoro, Davide, Lysiak, Darius, Winter, Lukas, Hezel, Fabian, Waiczies, Sonia, Guthoff, Rudolf F., Falke, Karen, Hosten, Norbert, Hadlich, Stefan, Krueger, Paul-Christian, Langner, Soenke, Stachs, Oliver, and Niendorf, Thoralf

Published

2014

36. Design and Evaluation of a Hybrid Radiofrequency Applicator for Magnetic Resonance Imaging and RF Induced Hyperthermia: Electromagnetic Field Simulations up to 14.0 Tesla and Proof-of-Concept at 7.0 Tesla.

Author

Winter, Lukas, Özerdem, Celal, Hoffmann, Werner, Santoro, Davide, Müller, Alexander, Waiczies, Helmar, Seemann, Reiner, Graessl, Andreas, Wust, Peter, and Niendorf, Thoralf

Subjects

*MAGNETIC resonance imaging of the brain, *ELECTROMAGNETIC fields, *ELECTRIC dipole moments, *HYBRID systems, *BRAIN imaging, *BRAIN, *RADIOGRAPHY, *MEDICAL physics, *SIMULATION methods & models

Abstract

This work demonstrates the feasibility of a hybrid radiofrequency (RF) applicator that supports magnetic resonance (MR) imaging and MR controlled targeted RF heating at ultrahigh magnetic fields (B0≥7.0T). For this purpose a virtual and an experimental configuration of an 8-channel transmit/receive (TX/RX) hybrid RF applicator was designed. For TX/RX bow tie antenna electric dipoles were employed. Electromagnetic field simulations (EMF) were performed to study RF heating versus RF wavelength (frequency range: 64 MHz (1.5T) to 600 MHz (14.0T)). The experimental version of the applicator was implemented at B0 = 7.0T. The applicators feasibility for targeted RF heating was evaluated in EMF simulations and in phantom studies. Temperature co-simulations were conducted in phantoms and in a human voxel model. Our results demonstrate that higher frequencies afford a reduction in the size of specific absorption rate (SAR) hotspots. At 7T (298 MHz) the hybrid applicator yielded a 50% iso-contour SAR (iso-SAR-50%) hotspot with a diameter of 43 mm. At 600 MHz an iso-SAR-50% hotspot of 26 mm in diameter was observed. RF power deposition per RF input power was found to increase with B0 which makes targeted RF heating more efficient at higher frequencies. The applicator was capable of generating deep-seated temperature hotspots in phantoms. The feasibility of 2D steering of a SAR/temperature hotspot to a target location was demonstrated by the induction of a focal temperature increase (ΔT = 8.1 K) in an off-center region of the phantom. Temperature simulations in the human brain performed at 298 MHz showed a maximum temperature increase to 48.6C for a deep-seated hotspot in the brain with a size of (19×23×32)mm3 iso-temperature-90%. The hybrid applicator provided imaging capabilities that facilitate high spatial resolution brain MRI. To conclude, this study outlines the technical underpinnings and demonstrates the basic feasibility of an 8-channel hybrid TX/RX applicator that supports MR imaging, MR thermometry and targeted RF heating in one device. [ABSTRACT FROM AUTHOR]

Published

2013

37. Assessment of the right ventricle with cardiovascular magnetic resonance at 7 Tesla.

Author

von Knobelsdorff-Brenkenhoff, Florian, Tkachenko, Valeriy, Winter, Lukas, Rieger, Jan, Thalhammer, Christof, Hezel, Fabian, Graessl, Andreas, Dieringer, Matthias A., Niendorf, Thoralf, and Schulz-Menger, Jeanette

Subjects

MAGNETIC resonance imaging evaluation, RIGHT heart ventricle, PROBABILITY theory, REGRESSION analysis, RESEARCH funding, STATISTICS, DATA analysis, DATA analysis software, DESCRIPTIVE statistics

