Your search keyword '"Maxim Terekhov"' showing total 15 results

1. B 0 shimming of the human heart at 7T

Author

David Lohr, Maria R. Stefanescu, Stefan Herz, Theresa Reiter, Maxim Terekhov, Laura M. Schreiber, Christoph Juchem, Michael Hock, Aleksander Kosmala, Markus J. Ankenbrand, and Tobias Gassenmaier

Subjects

Physics, Cardiac cycle, Ultrahigh field, Human heart, Spherical harmonics, Shim (magnetism), Human myocardium, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Nuclear magnetic resonance, Cardiac motion, Radiology, Nuclear Medicine and imaging, ddc:610, B0 shimming, 030217 neurology & neurosurgery

Abstract

Purpose Inhomogeneities of the static magnetic B\(_{0}\) field are a major limiting factor in cardiac MRI at ultrahigh field (≥ 7T), as they result in signal loss and image distortions. Different magnetic susceptibilities of the myocardium and surrounding tissue in combination with cardiac motion lead to strong spatio‐temporal B\(_{0}\)‐field inhomogeneities, and their homogenization (B0 shimming) is a prerequisite. Limitations of state‐of‐the‐art shimming are described, regional B\(_{0}\) variations are measured, and a methodology for spherical harmonics shimming of the B\(_{0}\) field within the human myocardium is proposed. Methods The spatial B\(_{0}\)‐field distribution in the heart was analyzed as well as temporal B\(_{0}\)‐field variations in the myocardium over the cardiac cycle. Different shim region‐of‐interest selections were compared, and hardware limitations of spherical harmonics B\(_{0}\) shimming were evaluated by calibration‐based B0‐field modeling. The role of third‐order spherical harmonics terms was analyzed as well as potential benefits from cardiac phase–specific shimming. Results The strongest B\(_{0}\)‐field inhomogeneities were observed in localized spots within the left‐ventricular and right‐ventricular myocardium and varied between systolic and diastolic cardiac phases. An anatomy‐driven shim region‐of‐interest selection allowed for improved B\(_{0}\)‐field homogeneity compared with a standard shim region‐of‐interest cuboid. Third‐order spherical harmonics terms were demonstrated to be beneficial for shimming of these myocardial B\(_{0}\)‐field inhomogeneities. Initial results from the in vivo implementation of a potential shim strategy were obtained. Simulated cardiac phase–specific shimming was performed, and a shim term‐by‐term analysis revealed periodic variations of required currents. Conclusion Challenges in state‐of‐the‐art B\(_{0}\) shimming of the human heart at 7 T were described. Cardiac phase–specific shimming strategies were found to be superior to vendor‐supplied shimming.

Published

2020

2. High‐resolution simulation of B 0 field conditions in the human heart from segmented computed tomography images

Author

Yun Shang, Sebastian Theilenberg, Maxim Terekhov, Wolfram Mattar, Boyu Peng, Sachin R. Jambawalikar, Laura M. Schreiber, and Christoph Juchem

Subjects

Molecular Medicine, Radiology, Nuclear Medicine and imaging, Spectroscopy

Published

2022

3. A novel antisymmetric 16‐element transceiver dipole antenna array for parallel transmit cardiac MRI in pigs at 7 T

Author

Ibrahim A. Elabyad, Maxim Terekhov, David Lohr, Maya Bille, Michael Hock, and Laura M. Schreiber

Subjects

Phantoms, Imaging, Swine, Cadaver, Animals, Molecular Medicine, Heart, Radiology, Nuclear Medicine and imaging, Equipment Design, Signal-To-Noise Ratio, Magnetic Resonance Imaging, Spectroscopy

Abstract

To improve parallel transmit (pTx) and receive performance for cardiac MRI (cMRI) in pigs at 7 T, a dedicated transmit/receive (Tx/Rx), 16-element antisymmetric dipole antenna array, which combines L-shaped and straight dipoles, was designed, implemented, and evaluated in both cadavers and animals in vivo. Electromagnetic-field simulations were performed with the new 16-element dipole antenna array loaded with a pig thorax-shaped phantom and compared with an eight-element array of straight dipoles. The new dipole array was interfaced to a 7 T scanner in pTx mode (8Tx/16Rx). Imaging performance of the novel array was validated through MRI measurements in a pig phantom, an 85 kg pig cadaver, and two pigs in vivo (74 and 81 kg). Due to the improved decoupling between interleaved L-shaped and straight dipole elements, the 16-element dipole array fits within the same outer dimensions as an eight-element array of straight dipoles. This provides improvement of both transmit and receive characteristics and additional degrees of freedom for

