Your search keyword '"Fidler F"' showing total 20 results

1. A system for in vivo on-demand ultra-low field Overhauser-enhanced 3D-Magnetic resonance imaging.

Author

Boudries D, Massot P, Parzy E, Seren S, Mellet P, Franconi JM, Miraux S, Bezançon E, Marque SRA, Audran G, Muetzel M, Wintzheimer S, Fidler F, and Thiaudiere E

Subjects

Rats, Animals, Magnetic Resonance Spectroscopy, Nitrogen Oxides chemistry, Magnetic Resonance Imaging methods, Lung

Abstract

Development of very-low field MRI is an active area of research. It aims at reducing operating costs and improve portability. However, the signal-to-noise issue becomes prominent at ultra-low field (<1 mT), especially for molecular imaging purposes that addresses specific biochemical events. In the context of preclinical molecular MRI of abnormal proteolysis the paper describes a MRI system able to produce Overhauser-enhanced MR images in living rats through in situ Dynamic Nuclear Polarization at 206 µT using stable and non-toxic nitroxides. In parallel conventional images are generated at 206 µT following pre-polarization at 20 mT. Results show that nitroxides are visualized in 3D within a few minutes in the lungs, kidneys and bladder post-administration. This system will be used for molecular imaging of inflammation using protease-specific nitroxide probes., 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 Elsevier Inc. All rights reserved.)

Published

2023

2. Design of a mobile, homogeneous, and efficient electromagnet with a large field of view for neonatal low-field MRI.

Author

Lother S, Schiff SJ, Neuberger T, Jakob PM, and Fidler F

Subjects

Algorithms, Ananas, Computer Simulation, Equipment Design, Humans, Infant, Newborn, Magnetic Fields, Magnetics, Signal-To-Noise Ratio, Steel, Head diagnostic imaging, Magnetic Resonance Imaging methods, Magnets

Abstract

Objective: In this work, a prototype of an effective electromagnet with a field-of-view (FoV) of 140 mm for neonatal head imaging is presented. The efficient implementation succeeded by exploiting the use of steel plates as a housing system. We achieved a compromise between large sample volumes, high homogeneity, high B0 field, low power consumption, light weight, simple fabrication, and conserved mobility without the necessity of a dedicated water cooling system., Materials and Methods: The entire magnetic resonance imaging (MRI) system (electromagnet, gradient system, transmit/receive coil, control system) is introduced and its unique features discussed. Furthermore, simulations using a numerical optimization algorithm for magnet and gradient system are presented., Results: Functionality and quality of this low-field scanner operating at 23 mT (generated with 500 W) is illustrated using spin-echo imaging (in-plane resolution 1.6 mm × 1.6 mm, slice thickness 5 mm, and signal-to-noise ratio (SNR) of 23 with a acquisition time of 29 min). B0 field-mapping measurements are presented to characterize the homogeneity of the magnet, and the B0 field limitations of 80 mT of the system are fully discussed., Conclusion: The cryogen-free system presented here demonstrates that this electromagnet with a ferromagnetic housing can be optimized for MRI with an enhanced and homogeneous magnetic field. It offers an alternative to prepolarized MRI designs in both readout field strength and power use. There are multiple indications for the clinical medical application of such low-field devices.

Published

2016

3. Myocardial T1: quantification by using an ECG-triggered radial single-shot inversion-recovery MR imaging sequence.

Author

Gensler D, Mörchel P, Fidler F, Ritter O, Quick HH, Ladd ME, Bauer WR, Ertl G, Jakob PM, and Nordbeck P

Subjects

Adult, Aged, Female, Humans, Male, Middle Aged, Young Adult, Arrhythmias, Cardiac diagnosis, Cardiac Imaging Techniques methods, Electrocardiography, Image Processing, Computer-Assisted, Magnetic Resonance Imaging methods, Myocardial Infarction diagnosis