Abstract

Background: Functional and morphologic assessment of the right ventricle (RV) is of clinical importance. Cardiovascular magnetic resonance (CMR) at 1.5T has become gold standard for RV chamber quantification and assessment of even small wall motion abnormalities, but tissue analysis is still hampered by limited spatial resolution. CMR at 7T promises increased resolution, but is technically challenging. We examined the feasibility of cine imaging at 7T to assess the RV. Methods: Nine healthy volunteers underwent CMR at 7T using a 16-element TX/RX coil and acoustic cardiac gating. 1.5T served as gold standard. At 1.5T, steady-state free-precession (SSFP) cine imaging with voxel size (1.2x1.2x6) mm3 was used; at 7T, fast gradient echo (FGRE) with voxel size (1.2x1.2x6) mm3 and (1.3x1.3x4) mm3 were applied. RV dimensions (RVEDV, RVESV), RV mass (RVM) and RV function (RVEF) were quantified in transverse slices. Overall image quality, image contrast and image homogeneity were assessed in transverse and sagittal views. Results: All scans provided diagnostic image quality. Overall image quality and image contrast of transverse RV views were rated equally for SSFP at 1.5T and FGRE at 7T with voxel size (1.3x1.3x4)mm3. FGRE at 7T provided significantly lower image homogeneity compared to SSFP at 1.5T. RVEDV, RVESV, RVEF and RVM did not differ significantly and agreed close between SSFP at 1.5T and FGRE at 7T (p=0.5850; p=0.5462; p=0.2789; p=0.0743). FGRE at 7T with voxel size (1.3x1.3x4) mm3 tended to overestimate RV volumes compared to SSFP at 1.5T (mean difference of RVEDV 8.2±9.3ml) and to FGRE at 7T with voxel size (1.2x1.2x6) mm3 (mean difference of RVEDV 9.3±8.6ml). Conclusions: FGRE cine imaging of the RV at 7T was feasible and provided good image quality. RV dimensions and function were comparable to SSFP at 1.5T as gold standard. [ABSTRACT FROM AUTHOR]

Published

2013

38. Detailing Radio Frequency Heating Induced by Coronary Stents: A 7.0 Tesla Magnetic Resonance Study.

Author

Santoro, Davide, Winter, Lukas, Müller, Alexander, Vogt, Julia, Renz, Wolfgang, Özerdem, Celal, Grässl, Andreas, Tkachenko, Valeriy, Schulz-Menger, Jeanette, and Niendorf, Thoralf

Subjects

*AMPA receptors, *NERVOUS system, *CHICKENS as laboratory animals, *MOTOR neurons, *GENE expression, *SPINAL cord

Abstract

The sensitivity gain of ultrahigh field Magnetic Resonance (UHF-MR) holds the promise to enhance spatial and temporal resolution. Such improvements could be beneficial for cardiovascular MR. However, intracoronary stents used for treatment of coronary artery disease are currently considered to be contra-indications for UHF-MR. The antenna effect induced by a stent together with RF wavelength shortening could increase local radiofrequency (RF) power deposition at 7.0 T and bears the potential to induce local heating, which might cause tissue damage. Realizing these constraints, this work examines RF heating effects of stents using electro-magnetic field (EMF) simulations and phantoms with properties that mimic myocardium. For this purpose, RF power deposition that exceeds the clinical limits was induced by a dedicated birdcage coil. Fiber optic probes and MR thermometry were applied for temperature monitoring using agarose phantoms containing copper tubes or coronary stents. The results demonstrate an agreement between RF heating induced temperature changes derived from EMF simulations versus MR thermometry. The birdcage coil tailored for RF heating was capable of irradiating power exceeding the specific-absorption rate (SAR) limits defined by the IEC guidelines by a factor of three. This setup afforded RF induced temperature changes up to +27 K in a reference phantom. The maximum extra temperature increase, induced by a copper tube or a coronary stent was less than 3 K. The coronary stents examined showed an RF heating behavior similar to a copper tube. Our results suggest that, if IEC guidelines for local/global SAR are followed, the extra RF heating induced in myocardial tissue by stents may not be significant versus the baseline heating induced by the energy deposited by a tailored cardiac transmit RF coil at 7.0 T, and may be smaller if not insignificant than the extra RF heating observed under the circumstances used in this study. [ABSTRACT FROM AUTHOR]

Published

2012

39. Design, Implementation, Evaluation and Application of a 32-Channel Radio Frequency Signal Generator for Thermal Magnetic Resonance Based Anti-Cancer Treatment.