Published

2022

4. Longitudinal assessment of tissue properties and cardiac diffusion metrics of the ex vivo porcine heart at 7 T: Impact of continuous tissue fixation using formalin

Author

Laura M. Schreiber, Franziska Veit, David Lohr, and Maxim Terekhov

Subjects

Relaxometry, Tissue Fixation, Swine, Signal-To-Noise Ratio, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Nuclear magnetic resonance, Formaldehyde, Fractional anisotropy, medicine, Animals, Effective diffusion coefficient, Radiology, Nuclear Medicine and imaging, ddc:610, Ventricular remodeling, Spectroscopy, Fixation (histology), medicine.diagnostic_test, Chemistry, Heart, Magnetic resonance imaging, medicine.disease, Diffusion Magnetic Resonance Imaging, Spin echo, Molecular Medicine, Spin Labels, 030217 neurology & neurosurgery, Diffusion MRI

Abstract

In this study we aimed to assess the effects of continuous formalin fixation on diffusion and relaxation metrics of the ex vivo porcine heart at 7 T. Magnetic resonance imaging was performed on eight piglet hearts using a 7 T whole body system. Hearts were measured fresh within 3 hours of cardiac arrest followed by immersion in 10% neutral buffered formalin. T\(_{2}\)* and T\(_{2}\) were assessed using a gradient multi‐echo and multi‐echo spin echo sequence, respectively. A spin echo and a custom stimulated echo sequence were employed to assess diffusion time‐dependent changes in metrics of cardiac diffusion tensor imaging. SNR was determined for b = 0 images. Scans were performed for 5 mm thick apical, midcavity and basal slices (in‐plane resolution: 1 mm) and repeated 7, 15, 50, 100 and 200 days postfixation. Eigenvalues of the apparent diffusion coefficient (ADC) and fractional anisotropy (FA) decreased significantly (P < 0.05) following fixation. Relative to fresh hearts, FA values 7 and 200 days postfixation were 90% and 80%, while respective relative ADC values at those fixation stages were 78% and 92%. Statistical helix and sheetlet angle distributions as well as respective mean and median values showed no systematic influence of continuous formalin fixation. Similar to changes in the ADC, values for T\(_{2}\), T\(_{2}\)* and SNR dropped initially postfixation. Respective relative values compared with fresh hearts at day 7 were 64%, 79% and 68%, whereas continuous fixation restored T\(_{2}\), T\(_{2}\)* and SNR leading to relative values of 74%, 100%, and 81% at day 200, respectively. Relaxation parameters and diffusion metrics are significantly altered by continuous formalin fixation. The preservation of microstructure metrics following prolonged fixation is a key finding that may enable future studies of ventricular remodeling in cardiac pathologies.

Published

2020

5. Dynamic contrast‐enhanced magnetic resonance imaging for monitoring angiogenesis during bone regeneration – a randomized pilot study in rabbits

Author

Junho Jung, Maxim Terekhov, Maximilian Ackermann, Tilman Emrich, Leonardo Righesso, Werner E.G. Müller, Bilal Al-Nawas, Herman Götz, and Javier Rojas

Subjects

Dynamic contrast, medicine.diagnostic_test, Angiogenesis, business.industry, medicine, Magnetic resonance imaging, Oral Surgery, Bone regeneration, business, Biomedical engineering

Published

2020

6. Application unit for the administration of contrast gases for pulmonary magnetic resonance imaging: optimization of ventilation distribution for3He-MRI

Author

Christoph Düber, Ursula Wolf, Laura M. Schreiber, M. Güldner, K. K. Gast, S. Karpuk, J. Rivoire, Maxim Terekhov, Werner Heil, Zahir Salhi, C Hoffmann, St. Becker, A. Scholz, A. Friesenecker, and Ernst W. Otten