Abstract

Purpose: To develop and validate a fast cardiac magnetic resonance imaging T1 mapping technique with high spatial resolution based on a radial inversion-recovery (IR) spoiled gradient-echo acquisition., Materials and Methods: Approval for the study was granted by the local institutional review board, and all subjects gave written informed consent. An electrocardiographically triggered radial single-shot IR (TRASSI) sequence was developed in conjunction with a custom-written fitting algorithm. The proposed imaging technique was validated in phantom measurements and then used for cardiac T1 mapping in 62 subjects with or without cardiac disease. The study population included 51 healthy subjects, three patients with arrhythmia, and eight patients with myocardial infarction. The potential heart rate dependency of the TRASSI method was tested by using linear regression analysis. Statistically significant differences between the sexes and various section orientations were analyzed with a Student t test for independent groups and a repeated-measures analysis of variance for dependent groups., Results: High-spatial-resolution T1 maps (1.17 × 1.17 mm) without motion artifacts and without heart rate dependency (slope = -0.0303, R(2) = 0.0000887, P = .899) were acquired with an acquisition time of less than 6 seconds in all subjects. The mean T1 of healthy left ventricular myocardium across all examined subjects was 1031 msec ± 33 (standard deviation). Testing for reproducibility in three individuals with 34 repetitive measurements revealed a mean standard deviation of 4.1 msec (0.412%). Subacute and chronic myocardial infarction could be detected in all eight patients. T1 disturbances due to arrhythmia proved to be minimal in three patients (standard deviation, <1.2%)., Conclusion: Fast and accurate cardiac T1 mapping is feasible within a single-shot IR experiment.

Published

2015

4. MRI Meets MPI: a bimodal MPI-MRI tomograph.

Author

Vogel P, Lother S, Rückert MA, Kullmann WH, Jakob PM, Fidler F, and Behr VC

Subjects

Equipment Design, Image Processing, Computer-Assisted, Magnetic Fields, Magnetic Resonance Imaging instrumentation, Multimodal Imaging instrumentation, Phantoms, Imaging, Magnetic Resonance Imaging methods, Magnetite Nanoparticles chemistry, Multimodal Imaging methods

Abstract

While magnetic particle imaging (MPI) constitutes a novel biomedical imaging technique for tracking superparamagnetic nanoparticles in vivo, unlike magnetic resonance imaging (MRI), it cannot provide anatomical background information. Until now these two modalities have been performed in separate scanners and image co-registration has been hampered by the need to reposition the sample in both systems as similarly as possible. This paper presents a bimodal MPI-MRI-tomograph that combines both modalities in a single system.MPI and MRI images can thus be acquired without moving the sample or replacing any parts in the setup. The images acquired with the presented setup show excellent agreement between the localization of the nanoparticles in MPI and the MRI background data. A combination of two highly complementary imaging modalities has been achieved.

Published

2014

5. Spatial phase encoding exploiting the Bloch-Siegert shift effect.

Author

Kartäusch R, Driessle T, Kampf T, Basse-Lüsebrink TC, Hoelscher UC, Jakob PM, Fidler F, and Helluy X

Subjects

Equipment Design, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging instrumentation, Models, Theoretical, Phantoms, Imaging, Plant Stems, Radio Waves, Algorithms, Image Enhancement methods, Magnetic Resonance Imaging methods

Abstract

Objective: The present work introduces an alternative to the conventional B0-gradient spatial phase encoding technique. By applying far off-resonant radiofrequency (RF) pulses, a spatially dependent phase shift is introduced to the on-resonant transverse magnetization. This so-called Bloch-Siegert (BS) phase shift has been recently used for B1(+)-mapping. The current work presents the theoretical background for the BS spatial encoding technique (BS-SET) using RF-gradients., Materials and Methods: Since the BS-gradient leads to nonlinear encoding, an adapted reconstruction method was developed to obtain undistorted images. To replace conventional phase encoding gradients, BS-SET was implemented in a two-dimensional (2D) spin echo sequence on a 0.5 T portable MR scanner., Results: A 2D spin echo (SE) measurement imaged along a single dimension using the BS-SET was compared to a conventional SE 2D measurement. The proposed reconstruction method yielded undistorted images., Conclusions: BS-gradients were demonstrated as a feasible option for spatial phase encoding. Furthermore, undistorted BS-SET images could be obtained using the proposed reconstruction method.

Published

2014

6. 3D gradient system for two B0 field directions in earth's field MRI.