Author

Han, Haopeng, Eigentler, Thomas Wilhelm, Wang, Shuailin, Kretov, Egor, Winter, Lukas, Hoffmann, Werner, Grass, Eckhard, and Niendorf, Thoralf

Subjects

NUCLEAR magnetic resonance spectroscopy, IMAGING phantoms, RADIO waves, TEMPERATURE, THERMOTHERAPY

Abstract

Thermal Magnetic Resonance (ThermalMR) leverages radio frequency (RF)-induced heating to examine the role of temperature in biological systems and disease. To advance RF heating with multi-channel RF antenna arrays and overcome the shortcomings of current RF signal sources, this work reports on a 32-channel modular signal generator (SGPLL). The SGPLL was designed around phase-locked loop (PLL) chips and a field-programmable gate array chip. To examine the system properties, switching/settling times, accuracy of RF power level and phase shifting were characterized. Electric field manipulation was successfully demonstrated in deionized water. RF heating was conducted in a phantom setup using self-grounded bow-tie RF antennae driven by the SGPLL. Commercial signal generators limited to a lower number of RF channels were used for comparison. RF heating was evaluated with numerical temperature simulations and experimentally validated with MR thermometry. Numerical temperature simulations and heating experiments controlled by the SGPLL revealed the same RF interference patterns. Upon RF heating similar temperature changes across the phantom were observed for the SGPLL and for the commercial devices. To conclude, this work presents the first 32-channel modular signal source for RF heating. The large number of coherent RF channels, wide frequency range and accurate phase shift provided by the SGPLL form a technological basis for ThermalMR controlled hyperthermia anti-cancer treatment. [ABSTRACT FROM AUTHOR]

Published

2020

40. Controlled Release of Therapeutics from Thermoresponsive Nanogels: A Thermal Magnetic Resonance Feasibility Study.

Author

Ji, Yiyi, Winter, Lukas, Navarro, Lucila, Ku, Min-Chi, Periquito, João S., Pham, Michal, Hoffmann, Werner, Theune, Loryn E., Calderón, Marcelo, and Niendorf, Thoralf

Subjects

*MAGNETIC resonance imaging equipment, *CONTROLLED release preparations, *DRUG delivery systems, *POLYMERS, *RADIO waves, *SERUM albumin, *TEMPERATURE, *THERAPEUTICS, *PILOT projects, *NANOMEDICINE, *FLUORESCENT dyes

Abstract

Thermal magnetic resonance (ThermalMR) accommodates radio frequency (RF)-induced temperature modulation, thermometry, anatomic and functional imaging, and (nano)molecular probing in an integrated RF applicator. This study examines the feasibility of ThermalMR for the controlled release of a model therapeutics from thermoresponsive nanogels using a 7.0-tesla whole-body MR scanner en route to local drug-delivery-based anticancer treatments. The capacity of ThermalMR is demonstrated in a model system involving the release of fluorescein-labeled bovine serum albumin (BSA-FITC, a model therapeutic) from nanometer-scale polymeric networks. These networks contain thermoresponsive polymers that bestow environmental responsiveness to physiologically relevant changes in temperature. The release profile obtained for the reference data derived from a water bath setup used for temperature stimulation is in accordance with the release kinetics deduced from the ThermalMR setup. In conclusion, ThermalMR adds a thermal intervention dimension to an MRI device and provides an ideal testbed for the study of the temperature-induced release of drugs, magnetic resonance (MR) probes, and other agents from thermoresponsive carriers. Integrating diagnostic imaging, temperature intervention, and temperature response control, ThermalMR is conceptually appealing for the study of the role of temperature in biology and disease and for the pursuit of personalized therapeutic drug delivery approaches for better patient care. [ABSTRACT FROM AUTHOR]

