Your search keyword '"Petryakov, Sergey"' showing total 12 results

1. Surface dielectric resonator for in vivo EPR measurements.

Author

Petryakov SV, Kmiec MM, Ubert CS, Kassey VB, Schaner PE, and Kuppusamy P

Subjects

Electron Spin Resonance Spectroscopy methods, Electron Spin Resonance Spectroscopy instrumentation, Reproducibility of Results, Oximetry instrumentation, Oximetry methods, Phantoms, Imaging, Equipment Design, Electromagnetic Fields

Abstract

This research report describes a novel surface dielectric resonator (SDR) with a flexible connector for in vivo electron paramagnetic resonance (EPR) spectroscopy. Contrary to the conventional cavity or surface loop-gap resonators, the newly developed SDR is constructed from a ceramic dielectric material, and it is tuned to operate at the L-band frequency band (1.15 GHz) in continuous-wave mode. The SDR is designed to be critically coupled and capable of working with both very lossy samples, such as biological tissues, and non-lossy materials. The SDR was characterized using electromagnetic field simulations, assessed for sensitivity with a B 1 field-perturbation method, and validated with tissue phantoms using EPR measurements. The results showed remarkably higher sensitivity in lossy tissue phantoms than the previously reported multisegment surface-loop resonators. The new SDR can provide potential new insights for advancements in the application of in vivo EPR spectroscopy for biological measurements, including clinical oximetry., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Inc. All rights reserved.)

Published

2024

2. Organ specific mapping of in vivo redox state in control and cigarette smoke-exposed mice using EPR/NMR co-imaging.

Author

Caia GL, Efimova OV, Velayutham M, El-Mahdy MA, Abdelghany TM, Kesselring E, Petryakov S, Sun Z, Samouilov A, and Zweier JL

Subjects

Animals, Atmosphere Exposure Chambers, Cyclic N-Oxides, Electromagnetic Fields, Electron Spin Resonance Spectroscopy, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Male, Mice, Mice, Inbred C57BL, Nitrogen Oxides chemistry, Organ Specificity, Oxidation-Reduction, Oxidative Stress, Pyrrolidines, Spin Labels, Tissue Distribution, Smoke adverse effects, Nicotiana chemistry

Abstract

In vivo mapping of alterations in redox status is important for understanding organ specific pathology and disease. While electron paramagnetic resonance imaging (EPRI) enables spatial mapping of free radicals, it does not provide anatomic visualization of the body. Proton MRI is well suited to provide anatomical visualization. We applied EPR/NMR co-imaging instrumentation to map and monitor the redox state of living mice under normal or oxidative stress conditions induced by secondhand cigarette smoke (SHS) exposure. A hybrid co-imaging instrument, EPRI (1.2 GHz)/proton MRI (16.18 MHz), suitable for whole-body co-imaging of mice was utilized with common magnet and gradients along with dual EPR/NMR resonators that enable co-imaging without sample movement. The metabolism of the nitroxide probe, 3-carbamoyl-proxyl (3-CP), was used to map the redox state of control and SHS-exposed mice. Co-imaging allowed precise 3D mapping of radical distribution and reduction in major organs such as the heart, lungs, liver, bladder and kidneys. Reductive metabolism was markedly decreased in SHS-exposed mice and EPR/NMR co-imaging allowed quantitative assessment of this throughout the body. Thus, in vivo EPR/NMR co-imaging enables in vivo organ specific mapping of free radical metabolism and redox stress and the alterations that occur in the pathogenesis of disease., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2012

3. Standard-based method for proton-electron double resonance imaging of oxygen.

Author

Efimova OV, Caia GL, Sun Z, Petryakov S, Kesselring E, Samouilov A, and Zweier JL

Subjects

Algorithms, Electromagnetic Fields, Electron Spin Resonance Spectroscopy, Indicators and Reagents, Magnetic Resonance Spectroscopy, Oximetry, Phantoms, Imaging, Reference Standards, Tritium, Electrons, Magnetic Resonance Imaging methods, Oxygen chemistry, Protons

Abstract

Proton-electron double resonance imaging (PEDRI) has been utilized for indirect determination of oxygen concentrations in aqueous samples and living systems. Due to the complexity of the problem, there are seven oxygen related parameters that need to be measured to determine the distribution of oxygen. We present an improved approach in which image intensities from only two PEDRI acquisitions with different EPR irradiation powers are required to determine the distribution of a paramagnetic probe and oxygen in an analyzed sample. This is achieved using three reference samples with known concentrations of a paramagnetic probe and oxygen placed inside the resonator together with the measurement sample. An EPR-off image, which has low signal intensity at low magnetic field (0.02 T) is not required for the calculations, significantly reducing the total time of the experiments and the noise while enhancing the accuracy of these oxygen measurements. The Finland trityl radical was used as the paramagnetic probe and oxygen concentrations could be accurately measured and imaged over the physiological range from 0 to 240 μM., (Published by Elsevier Inc.)