Author

Lother S, Hoelscher U, Kampf T, Jakob P, and Fidler F

Subjects

Algorithms, Computer Simulation, Equipment Design, Magnetic Fields, Electromagnetic Fields, Imaging, Three-Dimensional instrumentation, Magnetic Resonance Imaging

Abstract

Object: A new gradient system for earth's field magnetic resonance imaging (EFMRI) is presented that can be rotated relatively to the earth's field direction while maintaining the ability to encode images. Orthogonal components of the gradient field are exploited to reduce the number of gradient coils., Materials and Methods: Two favorable orientations of the gradient system relative to the earth's magnetic field (parallel and perpendicular) are discussed. We introduce the theory for the magnetic fields of the new gradient system and illustrate the design of the coil geometries which were worked out with the help of simulations and a numerical optimization algorithm. Field mapping measurements and imaging experiments in the two different orientations of the gradient system were carried out., Results: Orthogonal components of the gradient field take over the role of the additionally needed gradient fields when the gradient system is rotated relative to the earth's magnetic field. The results from the field mapping and imaging experiments verify the presented theory and show the functionality of the new gradient system., Conclusion: The presented system demonstrates that gradient coils can be used for image encoding in multiple directions. This fact can be exploited to realize an EFMRI setup for parallel and perpendicular prepolarization with a single set of gradient coils.

Published

2013

7. Reducing RF-related heating of cardiac pacemaker leads in MRI: implementation and experimental verification of practical design changes.

Author

Nordbeck P, Fidler F, Friedrich MT, Weiss I, Warmuth M, Gensler D, Herold V, Geistert W, Jakob PM, Ertl G, Ritter O, Ladd ME, Bauer WR, and Quick HH

Subjects

Equipment Design, Equipment Failure Analysis, Hot Temperature, Electrodes, Magnetic Resonance Imaging instrumentation, Pacemaker, Artificial

Abstract

There are serious concerns regarding safety when performing magnetic resonance imaging in patients with implanted conductive medical devices, such as cardiac pacemakers, and associated leads, as severe incidents have occurred in the past. In this study, several approaches for altering an implant's lead design were systematically developed and evaluated to enhance the safety of implanted medical devices in a magnetic resonance imaging environment. The individual impact of each design change on radiofrequency heating was then systematically investigated in functional lead prototypes at 1.5 T. Radiofrequency-induced heating could be successfully reduced by three basic changes in conventional pacemaker lead design: (1) increasing the lead tip area, (2) increasing the lead conductor resistance, and (3) increasing outer lead insulation conductivity. The findings show that radiofrequency energy pickup in magnetic resonance imaging can be reduced and, therefore, patient safety can be improved with dedicated construction changes according to a "safe by design" strategy. Incorporation of the described alterations into implantable medical devices such as pacemaker leads can be used to help achieve favorable risk-benefit-ratios when performing magnetic resonance imaging in the respective patient group., (Copyright © 2012 Wiley Periodicals, Inc.)

Published

2012

8. MR safety: fast T₁ thermometry of the RF-induced heating of medical devices.

Author

Gensler D, Fidler F, Ehses P, Warmuth M, Reiter T, Düring M, Ritter O, Ladd ME, Quick HH, Jakob PM, Bauer WR, and Nordbeck P

Subjects

Equipment Failure Analysis instrumentation, Equipment Failure Analysis methods, Temperature, Energy Transfer, Equipment and Supplies, Magnetic Resonance Imaging instrumentation, Magnetic Resonance Imaging methods, Thermography instrumentation, Thermography methods

Abstract

Determining the MR compatibility of medical implants and devices is becoming increasingly relevant. In most cases, the heating of conductive implants due to radiefrequency (RF) excitation pulses is measured by fluoroptic temperature sensors in relevant tests for approval. Another common method to determine these heating effects is MR thermometry using the proton resonance frequency. This method gives good results in homogeneous phantoms. However in many cases, technical shortcomings such as susceptibility artifacts prohibit exact proton resonance frequency thermometry near medical implants. Therefore, this work aimed at developing a fast T₁-based method which allows controlled MR-related heating of a medical implant while simultaneously quantifying the spatial and temporal temperature distribution. To this end, an inversion recovery snapshot Fast Low-Angle Shot (FLASH) sequence was modified with additional off-resonant heating pulses. With an accelerated imaging method and a sliding-window technique, every 7.6 s a new temperature map could be generated with a spatial in-plane resolution of 2 mm. The temperature deviation from calculated temperature values to reference fluoroptic probe was found to be smaller than 1 K., (Copyright © 2012 Wiley Periodicals, Inc.)