Published

2020

41. Cover Image.

Author

Eigentler, Thomas Wilhelm, Winter, Lukas, Han, Haopeng, Oberacker, Eva, Kuehne, Andre, Waiczies, Helmar, Schmitter, Sebastian, Boehmert, Laura, Prinz, Christian, Trefna, Hana Dobsicek, and Niendorf, Thoralf

Subjects

BOW-tie antennas, IMAGE

Published

2020

42. Systematic review on the biological effects of electric, magnetic and electromagnetic fields in the intermediate frequency range (300 Hz to 1 MHz).

Author

Bodewein, Lambert, Schmiedchen, Kristina, Dechent, Dagmar, Stunder, Dominik, Graefrath, David, Winter, Lukas, Kraus, Thomas, and Driessen, Sarah

Subjects

*ELECTROMAGNETIC fields, *INTERMEDIATE frequency amplifiers, *BIOLOGICAL systems, *BIOMAGNETISM, *META-analysis

Abstract

Abstract Background Many novel technologies, including induction cookers or wireless power transfer, produce electric fields (EF), magnetic fields (MF) or electromagnetic fields (EMF) in the intermediate frequency (IF) range. The effects of such fields on biological systems, however, have been poorly investigated. The aim of this systematic review was to provide an update of the state of research and to evaluate the potential for adverse effects of EF, MF and EMF in the IF range (300 Hz to 1 MHz) on biological systems. Methods The review was prepared in accordance with PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) guidelines. Methodical limitations in individual studies were assessed using the Office of Health Assessment and Translation (OHAT) Risk of Bias Rating Tool for Human and Animal Studies. Results Fifty-six studies exposing humans, animals or in vitro systems were eligible for this review. In these studies, many different endpoints were examined and most of the findings were obtained in studies with exposure to MF. For most endpoints, however, the reviewed studies yielded inconsistent results, with some studies indicating no effect and some linking IF exposure with adverse effects. In the majority of the included studies, the applied field strengths were above the International Commission on Non-Ionizing Radiation Protection (ICNIRP) reference levels for the general public and the applied frequencies were mainly below 100 kHz. Furthermore, many of the reviewed studies suffered from methodical limitations which lowered the credibility of the reported results. Conclusion Due to the large heterogeneity in study designs, endpoints and exposed systems, as well as the inconsistent results and methodical limitations in many studies, the quality of evidence for adverse effects remains inadequate for drawing a conclusion on investigated biological effects of IF fields for most endpoints. We recommend that in future studies, effects of EF, MF and EMF in the IF range should be investigated more systematically, i.e., studies should consider various frequencies to identify potential frequency-dependent effects and apply different field strengths, especially if threshold-dependent effects are expected. Priority should be given to the investigation of acute effects, like induction of phosphenes, perception, excitation of nerves or muscles and thermal effects. This would be an important step towards the validation of the reference levels recommended by ICNIRP. Furthermore, we recommend that any new studies aim at implementing high quality dosimetry and minimizing sources of risk of bias. Highlights • Biological effects of intermediate frequency fields were systematically analyzed. • Fifty-six experimental studies were eligible. • Weak field strengths and frequencies > 100 kHz have been hardly investigated. • Low quality of evidence for adverse effects for most examined endpoints. • Methodical limitations lowered credibility of the results. [ABSTRACT FROM AUTHOR]

Published

2019

43. The Bacterial Translocon SecYEG Opens upon Ribosome Binding.

Author

Knyazev, Denis G., Lents, Alexander, Krause, Eberhard, Ollinger, Nicole, Siligan, Christine, Papinski, Daniel, Winter, Lukas, Horner, Andreas, and Pohl, Peter