Subjects

Reproducibility, Materials science, medicine.diagnostic_test, Magnetic resonance imaging, law.invention, Pulmonary imaging, Volume (thermodynamics), law, Anesthesia, Healthy volunteers, Ventilation (architecture), medicine, Radiology, Nuclear Medicine and imaging, Hyperpolarization (physics), Mr images, Biomedical engineering

Abstract

Purpose MRI of lung airspaces using gases with MR-active nuclei (3He, 129Xe, and 19F) is an important area of research in pulmonary imaging. The volume-controlled administration of gas mixtures is important for obtaining quantitative information from MR images. State-of-the-art gas administration using plastic bags (PBs) does not allow for a precise determination of both the volume and timing of a 3He bolus. Methods A novel application unit (AU) was built according to the requirements of the German medical devices law. Integrated spirometers enable the monitoring of the inhaled gas flow. The device is particularly suited for hyperpolarized (HP) gases (e.g., storage and administration with minimal HP losses). The setup was tested in a clinical trial (n = 10 healthy volunteers) according to the German medicinal products law using static and dynamic ventilation HP-3He MRI. Results The required specifications for the AU were successfully realized. Compared to PB-administration, better reproducibility of gas intrapulmonary distribution was observed when using the AU for both static and dynamic ventilation imaging. Conclusion The new AU meets the special requirements for HP gases, which are storage and administration with minimal losses. Our data suggest that gas AU-administration is superior to manual modes for determining the key parameters of dynamic ventilation measurements. Magn Reson Med 74:884–893, 2015. © 2014 Wiley Periodicals, Inc.

Published

2014

7. Lung ventilation- and perfusion-weighted Fourier decomposition magnetic resonance imaging: In vivo validation with hyperpolarized3He and dynamic contrast-enhanced MRI

Author

Maxim Terekhov, J. Rivoire, Laura M. Schreiber, Janet Friedrich, Michael Puderbach, Wolfhard Semmler, Andre de Oliveira, Alexander Scholz, and Grzegorz Bauman

Subjects

medicine.medical_specialty, medicine.diagnostic_test, business.industry, Magnetic resonance imaging, Atelectasis, Air trapping, medicine.disease, Ventilation/perfusion ratio, Magnetic resonance angiography, Dynamic contrast-enhanced MRI, Breathing, Medicine, Radiology, Nuclear Medicine and imaging, Radiology, medicine.symptom, business, Nuclear medicine, Perfusion

Abstract

The purpose of this work was to validate ventilation-weighted (VW) and perfusion-weighted (QW) Fourier decomposition (FD) magnetic resonance imaging (MRI) with hyperpolarized (3)He MRI and dynamic contrast-enhanced perfusion (DCE) MRI in a controlled animal experiment. Three healthy pigs were studied on 1.5-T MR scanner. For FD MRI, the VW and QW images were obtained by postprocessing of time-resolved lung image sets. DCE acquisitions were performed immediately after contrast agent injection. (3)He MRI data were acquired following the administration of hyperpolarized helium and nitrogen mixture. After baseline MR scans, pulmonary embolism was artificially produced. FD MRI and DCE MRI perfusion measurements were repeated. Subsequently, atelectasis and air trapping were induced, which followed with FD MRI and (3)He MRI ventilation measurements. Distributions of signal intensities in healthy and pathologic lung tissue were compared by statistical analysis. Images acquired using FD, (3)He, and DCE MRI in all animals before the interventional procedure showed homogeneous ventilation and perfusion. Functional defects were detected by all MRI techniques at identical anatomical locations. Signal intensity in VW and QW images was significantly lower in pathological than in healthy lung parenchyma. The study has shown usefulness of FD MRI as an alternative, noninvasive, and easily implementable technique for the assessment of acute changes in lung function.