Published

2012

9. Quantification and localization of contrast agents using delta relaxation enhanced magnetic resonance at 1.5 T.

Author

Hoelscher UC, Lother S, Fidler F, Blaimer M, and Jakob P

Subjects

Computer Simulation, Contrast Media pharmacokinetics, Image Enhancement methods, Models, Cardiovascular, Phantoms, Imaging, Reproducibility of Results, Sensitivity and Specificity, Tissue Distribution, Algorithms, Image Interpretation, Computer-Assisted methods, Magnetic Resonance Imaging methods, Organometallic Compounds pharmacokinetics

Abstract

Object: Delta relaxation enhanced magnetic resonance (dreMR) is a new imaging technique based on the idea of cycling the magnetic field B (0) during an imaging sequence. The method determines the field dependency of the relaxation rate (relaxation dispersion dR (1)/dB). This quantity is of particular interest in contrast agent imaging because the parameter can be used to determine contrast agent concentrations and increases the ability to localize the contrast agent., Materials and Methods: In this paper dreMR imaging was implemented on a clinical 1.5 T MR scanner combining conventional MR imaging with fast field-cycling. Two improvements to dreMR theory are presented describing the quantification of contrast agent concentrations from dreMR data and a correction for field-cycling with finite ramp times., Results: Experiments demonstrate the use of the extended theory and show the measurement of contrast agent concentrations with the dreMR method. A second experiment performs localization of a contrast agent with a significant improvement in comparison to conventional imaging., Conclusion: dreMR imaging has been extended by a method to quantify contrast agent concentrations and improved for field-cycling with finite ramp times. Robust localization of contrast agents using dreMR imaging has been performed in a sample where conventional imaging delivers inconclusive results.

Published

2012

10. Contrast agent derived determination of the total circulating blood volume using magnetic resonance.

Author

Pannek K, Fidler F, Kartäusch R, Jakob PM, and Hiller KH

Subjects

Animals, Computer Simulation, Contrast Media pharmacokinetics, Image Enhancement methods, Male, Rats, Rats, Wistar, Reproducibility of Results, Sensitivity and Specificity, Algorithms, Blood Volume physiology, Blood Volume Determination methods, Gadolinium DTPA pharmacokinetics, Image Interpretation, Computer-Assisted methods, Magnetic Resonance Imaging methods, Models, Cardiovascular

Abstract

Object: Knowledge of the total circulating blood volume (TCBV) is essential for the treatment of a variety of medical conditions and blood disorders. To date, blood volume analysis is rarely carried out due to the disadvantages of available methods. Our aim was to develop a widely available, simple, fast, yet accurate method for the determination of the total circulating blood volume., Materials and Methods: Magnetic resonance (MR) is a well-established, non-invasive technique. In this article, we present a method that uses MR contrast agents for the determination of the blood volume. The dependence of MR relaxation times on the concentration of MR contrast agents allows the calculation of the volume the contrast agent has been diluted in., Results: In phantom and in vivo experiments we could demonstrate that TCBV can be determined with high accuracy and precision., Conclusion: This work introduces a novel method for the determination of the total circulating blood volume using magnetic resonance contrast agents as tracers.

Published

2012

11. Feasibility of real-time MRI with a novel carbon catheter for interventional electrophysiology.

Author

Nordbeck P, Bauer WR, Fidler F, Warmuth M, Hiller KH, Nahrendorf M, Maxfield M, Wurtz S, Geistert W, Broscheit J, Jakob PM, and Ritter O

Subjects

Animals, Cardiac Pacing, Artificial, Catheter Ablation methods, Electrocardiography, Electrophysiologic Techniques, Cardiac methods, Equipment Design, Feasibility Studies, Swine, Swine, Miniature, Temperature, Carbon, Catheter Ablation instrumentation, Electrophysiologic Techniques, Cardiac instrumentation, Magnetic Resonance Imaging methods