Subjects

*RIBOSOMES, *GENETIC mutation, *MUTANT proteins, *FLUORESCENCE, *LIPOSOMES

Abstract

In co-translational translocation, the ribosome funnel and the channel of the protein translocation complex SecYEG are aligned. For the nascent chain to enter the channel immediately after synthesis, a yet unidentified signal triggers displacement of the SecYEG sealing plug from the pore. Here, we show that ribosome binding to the resting SecYEG channel triggers this conformational transition. The purified and reconstituted SecYEG channel opens to form a large ion-conducting channel, which has the conductivity of the plug deletion mutant. The number of ion-conducting channels inserted into the planar bilayer per fusion event roughly equals the number of SecYEG channels counted by fluorescence correlation spectroscopy in a single proteoliposome. Thus, the open probability of the channel must be close to unity. To prevent the otherwise lethal proton leak, a closed post-translational conformation of the SecYEG complex bound to a ribosome must exist. [ABSTRACT FROM AUTHOR]

Published

2013

44. Joint [Formula: see text] and Image Reconstruction in Low-Field MRI by Physics-Informed Deep-Learning.

Author

Schote D, Winter L, Kolbitsch C, Rose G, Speck O, and Kofler A

Subjects

Humans, Algorithms, Neural Networks, Computer, Magnetic Resonance Imaging methods, Deep Learning, Image Processing, Computer-Assisted methods, Knee diagnostic imaging

Abstract

Objective: We present a model-based image reconstruction approach based on unrolled neural networks which corrects for image distortion and noise in low-field ( B 0  ∼  50 mT) MRI., Methods: Utilising knowledge about the underlying physics, a novel network architecture (SH-Net) is introduced which involves the estimation of spherical harmonic coefficients to guarantee a spatially smooth field map estimate. The SH-Net is integrated in an end-to-end trainable model which jointly estimates the B 0 -field map as well as the image. Experiments were conducted on retrospectively simulated low-field data of human knees., Results: We compare our model to different model-based approaches at distinct noise levels and various B 0 -field distributions. Our results show that our physics-informed neural network approach outperforms the purely model-based methods by improving the PSNR up to 11.7% and the RMSE up to 86.3%., Conclusion: Our end-to-end trained model-based approach outperforms existing methods in reconstructing image and B 0 -field maps in the low-field regime., Significance: low-field MRI is becoming increasingly more popular as it enables access to MR in challenging situations such as intensive care units or resource poor areas. Our method allows for fast and accurate image reconstruction in such low-field imaging with B 0 -inhomogeneity compensation under a wide range of various environmental conditions.

Published

2024

45. Rapid safety assessment and mitigation of radiofrequency induced implant heating using small root mean square sensors and the sensor matrix Q s .

Author

Silemek B, Seifert F, Petzold J, Hoffmann W, Pfeiffer H, Speck O, Rose G, Ittermann B, and Winter L

Subjects

Magnetic Resonance Imaging, Phantoms, Imaging, Prostheses and Implants, Radio Waves, Heating, Hot Temperature

Abstract

Purpose: Rapid detection and mitigation of radiofrequency (RF)-induced implant heating during MRI based on small and low-cost embedded sensors., Theory and Methods: A diode and a thermistor are embedded at the tip of an elongated mock implant. RF-induced voltages or temperature change measured by these root mean square (RMS) sensors are used to construct the sensor Q-Matrix (Q S ). Hazard prediction, monitoring and parallel transmit (pTx)-based mitigation using these sensors is demonstrated in benchtop measurements at 300 MHz and within a 3T MRI., Results: Q S acquisition and mitigation can be performed in <20 ms demonstrating real-time capability. The acquisitions can be performed using safe low powers (<3 W) due to the high reading precision of the diode (126 µV) and thermistor (26 µK). The orthogonal projection method used for pTx mitigation was able to reduce the induced signals and temperatures in all 155 investigated locations. Using the Q S approach in a pTx capable 3T MRI with either a two-channel body coil or an eight-channel head coil, RF-induced heating was successfully assessed, monitored and mitigated while the image quality outside the implant region was preserved., Conclusion: Small (<1.5 mm 3 ) and low-cost (<1 €) RMS sensors embedded in an implant can provide all relevant information to predict, monitor and mitigate RF-induced heating in implants, while preserving image quality. The proposed pTx-based Q S approach is independent of simulations or in vitro testing and therefore complements these existing safety assessments., (© 2021 Physikalisch-Technische Bundesanstalt. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published

2022

46. Open Source 3D Multipurpose Measurement System with Submillimetre Fidelity and First Application in Magnetic Resonance.