Published

2012

8. Three-dimensional mapping of the B 1 field using an optimized phase-based method: Application to hyperpolarized 3 He in lungs

Author

J. Rivoire, K. K. Gast, Zahir Salhi, Maxim Terekhov, Laura M. Schreiber, Florian M. Meise, and Davide Santoro

Subjects

Materials science, Pulse (signal processing), business.industry, Phase angle, Phase (waves), Pulse sequence, Imaging phantom, Nuclear magnetic resonance, Optics, Flip angle, Radiology, Nuclear Medicine and imaging, Sensitivity (control systems), business, Excitation

Abstract

A novel method is presented for the three-dimensional mapping of the B1-field of a transmit radio-frequency MR coil. The method is based on the acquisition of phase images, where the effective flip angle is encoded in the phase of the nonselective hard pulse excitation. The method involves the application of a rectangular composite pulse as excitation in a three-dimensional gradient recall echo to produce measurable phase angle variation. However, such a pulse may significantly increase the radio-frequency power deposition in excess of the standard acceptable SAR limits, imposing extremely long TRs (>100 msec), which would result in acquisition times significantly greater than a single breath-hold. In this study, the phases of the radio-frequency excitation are modified, resulting in a different pulse sequence scheme. It is shown that the new method increases sensitivity with respect to radio-frequency inhomogeneities by up to 10 times, and reduces the total duration of the pulse so that three-dimensional B1 mapping is possible with 3He in lungs within a single breath-hold. Computer simulations demonstrate the increase in sensitivity. Phantom results with 1H MRI are used for validation. In vivo results are presented with hyperpolarized 3He in human lungs at 1.5T. Magn Reson Med, 2010. © 2010 Wiley-Liss, Inc.

Published

2010

9. Visualization of inert gas wash-out during high-frequency oscillatory ventilation using fluorine-19 MRI

Author

Ursula Wolf, Laura M. Schreiber, Matthias David, Rainer Koebrich, Alexander Scholz, and Maxim Terekhov

Subjects

medicine.diagnostic_test, chemistry.chemical_element, Magnetic resonance imaging, law.invention, Transverse plane, Octafluorocyclobutane, chemistry.chemical_compound, Nuclear magnetic resonance, chemistry, law, Anesthesia, Ventilation (architecture), medicine, Fluorine, Radiology, Nuclear Medicine and imaging, Respiratory system, Inert gas, High frequency oscillatory ventilation

Abstract

High-frequency oscillatory ventilation is looked upon as a lung-protective ventilation strategy. For a further clarification of the physical processes promoting gas transport, a visualization of gas flow and the distribution of ventilation are of considerable interest. Therefore, fluorine-19 magnetic resonance imaging of the imaging gas octafluorocyclobutane (C(4) F(8) ) during high-frequency oscillatory ventilation was performed in five healthy pigs. For that, a mutually compatible ventilation-imaging system was set up and transverse images were acquired every 5 sec using FLASH sequences on a 1.5 T scanner. Despite a drop in signal-to-noise ratio after the onset of high-frequency oscillatory ventilation, for each pig, the four experiments could be analyzed. A mean wash-out time (τ) at 5 Hz of 52.7 ± 18 sec and 125.9 ± 39 sec at 10 Hz, respectively, were found for regions of interest including the whole lung. This is in agreement with the clinical findings, in that wash-out of respiratory gases is significantly prolonged for increased high-frequency oscillatory ventilation frequencies. Our study could be a good starting-point for a further optimization of high-frequency oscillatory ventilation.

Published

2010

10. Measurement of gas transport kinetics in high-frequency oscillatory ventilation (HFOV) of the lung using hyperpolarized 3He magnetic resonance imaging

Author

Ursula Wolf, Zahir Salhi, Maxim Terekhov, J. Rivoire, Laura M. Schreiber, Sergei Karpuk, Rainer Koebrich, Alexander Scholz, and Matthias David

Subjects

Artificial ventilation, ARDS, Materials science, Ventilator-associated lung injury, Swine, medicine.medical_treatment, Kinetics, High-Frequency Ventilation, Helium, Oscillometry, Pressure, medicine, Animals, Radiology, Nuclear Medicine and imaging, Lung, Respiratory Distress Syndrome, medicine.diagnostic_test, High-frequency ventilation, Apnea, Magnetic resonance imaging, Models, Theoretical, medicine.disease, Magnetic Resonance Imaging, Respiration, Artificial, medicine.anatomical_structure, Anesthesia, Gases, medicine.symptom, Biomedical engineering