Abstract

Background: Cardiac MRI offers 3D real-time imaging with unsurpassed soft tissue contrast without x-ray exposure. To minimize safety concerns and imaging artifacts in MR-guided interventional electrophysiology (EP), we aimed at developing a setup including catheters for ablation therapy based on carbon technology., Methods and Results: The setup, including a steerable carbon catheter, was tested for safety, image distortion, and feasibility of diagnostic EP studies and radiofrequency ablation at 1.5 T. MRI was performed in 3 different 1.5-T whole-body scanners using various receive coils and pulse sequences. To assess unintentional heating of the catheters by radiofrequency pulses of the MR scanner in vitro, a fluoroptic thermometry system was used to record heating at the catheter tip. Programmed stimulation and ablation therapy was performed in 8 pigs. There was no significant heating of the carbon catheters while using short, repetitive radiofrequency pulses from the MR system. Because there was no image distortion when using the carbon catheters, exact targeting of the lesion sites was possible. Both atrial and ventricular radiofrequency ablation procedures including atrioventricular node modulation were performed successfully in the scanner. Potential complications such as pericardial effusion after intentional perforation of the right ventricular free wall during ablation could be monitored in real time as well., Conclusions: We describe a newly developed EP technology for interventional electrophysiology based on carbon catheters. The feasibility of this approach was demonstrated by safety testing and performing EP studies and ablation therapy with carbon catheters in the MRI environment.

Published

2009

12. Measuring RF-induced currents inside implants: Impact of device configuration on MRI safety of cardiac pacemaker leads.

Author

Nordbeck P, Weiss I, Ehses P, Ritter O, Warmuth M, Fidler F, Herold V, Jakob PM, Ladd ME, Quick HH, and Bauer WR

Subjects

Body Burden, Burns, Electric etiology, Humans, Magnetic Resonance Imaging adverse effects, Radiation Dosage, Radiometry instrumentation, Relative Biological Effectiveness, Burns, Electric prevention & control, Electrodes, Implanted, Equipment Failure Analysis, Magnetic Resonance Imaging methods, Pacemaker, Artificial, Prostheses and Implants, Radiometry methods

Abstract

Radiofrequency (RF)-related heating of cardiac pacemaker leads is a serious concern in magnetic resonance imaging (MRI). Recent investigations suggest such heating to be strongly dependent on an implant's position within the surrounding medium, but this issue is currently poorly understood. In this study, phantom measurements of the RF-induced electric currents inside a pacemaker lead were performed to investigate the impact of the device position and lead configuration on the amount of MRI-related heating at the lead tip. Seven hundred twenty device position/lead path configurations were investigated. The results show that certain configurations are associated with a highly increased risk to develop MRI-induced heating, whereas various configurations do not show any significant heating. It was possible to precisely infer implant heating on the basis of current intensity values measured inside a pacemaker lead. Device position and lead configuration relative to the surrounding medium are crucial to the amount of RF-induced heating in MRI. This indicates that a considerable number of implanted devices may incidentally not develop severe heating in MRI because of their specific configuration in the body. Small variations in configuration can, however, strongly increase the risk for such heating effects, meaning that hazardous situations might appear during MRI.

Published

2009

13. Investigating the locomotion of the sandfish in desert sand using NMR-imaging.

Author

Baumgartner W, Fidler F, Weth A, Habbecke M, Jakob P, Butenweg C, and Böhme W

Subjects

Animals, Behavior, Animal physiology, Models, Biological, Environment, Lizards physiology, Locomotion, Magnetic Resonance Imaging, Silicon Dioxide chemistry

Abstract

The sandfish (Scincus scincus) is a lizard having the remarkable ability to move through desert sand for significant distances. It is well adapted to living in loose sand by virtue of a combination of morphological and behavioural specializations. We investigated the bodyform of the sandfish using 3D-laserscanning and explored its locomotion in loose desert sand using fast nuclear magnetic resonance (NMR) imaging. The sandfish exhibits an in-plane meandering motion with a frequency of about 3 Hz and an amplitude of about half its body length accompanied by swimming-like (or trotting) movements of its limbs. No torsion of the body was observed, a movement required for a digging-behaviour. Simple calculations based on the Janssen model for granular material related to our findings on bodyform and locomotor behaviour render a local decompaction of the sand surrounding the moving sandfish very likely. Thus the sand locally behaves as a viscous fluid and not as a solid material. In this fluidised sand the sandfish is able to "swim" using its limbs.