Author

Han H, Moritz R, Oberacker E, Waiczies H, Niendorf T, and Winter L

Abstract

Magnetic resonance imaging (MRI) is the mainstay of diagnostic imaging, a versatile instrument for clinical science and the subject of intense research interest. Advancing clinical science, research and technology of MRI requires high fidelity measurements in quantity, location and time of the given physical property. To meet this goal a broad spectrum of commercial measurement systems has been made available. These instruments frequently share in common that they are costly and typically employ closed proprietary hardware and software. This shortcoming makes any adjustment for a specified application difficult if not prohibitive. Recognizing this limitation this work presents COSI Measure, an automated open source measurement system that provides submillimetre resolution, robust configuration and a large working volume to support a versatile range of applications. The submillimetre fidelity and reproducibility/backlash performance were evaluated experimentally. Magnetic field mapping of a single ring Halbach magnet, a 3.0 T and a 7.0 T MR scanner as well as temperature mapping of a radio frequency coil were successfully conducted. Due to its open source nature and versatile construction, the system can be easily modified for other applications. In a resource limited research setting, COSI Measure makes efficient use of laboratory space, financial resources and collaborative efforts.

Published

2017

47. YidC and SecYEG form a heterotetrameric protein translocation channel.

Author

Sachelaru I, Winter L, Knyazev DG, Zimmermann M, Vogt A, Kuttner R, Ollinger N, Siligan C, Pohl P, and Koch HG

Subjects

Escherichia coli chemistry, Models, Molecular, Protein Binding, Protein Conformation, Protein Multimerization, Protein Translocation Systems chemistry, Protein Translocation Systems metabolism, Escherichia coli metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Membrane Transport Proteins chemistry, Membrane Transport Proteins metabolism, SEC Translocation Channels chemistry, SEC Translocation Channels metabolism

Abstract

The heterotrimeric SecYEG complex cooperates with YidC to facilitate membrane protein insertion by an unknown mechanism. Here we show that YidC contacts the interior of the SecY channel resulting in a ligand-activated and voltage-dependent complex with distinct ion channel characteristics. The SecYEG pore diameter decreases from 8 Å to only 5 Å for the YidC-SecYEG pore, indicating a reduction in channel cross-section by YidC intercalation. In the presence of a substrate, YidC relocates to the rim of the pore as indicated by increased pore diameter and loss of YidC crosslinks to the channel interior. Changing the surface charge of the pore by incorporating YidC into the channel wall increases the anion selectivity, and the accompanying change in wall hydrophobicity is liable to alter the partition of helices from the pore into the membrane. This could explain how the exit of transmembrane domains from the SecY channel is facilitated by YidC.

Published

2017

48. Tuning membrane protein mobility by confinement into nanodomains.

Author

Karner A, Nimmervoll B, Plochberger B, Klotzsch E, Horner A, Knyazev DG, Kuttner R, Winkler K, Winter L, Siligan C, Ollinger N, Pohl P, and Preiner J

Subjects

Escherichia coli genetics, Escherichia coli Proteins genetics, Microscopy, Atomic Force methods, Protein Domains, Protein Transport, Escherichia coli chemistry, Escherichia coli Proteins chemistry, Lipid Bilayers chemistry, Membrane Proteins chemistry

Abstract

High-speed atomic force microscopy (HS-AFM) can be used to visualize function-related conformational changes of single soluble proteins. Similar studies of single membrane proteins are, however, hampered by a lack of suitable flat, non-interacting membrane supports and by high protein mobility. Here we show that streptavidin crystals grown on mica-supported lipid bilayers can be used as porous supports for membranes containing biotinylated lipids. Using SecYEG (protein translocation channel) and GlpF (aquaglyceroporin), we demonstrate that the platform can be used to tune the lateral mobility of transmembrane proteins to any value within the dynamic range accessible to HS-AFM imaging through glutaraldehyde-cross-linking of the streptavidin. This allows HS-AFM to study the conformation or docking of spatially confined proteins, which we illustrate by imaging GlpF at sub-molecular resolution and by observing the motor protein SecA binding to SecYEG.