Abstract

PURPOSE: To protect the patient with acute respiratory distress syndrome from ventilator associated lung injury (VALI) high-frequency oscillatory ventilation (HFOV) is used. Clinical experience has proven that HFOV is an efficient therapy when conventional artificial ventilation is insufficient. However, the optimal settings of HFOV parameters, eg, tidal volumes, pressure amplitudes and frequency for maximal lung protection, and efficient gas exchange are not established unambiguously. METHODS: In this work magnetic resonance imaging (MRI) with hyperpolarized (3)He was employed to visualize the redistribution of gas within the cadaver pig lung during HFOV. The saturated slice method was used to characterize fast gas kinetics. RESULTS: The strong differences in kinetics were observed for HFOV-driven gas exchange in comparison with diffusive gas transport (apnea). The significant regional and HFOV frequency dependence was detected for washout and gas exchange within the lungs. Gas redistribution was much faster in posterior than in anterior parts of the lungs during HFOV, in contrast to minor differences with an opposite trend observed in apnea. CONCLUSION: The method shows significant potential for visualization and quantification of gas redistribution under HFOV and may help in optimization of the parameters to improve the clinical effect of HFOV for patients.

Published

2010

11. Flip-angle measurement by magnetization inversion: Calibration of magnetization nutation angle in hyperpolarized 3 He magnetic resonance imaging lung experiments

Author

Laura M. Schreiber, J. Rivoire, Zahir Salhi, Maxim Terekhov, Florian M. Meise, and K. K. Gast

Subjects

medicine.diagnostic_test, Chemistry, business.industry, Nutation, Inverse transform sampling, Magnetic resonance imaging, Image processing, Magnetization, Nuclear magnetic resonance, Optics, Flip angle, medicine, Radiology, Nuclear Medicine and imaging, Wafer, business, Excitation

Abstract

The aim of this work was to establish a new, fast, and robust method of flip-angle calibration for magnetic resonance imaging of hyperpolarized 3He. The method called flip-angle measurement with magnetization inversion is based on acquiring images from periodically inverted longitudinal magnetization created using the spatial modulation of magnetization technique. By measuring the width of the area where the magnetization was inverted by the spatial modulation of magnetization preparation in phase images, the flip angle can be generated using a simple equation. To validate and establish the limits of the proposed method, flip-angle measurement with magnetization inversion acquisitions were simulated and applied to proton and hyperpolarized 3He phantoms. Then, the calibration procedure was applied during hyperpolarized 3He magnetic resonance imaging in a healthy volunteer. The advantage of the flip-angle measurement with magnetization inversion method compared with the conventional method based on the assessment of radiofrequency-decay is that it is free of errors induced by relaxation due to oxygen, by imperfect excitation slice profile and by any diffusion of 3He into and out of the slice. Another advantage is that it does not require image processing with external software and therefore can be performed using the implemented tools on the magnetic resonance workstation. Magn Reson Med, 2011. © 2010 Wiley-Liss, Inc.

Published

2010

12. Design and evaluation of a 32-channel phased-array coil for lung imaging with hyperpolarized 3-helium

Author

Laura M. Schreiber, Maxim Terekhov, Lawrence L. Wald, S. Karpuk, Zahir Salhi, J. Rivoire, Boris Keil, Florian M. Meise, and Graham Wiggins

Subjects

COPD, Lung, Channel (digital image), Image quality, business.industry, medicine.disease, Phased array coil, medicine.anatomical_structure, Nuclear magnetic resonance, Lung imaging, Array coil, medicine, Radiology, Nuclear Medicine and imaging, business, Image resolution

Abstract

Imaging with hyperpolarized 3-helium is becoming an increasingly important technique for MRI diagnostics of the lung but is hampered by long breath holds (>20 sec), which are not always applicable in patients with severe lung disease like chronic obstructive pulmonary disease (COPD) or α-1-anti-trypsin deficiency. Additionally, oxygen-induced depolarization decay during the long breath holds complicates interpretation of functional data such as apparent diffusion coefficients. To address these issues, we describe and validate a 1.5-T, 32-channel array coil for accelerated 3He lung imaging and demonstrate its ability to speed up imaging 3He. A signal-to-noise ratio increase of up to a factor of 17 was observed compared to a conventional double-resonant birdcage for unaccelerated imaging, potentially allowing increased image resolution or decreased gas production requirements. Accelerated imaging of the whole lung with one-dimensional and two-dimensional acceleration factors of 4 and 4 × 2, respectively, was achieved while still retaining excellent image quality. Finally, the potential of highly parallel detection in lung imaging is demonstrated with high-resolution morphologic and functional images. Magn Reson Med, 2010. © 2010 Wiley-Liss, Inc.