Published

2008

14. MRI thermometry: Fast mapping of RF-induced heating along conductive wires.

Author

Ehses P, Fidler F, Nordbeck P, Pracht ED, Warmuth M, Jakob PM, and Bauer WR

Subjects

Electric Conductivity, Radio Waves, Reproducibility of Results, Sensitivity and Specificity, Algorithms, Heating methods, Image Interpretation, Computer-Assisted methods, Magnetic Resonance Imaging methods, Thermography methods

Abstract

Conductive implants are in most cases a strict contraindication for MRI examinations, as RF pulses applied during the MRI measurement can lead to severe heating of the surrounding tissue. Understanding and mapping of these heating effects is therefore crucial for determining the circumstances under which patient examinations are safe. The use of fluoroptic probes is the standard procedure for monitoring these heating effects. However, the observed temperature increase is highly dependent on the positioning of such a probe, as it can only determine the temperature locally. Temperature mapping with MRI after RF heating can be used, but cooling effects during imaging lead to a significant underestimation of the heating effect. In this work, an MRI thermometry method was combined with an MRI heating sequence, allowing for temperature mapping during RF heating. This technique may provide new opportunities for implant safety investigations., ((c) 2008 Wiley-Liss, Inc.)

Published

2008

15. Spatial distribution of RF-induced E-fields and implant heating in MRI.

Author

Nordbeck P, Fidler F, Weiss I, Warmuth M, Friedrich MT, Ehses P, Geistert W, Ritter O, Jakob PM, Ladd ME, Quick HH, and Bauer WR

Subjects

Computer Simulation, Radiation Dosage, Scattering, Radiation, Body Temperature physiology, Body Temperature radiation effects, Magnetic Resonance Imaging, Models, Biological, Prostheses and Implants, Radiometry methods

Abstract

The purpose of this study was to assess the distribution of RF-induced E-fields inside a gel-filled phantom of the human head and torso and compare the results with the RF-induced temperature rise at the tip of a straight conductive implant, specifically examining the dependence of the temperature rise on the position of the implant inside the gel. MRI experiments were performed in two different 1.5T MR systems of the same manufacturer. E-field distribution inside the liquid was assessed using a custom measurement system. The temperature rise at the implant tip was measured in various implant positions and orientations using fluoroptic thermometry. The results show that local E-field strength in the direction of the implant is a critical factor in RF-related tissue heating. The actual E-field distribution, which is dependent on phantom/body properties and the MR-system employed, must be considered when assessing the effects of RF power deposition in implant safety investigations., ((c) 2008 Wiley-Liss, Inc.)

Published

2008

16. Quantitative regional oxygen transfer imaging of the human lung.

Author

Arnold JF, Kotas M, Fidler F, Pracht ED, Flentje M, and Jakob PM

Subjects

Carbon Dioxide chemistry, Gases, Humans, Image Processing, Computer-Assisted, Oxygen metabolism, Oxygen Consumption, Reproducibility of Results, Respiration, Carcinoma, Non-Small-Cell Lung diagnosis, Carcinoma, Non-Small-Cell Lung pathology, Echo-Planar Imaging methods, Lung pathology, Lung Neoplasms diagnosis, Lung Neoplasms pathology, Magnetic Resonance Imaging methods, Oxygen chemistry