Published

2017

49. Eight-channel transceiver RF coil array tailored for ¹H/¹⁹F MR of the human knee and fluorinated drugs at 7.0 T.

Author

Ji Y, Waiczies H, Winter L, Neumanova P, Hofmann D, Rieger J, Mekle R, Waiczies S, and Niendorf T

Subjects

Adult, Anti-Inflammatory Agents administration & dosage, Anti-Inflammatory Agents pharmacokinetics, Equipment Design, Equipment Failure Analysis, Female, Flufenamic Acid administration & dosage, Humans, Male, Molecular Imaging methods, Reproducibility of Results, Sensitivity and Specificity, Young Adult, Flufenamic Acid pharmacokinetics, Fluorine-19 Magnetic Resonance Imaging instrumentation, Knee physiology, Molecular Imaging instrumentation, Proton Magnetic Resonance Spectroscopy instrumentation, Transducers

Abstract

The purpose of this study was to evaluate the feasibility of an eight-channel dual-tuned transceiver surface RF coil array for combined (1)H/(19)F MR of the human knee at 7.0 T following application of (19)F-containing drugs. The (1)H/(19)F RF coil array includes a posterior module with two (1)H loop elements and two anterior modules, each consisting of one (1)H and two (19)F elements. The decoupling of neighbor elements is achieved by a shared capacitor. Electromagnetic field simulations were performed to afford uniform transmission fields and to be in accordance with RF safety guidelines. Localized (19)F MRS was conducted with 47 and 101 mmol/L of flufenamic acid (FA) – a (19)F-containing non-steroidal anti-inflammatory drug – to determine T1 and T2 and to study the (19)F signal-to-dose relationship. The suitability of the proposed approach for (1)H/(19)F MR was examined in healthy subjects. Reflection coefficients of each channel were less than -17 dB and coupling between channels was less than -11 dB. Q(L)/Q(U) was less than 0.5 for all elements. MRS results demonstrated signal stability with 1% variation. T1 and T2 relaxation times changed with concentration of FA: T1 /T2 = 673/31 ms at 101 mmol/L and T1 /T2 = 616/26 ms at 47 mmol/L. A uniform signal and contrast across the patella could be observed in proton imaging. The sensitivity of the RF coil enabled localization of FA ointment administrated to the knee with an in-plane spatial resolution of (1.5 × 1.5) mm(2) achieved in a total scan time of approximately three minutes, which is well suited for translational human studies. This study shows the feasibility of combined (1)H/(19)F MRI of the knee at 7.0 T and proposes T1 and T2 mapping methods for quantifying fluorinated drugs in vivo. Further technological developments are necessary to promote real-time bioavailability studies and quantification of (19)F-containing medicinal compounds in vivo., (Copyright © 2015 John Wiley & Sons, Ltd.)

Published

2015

50. Real-time determination of skull thickness for a manually-navigated synergistic trepanation tool.

Author

Korff A, Follmann A, Winter L, de la Fuente M, Schmieder K, and Radermacher K

Subjects

Algorithms, Diagnostic Imaging methods, Equipment Design, Humans, Magnetic Resonance Imaging methods, Neurosurgery methods, Neurosurgical Procedures, Reproducibility of Results, Skull anatomy & histology, Software, Surgical Instruments, Time Factors, Tomography, X-Ray Computed methods, Neurosurgery instrumentation, Skull pathology, Trephining instrumentation

Abstract

Trepanation of the skull is a common procedure in neurosurgery with the problems of dural tears and wide cutting gaps. A hand-guided instrument containing a soft-tissue preserving saw whose cutting depth is automatically adapted on the basis of a-priori data (CT, MRI) is envisioned to reduce these problems.

Published

2010