Published

2010

13. Pathogen-Mimicking MnO Nanoparticles for Selective Activation of the TLR9 Pathway and Imaging of Cancer Cells

Author

Mohammed Ibrahim Shukoor, Laura M. Schreiber, Andreas Janshoff, Matthias Barz, Stefan A. L. Weber, Helen Annal Therese, Maxim Terekhov, Matthias Wiens, Patrick Theato, Filipe Natalio, Wolfgang Tremel, Rudolf Zentel, Marco Tarantola, Muhammad Nawaz Tahir, Werner E.G. Müller, and Heinz C. Schröder

Subjects

Phosphoramidite, Materials science, Oligonucleotide, Nanoparticle, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, Biomaterials, Rhodamine, chemistry.chemical_compound, chemistry, Cancer cell, Electrochemistry, Biophysics, Surface modification, 0210 nano-technology, Drug carrier, Biosensor

Abstract

Here, design of the first pathogen-mimicking metal oxide nanoparticles with the ability to enter cancer cells and to selectively target and activate the TLR9 pathway, and with optical and MR imaging capabilities, is reported. The immobilization of ssDNA (CpG ODN 2006) on MnO nanoparticles is performed via the phosphoramidite route using a multifunctional polymer. The multifunctional polymer used for the nanoparticle surface modification not only affords a protective organic biocompatible shell but also provides an efficient and convenient means for loading immunostimulatory oligonucleotides. Since fluorescent molecules are amenable to photodetection, a chromophore (Rhodamine) is introduced into the polymer chain to trace the nanoparticles in Caki-1 (human kidney cancer) cells. The ssDNA coupled nanoparticles are used to target Toll-like receptors 9 (TLR9) receptors inside the cells and to activate the classical TLR cascade. The presence of TLR9 is demonstrated independently in the Caki-1 cell line by western blotting and immunostaining techniques. The magnetic properties of the MnO core make functionalized MnO nanoparticles potential diagnostic agents for magnetic resonance imaging (MRI) thereby enabling multimodal detection by a combination of MR and optical imaging methods. The trimodal nanoparticles allow the imaging of cellular trafficking by different means and simultaneously are an effective drug carrier system.

Published

2009

14. Investigation of Polymer Structure and Properties with Solid-State and Gaseous MRI Methods

Author

D. Höpfel and Maxim Terekhov

Subjects

chemistry.chemical_classification, EPDM rubber, General Chemical Engineering, Physics::Medical Physics, Solid-state, General Chemistry, Polymer, Industrial and Manufacturing Engineering, Dipole, Nuclear magnetic resonance, chemistry, Correlation analysis, Hyperpolarized xenon, Physics::Atomic and Molecular Clusters, Hyperpolarization (physics), Image resolution

Abstract

The effectiveness of solid-state MRI with dipolar refocusing techniques was tested to improve the sensitivity and spatial resolution for the investigation of various solid polymers. The comparison of dipolar refocusing methods with conventional SPI was undertaken. As an alternative, gas-phase MRI experiments with thermally polarized SF6 and hyperpolarized xenon were performed. The performance of SF6 was found to be equivalent to solid-state methods. The possibility of achieving a significant increase in imaging efficiency by use of the hyperpolarization technique is demonstrated. The effects of embedding gaseous SF6 into EPDM rubber were investigated using NMR methods. A strong correlation was found between EPDM cross-linking and the transversal relaxation time of embedded SF6.

Published

2006

15. Functionalized Magnetic Nano-particles for Selective Targeting and Sensing of Cells

Author

Wolfgang Tremel, Mohammed Ibrahim Shukoor, H. C. Schröder, Filipe Natalio, Maxim Terekhov, Wolfgang Schreiber, S. Fischer, and Werner E.G. Müller

Subjects

Inorganic Chemistry, Chemistry, Nanoparticle, Nanotechnology

Published

2008