Abstract

Purpose: To demonstrate that the use of nonquantitative methods in oxygen-enhanced (OE) lung imaging can be problematic and to present a new approach for quantitative OE lung imaging, which fulfills the requirements for easy application in clinical practice., Materials and Methods: A total of 10 healthy volunteers and three non-small-cell lung cancer (NSCLC) patients were examined using a 1.5T scanner. OE imaging was performed using a snapshot fast low-angle shot (FLASH) T(1)-mapping technique (TE = 1.4 msec, TR = 3.5 msec) as well as a series of T(1)-weighted inversion recovery (IR) half- Fourier acquisition single-shot turbo spin-echo (HASTE) (TE(effective) = 43 msec, TE(inter) = 4.2 msec, and inversion time [TI] = 1200 msec) images. Semiquantitative relative signal enhancement ratios (RER) of T(1)-weighted images before and after inhalation of oxygen-enriched gas were compared to the quantitative change in T(1). A hybrid method is proposed that combines the advantages of T(1)-weighted imaging with the quantification provided by T(1)-mapping. To this end, the IR-HASTE images were transformed into quantitative parameter maps. To prevent mismatching and incorrect parameter maps, retrospective image selection was performed using a postprocessing navigator technique., Results: The RER was dependent on the intrinsic values of T(1) in the lung. Quantitative parameters, such as the decrease of T(1) after switching the breathing gas, were more suited to oxygen transfer quantification than to relative signal enhancement. The mean T(1) value during inhalation of room air (T(1,room)) for the volunteers was 1260 msec. This value decreased by about 10% after switching the breathing gas to carbogen. For the patients, the mean T(1,room) value was 1182 msec, which decreased by about 7% when breathing carbogen. The parameter maps generated using the proposed hybrid method deviated, on average, only about 1% from the T(1)-maps., Conclusion: For the purpose of intersubject comparison, OE lung imaging should be performed quantitatively. The proposed hybrid technique produced reliable quantitative results in a short amount of time and, therefore, is suited for clinical use., ((c) 2007 Wiley-Liss, Inc.)

Published

2007

17. Imaging lung function using rapid dynamic acquisition of T1-maps during oxygen enhancement.

Author

Arnold JF, Fidler F, Wang T, Pracht ED, Schmidt M, and Jakob PM

Subjects

Administration, Inhalation, Humans, Pulmonary Gas Exchange physiology, Pulmonary Ventilation physiology, Reproducibility of Results, Sensitivity and Specificity, Image Interpretation, Computer-Assisted methods, Magnetic Resonance Imaging methods, Oxygen administration & dosage, Oxygen Consumption physiology, Respiratory Function Tests methods

Abstract

This paper describes imaging of lung function with oxygen-enhanced MRI using dynamically acquired T1 parameter maps, which allows an accurate, quantitative assessment of time constants of T1-enhancement and therefore lung function. Eight healthy volunteers were examined on a 1.5-T whole-body scanner. Lung T1-maps based on an IR Snapshot FLASH technique (TE = 1.4 ms, TR = 3.5 ms, FA = 7 (composite function )) were dynamically acquired from each subject. Without waiting for full relaxation between subsequent acquisition of T1-maps, one T1-map was acquired every 6.7 s. For comparison, all subjects underwent a standard pulmonary function test (PFT). Oxygen wash-in and wash-out time course curves of T1 relaxation rate (R1)-enhancement were obtained and time constants of oxygen wash-in (w(in)) and wash-out (w(out)) were calculated. Averaged over the whole right lung, the mean w(out) was 43.90 +/- 10.47 s and the mean (w(in)) was 51.20 +/- 15.53 s, thus about 17% higher in magnitude. Wash-in time constants correlated strongly with forced expired volume in one second in percentage of the vital capacity (FEV1 % VC) and with maximum expiratory flow at 25% vital capacity (MEF25), whereas wash-out time constants showed only weak correlation. Using oxygen-enhanced rapid dynamic acquisition of T1-maps, time course curves of R1-enhancement can be obtained. With w(in) and w(out) two new parameters for assessing lung function are available. Therefore, the proposed method has the potential to provide regional information of pulmonary function in various lung diseases., (Copyright 2004 ESMRMB)

Published

2004

18. Myocardial perfusion measurements by spin-labeling under different vasodynamic states.

Author

Fidler F, Wacker CM, Dueren C, Weigel M, Jakob PM, Bauer WR, and Haase A

Subjects

Adenosine, Adult, Female, Humans, Male, Models, Cardiovascular, Oxygen administration & dosage, Rest, Spin Labels, Vasodilator Agents, Ventricular Function, Coronary Circulation physiology, Magnetic Resonance Imaging methods, Myocardium pathology