Published

2011

4. Variable radio frequency proton-electron double-resonance imaging: application to pH mapping of aqueous samples.

Author

Efimova OV, Sun Z, Petryakov S, Kesselring E, Caia GL, Johnson D, Zweier JL, Khramtsov VV, and Samouilov A

Subjects

Animals, Calibration, Data Interpretation, Statistical, Electromagnetic Fields, Electron Spin Resonance Spectroscopy instrumentation, Electrons, Free Radicals, Hydrogen-Ion Concentration, Indicators and Reagents, Mice, Phantoms, Imaging, Protons, Radio Waves, Electron Spin Resonance Spectroscopy methods, Magnetic Resonance Imaging methods, Water chemistry

Abstract

Proton-electron double-resonance imaging (PEDRI) offers rapid image data collection and high resolution for spatial distribution of paramagnetic probes. Recently we developed the concept of variable field (VF) PEDRI which enables extracting a functional map from a limited number of images acquired at pre-selected EPR excitation fields using specific paramagnetic probes (Khramtsov et al., J. Magn. Reson. 202 (2010) 267-273). In this work, we propose and evaluate a new modality of PEDRI-based functional imaging with enhanced temporal resolution which we term variable radio frequency (VRF) PEDRI. The approach allows for functional mapping (e.g., pH mapping) using specifically designed paramagnetic probes with high quality spatial resolution and short acquisition times. This approach uses a stationary magnetic field but different EPR RFs. The ratio of Overhauser enhancements measured at each pixel at two different excitation frequencies corresponding to the resonances of protonated and deprotonated forms of a pH-sensitive nitroxide is converted to a pH map using a corresponding calibration curve. Elimination of field cycling decreased the acquisition time by exclusion periods of ramping and stabilization of the magnetic field. Improved magnetic field homogeneity and stability allowed for the fast MRI acquisition modalities such as fast spin echo. In total, about 30-fold decrease in EPR irradiation time was achieved for VRF PEDRI (2.4s) compared with VF PEDRI (70s). This is particularly important for in vivo applications enabling one to overcome the limiting stability of paramagnetic probes and sample overheating by reducing RF power deposition., (Published by Elsevier Inc.)

Published

2011

5. A novel variable field system for field-cycled dynamic nuclear polarization spectroscopy.

Author

Shet K, Caia GL, Kesselring E, Samouilov A, Petryakov S, Lurie DJ, and Zweier JL

Subjects

Cyclic N-Oxides chemistry, Electromagnetic Fields, Electron Spin Resonance Spectroscopy, Nitric Oxide chemistry, Spin Labels, Magnetic Resonance Spectroscopy methods

Abstract

Dynamic nuclear polarization (DNP) is an NMR-based technique which enables detection and spectral characterization of endogenous and exogenous paramagnetic substances measured via transfer of polarization from the saturated unpaired electron spin system to the NMR active nuclei. A variable field system capable of performing DNP spectroscopy with NMR detection at any magnetic field in the range 0-0.38 T is described. The system is built around a clinical open-MRI system. To obtain EPR spectra via DNP, partial cancellation of the detection field B(0)(NMR) is required to alter the evolution field B(0)(EPR) at which the EPR excitation is achieved. The addition of resistive actively shielded field cancellation coils in the gap of the primary magnet provides this field offset in the range of 0-100 mT. A description of the primary magnet, cancellation coils, power supplies, interfacing hardware, RF electronics and console are included. Performance of the instrument has been evaluated by acquiring DNP spectra of phantoms with aqueous nitroxide solutions (TEMPOL) at three NMR detection fields of 97 G, 200 G and 587 G corresponding to 413 kHz, 851.6 kHz and 2.5 MHz respectively and fixed EPR evolution field of 100 G corresponding to an irradiation frequency of 282.3 MHz. This variable-field DNP system offers great flexibility for the performance of DNP spectroscopy with independent optimum choice of EPR excitation and NMR detection fields., (Copyright 2010 Elsevier Inc. All rights reserved.)

Published

2010

6. Dual frequency resonator for 1.2 GHz EPR/16.2 MHz NMR co-imaging.

Author

Petryakov S, Samouilov A, Kesselring E, Caia GL, Sun Z, and Zweier JL

Subjects

Animals, Electronics, Equipment Design, Heart anatomy & histology, Phantoms, Imaging, Rats, Magnetic Resonance Imaging instrumentation

Abstract

The development of a dual frequency resonator that enables both EPR and proton NMR imaging within the same resonator, magnet and gradient system is described. A novel design allows the same resonator to perform both EPR and proton NMR operation without moving resonator cables or switches. The resonator is capable of working at frequencies of 16.18 MHz for proton NMR and 1.2 GHz for EPR and is optimized for isolated rat heart experiments, measuring 22 mm in inner diameter and 19 mm in length. In EPR mode, the resonator functions as a one-loop-two gap resonator, electrically coupled through a half wavelength inverter. In NMR mode, it functions a single turn coil. Using the same loop for both modalities maximizes filling factor at both frequencies. Placing the tuning and switching controls away from the resonator prevents any inadvertent movement that would cause errors of EPR and NMR co-imaging registration. The resonator enabled good quality EPR and proton MRI of isolated rat hearts with precise registration., (Copyright (c) 2010 Elsevier Inc. All rights reserved.)

Published

2010

7. Variable Field Proton-Electron Double-Resonance Imaging: Application to pH mapping of aqueous samples.

Author

Khramtsov VV, Caia GL, Shet K, Kesselring E, Petryakov S, Zweier JL, and Samouilov A

Subjects

Electron Spin Resonance Spectroscopy, Electrons, Hydrogen-Ion Concentration, Nitrogen Oxides chemistry, Oxidation-Reduction, Oxygen chemistry, Phantoms, Imaging, Protons, Reactive Nitrogen Species chemistry, Magnetic Resonance Imaging methods, Water chemistry

Abstract

A new concept of Variable Field Proton-Electron Double-Resonance Imaging (VF PEDRI) is proposed. This allows for functional mapping using specifically designed paramagnetic probes (e.g. oxygen or pH mapping) with MRI high quality spatial resolution and short acquisition time. Studies performed at 200 G field MRI with phantoms show that a pH map of the sample can be extracted using only two PEDRI images acquired in 140 s at pre-selected EPR excitation fields providing pH resolution of 0.1 pH units and a spatial resolution of 1.25mm. Note that while concept of functional VF PEDRI was demonstrated using the pH probe, it can be applied for studies of other biologically relevant parameters of the medium such as redox state, concentrations of oxygen or glutathione using specifically designed EPR probes., (Published by Elsevier Inc.)

Published

2010

8. Segmented surface coil resonator for in vivo EPR applications at 1.1GHz.

Author

Petryakov S, Samouilov A, Chzhan-Roytenberg M, Kesselring E, Sun Z, and Zweier JL

Subjects

Algorithms, Animals, Charcoal, Electromagnetic Fields, Equipment Design, Female, Magnetic Resonance Imaging, Oximetry, Rats, Electron Spin Resonance Spectroscopy instrumentation

Abstract

A four-loop segmented surface coil resonator (SSCR) with electronic frequency and coupling adjustments was constructed with 18mm aperture and loading capability suitable for in vivo Electron Paramagnetic Resonance (EPR) spectroscopy and imaging applications at L-band. Increased sample volume and loading capability were achieved by employing a multi-loop three-dimensional surface coil structure. Symmetrical design of the resonator with coupling to each loop resulted in high homogeneity of RF magnetic field. Parallel loops were coupled to the feeder cable via balancing circuitry containing varactor diodes for electronic coupling and tuning over a wide range of loading conditions. Manually adjusted high Q trimmer capacitors were used for initial tuning with subsequent tuning electronically controlled using varactor diodes. This design provides transparency and homogeneity of magnetic field modulation in the sample volume, while matching components are shielded to minimize interference with modulation and ambient RF fields. It can accommodate lossy samples up to 90% of its aperture with high homogeneity of RF and modulation magnetic fields and can function as a surface loop or a slice volume resonator. Along with an outer coaxial NMR surface coil, the SSCR enabled EPR/NMR co-imaging of paramagnetic probes in living rats to a depth of 20mm.

Published

2009

9. Evaluation of oxygen-response times of phthalocyanine-based crystalline paramagnetic spin probes for EPR oximetry.

Author

Vikram DS, Ahmad R, Pandian RP, Petryakov S, and Kuppusamy P

Subjects

Isoindoles, Molecular Structure, Sensitivity and Specificity, Electron Spin Resonance Spectroscopy methods, Indoles chemistry, Oximetry methods, Oxygen analysis

Abstract

The goal of the present study was to evaluate the temporal response of particulate-based EPR oximetry probes to changes in partial pressure of oxygen (pO(2)). In order to accurately evaluate the oxygen-response time, we developed a method for rapid modulation of pO(2) in a chamber containing the probe using an oscillator-driven speaker-diaphragm setup. The apparatus was capable of producing sinusoidal changes in pO(2) at frequencies up to 300 Hz or more. The pressure-modulation setup was used to evaluate the temporal response of some of the most commonly used phthalocyanine-based particulate probes. For validation, the time-response of the probes was compared to that of a high sensitivity pressure sensor. The results revealed that some particulate probes could respond to changes in pO(2) with a temporal response of 3.3 ms (300 Hz). The observations were interpreted in the light of their crystalline packing in favor of oxygen diffusion. The results of the present study should enable the selection of probes for oximetry applications requiring high temporal resolution.