Abstract

In this study absolute myocardial perfusion was determined using a spin-labeling magnetic resonance imaging (MRI) technique at 2 Tesla. The technique was applied to 16 healthy volunteers at resting conditions, adenosine-induced stress, and oxygen breathing. Overall myocardial quantitative perfusion was determined as 2.3 +/- 0.8 mL/g/min (rest), 4.2 +/- 1.0 mL/g/min (adenosine), and 1.6 +/- 0.6 mL/g/min (oxygen), respectively. T1 of left ventricular blood pool decreased from 1709 +/- 101 ms (rest) to 1423 +/- 61 ms (oxygen), whereas T1 of right ventricular blood did not change significantly (1586 +/- 126 ms and 1558 +/- 150 ms). In conclusion, the presented technique for quantification of myocardial perfusion is an alternative to contrast agent-based methods. The spin labeling method is noninvasive and easily repeatable and it could therefore become an important tool to study changes in myocardial perfusion under different vasodynamic states.

Published

2004

19. Quantitative assessment of myocardial perfusion with a spin-labeling technique: preliminary results in patients with coronary artery disease.

Author

Wacker CM, Fidler F, Dueren C, Hirn S, Jakob PM, Ertl G, Haase A, and Bauer WR

Subjects

Adenosine, Adult, Case-Control Studies, Coronary Disease pathology, Female, Humans, Male, Middle Aged, Perfusion, Pilot Projects, Vasodilator Agents, Coronary Circulation, Coronary Disease diagnosis, Magnetic Resonance Imaging methods, Spin Labels

Abstract

Purpose: To determine perfusion and coronary reserve in human myocardium without contrast agent using a spin labeling technique., Materials and Methods: Assessment of myocardial perfusion is based on T1 measurements after global and slice-selective spin preparation. This magnetic resonance imaging (MRI) technique was applied to 12 healthy volunteers and 16 patients with suspected coronary artery disease under resting conditions and adenosine-induced vasodilatation., Results: In volunteers, quantitative perfusion was calculated as 2.4 +/- 1.2 mL/g/minute (rest) and 3.9 +/- 1.3 mL/g/minute (adenosine), respectively. Perfusion reserve was 2.1 +/- 0.6. In patients, when comparing perfusion reserve in the anterior and posterior myocardium, reduced values according to a stenotic supplying vessel could be seen in seven of 11 patients who underwent stress testing. In these patients, the relative difference of coronary reserve was 44% +/- 18%. Two patients without stenosis of coronary arteries showed no differences in coronary reserve (with a relative change of 2 +/- 2%)., Conclusion: In patients with single-vessel coronary artery disease, differences in coronary reserve were clearly detectable when comparing anterior and posterior myocardium. The spin labeling method is noninvasive and easily repeatable, and it could therefore become an important tool to study changes in myocardial perfusion., (Copyright 2003 Wiley-Liss, Inc.)

Published

2003

20. Microscopic spin tagging (MiST) for flow imaging.

Author

Olt S, Schmitt P, Fidler F, Haase A, and Jakob PM

Subjects

Arteries physiology, Blood Flow Velocity, Feasibility Studies, Magnetic Resonance Imaging instrumentation, Phantoms, Imaging, Sensitivity and Specificity, Image Enhancement methods, Magnetic Resonance Imaging methods, Rheology methods, Spin Labels

Abstract

In this study, a new strategy for slow flow imaging is proposed. The basic idea is to generate flow contrast on a microscopic level below the spatial resolution of an imaging experiment. Since a microscopic spin tagging scheme is used, this concept is called MiST (Microscopic Spin Tagging). MiST is not a single specific measurement sequence, but rather a new flow sensitive preparation concept which is highly flexible and can be carried out in many ways. The common principle in all possible realizations of MiST is a periodic tagging of magnetization in thin planes (100-200 microm) within the imaging voxels by means of spatially selective RF-pulses. Therefore, flow sensitivity occurs via inflow of fresh spins on a microscopic scale. With this approach, short evolution times are sufficient to introduce inflow contrast and a spatial dependence of inflow times is avoided. The flow sensitive preparation and image orientation are also not connected as they are in conventional time-of-flight techniques. Another powerful feature of MiST is that it can be designed as a non-subtraction method, which results in no signal from stationary spins. Here we present a first realization of the MiST concept and its validation in quantitative flow measurements to demonstrate the feasibility of the proposed preparation concept., (Copyright 2002 Elsevier Science B.V.)

Published

2002