Published

2008

10. A loop resonator for slice-selective in vivo EPR imaging in rats.

Author

Hirata H, He G, Deng Y, Salikhov I, Petryakov S, and Zweier JL

Subjects

Animals, Cyclic N-Oxides, Equipment Design, Image Processing, Computer-Assisted, Male, Phantoms, Imaging, Rats, Rats, Sprague-Dawley, Spin Labels, Echo-Planar Imaging instrumentation

Abstract

A loop resonator was developed for 300 MHz continuous-wave electron paramagnetic resonance (CW-EPR) spectroscopy and imaging in live rats. A single-turn loop (55 mm in diameter) was used to provide sufficient space for the rat body. Efficiency for generating a radiofrequency magnetic field of 38 microT/W(1/2) was achieved at the center of the loop. For the resonator itself, an unloaded quality factor of 430 was obtained. When a 350 g rat was placed in the resonator at the level of the lower abdomen, the quality factor decreased to 18. The sensitive volume in the loop was visualized with a bottle filled with an aqueous solution of the nitroxide spin probe 3-carbamoyl-2,2,5,5-tetramethyl-3-pyrrolin-1-yloxy (3-CP). The resonator was shown to enable EPR imaging in live rats. Imaging was performed for 3-CP that had been infused intravenously into the rat and its distribution was visualized within the lower abdomen.

Published

2008

11. Single loop multi-gap resonator for whole body EPR imaging of mice at 1.2 GHz.

Author

Petryakov S, Samouilov A, Kesselring E, Wasowicz T, Caia GL, and Zweier JL

Subjects

Animals, Mice, Radio Waves, Algorithms, Electron Spin Resonance Spectroscopy instrumentation, Electron Spin Resonance Spectroscopy methods

Abstract

For whole body EPR imaging of small animals, typically low frequencies of 250-750 MHz have been used due to the microwave losses at higher frequencies and the challenges in designing suitable resonators to accommodate these large lossy samples. However, low microwave frequency limits the obtainable sensitivity. L-band frequencies can provide higher sensitivity, and have been commonly used for localized in vivo EPR spectroscopy. Therefore, it would be highly desirable to develop an L-band microwave resonator suitable for in vivo whole body EPR imaging of small animals such as living mice. A 1.2 GHz 16-gap resonator with inner diameter of 42 mm and 48 mm length was designed and constructed for whole body EPR imaging of small animals. The resonator has good field homogeneity and stability to animal-induced motional noise. Resonator stability was achieved with electrical and mechanical design utilizing a fixed position double coupling loop of novel geometry, thus minimizing the number of moving parts. Using this resonator, high quality EPR images of lossy phantoms and living mice were obtained. This design provides good sensitivity, ease of sample access, excellent stability and uniform B(1) field homogeneity for in vivo whole body EPR imaging of mice at 1.2 GHz.

Published

2007

12. Transverse oriented electric field re-entrant resonator (TERR) with automatic tuning and coupling control for EPR spectroscopy and imaging of the beating heart.

Author

He G, Dumitrescu C, Petryakov S, Deng Y, Kesselring E, and Zweier JL

Subjects

Animals, Electromagnetic Fields, Electronics, Male, Myocardium metabolism, Oxidation-Reduction, Phantoms, Imaging, Rats, Rats, Sprague-Dawley, Electron Spin Resonance Spectroscopy instrumentation, Heart anatomy & histology, Magnetic Resonance Imaging instrumentation

Abstract

Sample motion, particularly that of a beating heart, induces baseline noise and spectral distortion on an EPR spectrum. In order to quench motional noise and restore the EPR signal amplitude and line-width, an L-band transverse oriented electric field re-entrant resonator (TERR) was designed and constructed with provisions for automatic tuning control (ATC) and automatic coupling control (ACC) suited for studies of isolated beating rat hearts. Two sets of electronic circuits providing DC biased voltage to two varactor diodes were implemented to electronically adjust coupling and tuning. The resonator has a rectangular cross-sectional sample arm of 25 mm diameter with a Q value of 1100 without sample. Once inserted with lossy aqueous samples of 0.45% NaCl, Q value drops to 400 with a volume of 0.5 ml and 150 with 5 ml. The ATC/ACC functions were tested with a moving phantom and isolated beating rat hearts with the improvement of signal to noise ratio (S/N, peak amplitude of signal over peak amplitude of baseline noise) of 6.7-, and 4 to 6-fold, respectively. With these improvements, EPR imaging could be performed on an isolated beating rat heart. Thus, this TERR resonator with ATC/ACC enables application of EPR spectroscopy and imaging for the measurement and imaging of radical metabolism, redox state, and oxygenation in the isolated beating rat heart.

Published

2007