Your search keyword '"Borbath, T."' showing total 18 results

1. Magnetic Resonance Spectroscopy: Quantitative Analysis of Brain Metabolites and Macromolecules

Author

Borbath, T. and Henning, Anke (Prof. Dr.)

Subjects

NMR-Spektroskopie , Software , Modellierung , Metabolit , Gehirn , Aminosäuren

Abstract

Die Protonen-Magnetresonanzspektroskopie (1H-MRS) ermöglicht die nichtinvasive in vivo Quantifizierung des Metabolismus im menschlichen Gehirn. In der 1H-MRS wird die Interaktion zwischen einem in ein starkes elektromagnetisches Feld platziertes 1H-Wasserstoffisotop und einem oszillierenden elektromagnetischen Feld gemessen. Die gemessenen MRS-Signale der 1H-Wasserstoffatome spiegeln die Konzentration der in dem Gewebe enthaltenen Metaboliten wieder. Jedes 1H-Wasserstoffatom in einem Metaboliten hat eine spezifische Resonanzfrequenz, die von der chemischen Struktur des Metaboliten abhängt. Die Gesamtheit der Resonanzfrequenzen aller Metaboliten in dem gemessenen Gewebe generiert das MRS-Signal. Durch die Fourier-Transformation dieses MRS-Signals entsteht ein MRS-Spektrum mit Spektrallinien, die den enthaltenen Resonanzfrequenzen entsprechen. Wasser ist das häufigste Molekül im menschlichen Gewebe. Um Metaboliten mit signifikant geringeren Konzentrationen quantifizieren zu können, wird in der MRS das Wassersignal unterdrückt. Wasserstoffatome mit einer niedrigeren Resonanzfrequenz als Wasser bilden das sogenannte „Upfield-Spektrum”, während die Wasserstoffatome mit einer höheren Resonanzfrequenz das “Downfield-Spektrum” bilden. Das „Upfield-Spektrum” enthält die Spektrallinien der meisten klinisch relevanten Metaboliten, ist aber von einer starken spektralen Überlagerung geprägt. Deshalb müssen die Anteile der einzelnen Metaboliten im Gesamtspektrum durch eine spezielle Software berechnet werden. Die Modellierung der einzelnen Beiträge der Metaboliten zu dem gemessenen Spektrum nennt man spektrales Fitting. Mithilfe des spektralen Fitting werden die für die klinische Diagnostik relevanten Metabolitenkonzentrationen bestimmt. Diese Doktorarbeit fokussiert sich auf die Modellierung des MRS-Spektrums. Der erste Teil beschäftigt sich mit der akkuraten Quantifizierung der Metabolitenkonzentrationen. Die signifikanteste spektrale Überlagerung im MRS entsteht durch Signale, die unter den Spektrallinien der Metaboliten liegen und die als makromolekulares Spektrum bezeichnet werden. Das makromolekulare Spektrum besteht aus den Resonanzfrequenzen der Protonen von Proteinen und Peptiden, deren MRS-Signal schneller zerfällt als das der kleineren Moleküle (Metaboliten). Zusätzlich tragen zu der spektralen Überlagerung nicht ausreichend unterdrückte Wassersignale, sowie Signale von Fettmolekülen, die sich von außerhalb des gemessenen Volumens in das Spektrum reinfalten bei. Diese unerwünschten Signale werden im spektralen Fitting typischerweise durch Spline-Grundlinien modelliert. In dieser Arbeit wird untersucht, wie sich verschiedene makromolekulare Spektren und Spline-Grundlinien auf das spektrale Fitting auswirken. Änderungen der Flexibilität an der Spline-Grundlinie im LCModel (am häufigsten genutzte MRS-Software) führen zu signifikant unterschiedlichen Metabolitenkonzentrationen. Deshalb wurde in dem für diese Arbeit neuentwickelten, spektralen Fitting-Algorithmus ProFit-v3 eine automatische Erkennung der notwendigen Flexibilität der Spline-Grundlinie etabliert. Die ProFit-v3 Software wurde danach systematisch auf verschiedene Perturbationen und Grundlinien getestet. Die quantifizierten Konzentrationen wurden mit den wahren Konzentrationen (falls bekannt) und mit den Ergebnissen der LCModel Software verglichen. Der zweite Teil dieser Arbeit untersucht neue Modellierungsmöglichkeiten für zwei weniger untersuchte Bereiche des MRS-Spektrums. Das „Downfield-Spektrum” enthält mehrere Spektrallinien, die noch keinen Metaboliten zugeordnet werden konnten. In dieser Arbeit wurde der intrazelluläre pH-Wert durch Downfield-Spektrallinien bestimmt. Im Weiteren wurden für alle Downfield-Spektrallinien T2 Relaxationszeiten, spektrale Linienbreiten und Konzentrationen berechnet. Zuletzt wurden die entsprechenden Metaboliten anhand der quantifizierten Eigenschaften und Messungen aus vorliegender Literatur zu den Spektrallinien zugeordnet. Vorherige Literatur ordnet das makromolekulare Spektrum Beiträge der Aminosäuren aus Proteinen und Peptiden zu. Zusätzlich wurden die Resonanzfrequenzen der Aminosäuren in Proteinen umfangreich von der NMR-Gemeinschaft in Proteindatenbanken gesammelt. Daher wird in dieser Arbeit ein Modellierungsverfahren vorgestellt, um die in vivo gemessenen makromolekularen Spektren als Kontribution einzelner Aminosäuren zu quantifizieren. Insgesamt konnte gezeigt werden, dass die Forschungsergebnisse und die vorgestellte ProFit-v3 Fitting Software zur Verbesserung der MRS Quantifizierung beitragen. Die Zuordnung von Metaboliten im „Downfield-Spektrum“ und das Modell zur Quantifizierung von Aminosäuren können als zukünftige Biomarker für Krankheiten dienen. Proton magnetic resonance spectroscopy (1H-MRS) allows non-invasive quantification of the human brain's metabolism in vivo. 1H-MRS measures the interaction of the 1H-hydrogen isotope with oscillating electromagnetic fields in the presence of a strong electromagnetic field. The measured MRS signal of the 1H-hydrogen atoms reflects the concentration of the metabolites present in the tissue. Metabolites are small molecules reflecting the metabolism. Each 1H-hydrogen atom present in a metabolite has a specific resonance frequency, which depends on the chemical structure of the metabolite. The ensemble of the resonance frequencies of all metabolites present in the measured tissue creates the MRS signal. The MRS signal is Fourier transformed, producing an MRS spectrum, where each resonance frequency appears as a distinct peak. The most abundant molecule in the human tissue is water. The resonance frequency of water is suppressed in 1H-MRS to permit the quantification of other metabolites, which are present with significantly lower concentrations. In the MRS spectrum, protons with lower resonance frequencies than water form the upfield spectrum, whereas protons with higher resonance frequencies form the downfield spectrum. This work focused on the modelling of the MRS spectrum. The first part is focused on the accurate determination of metabolite concentrations. The upfield spectrum contains most brain metabolites of clinical interest. However, there is a severe spectral overlap between the metabolite resonances, and therefore dedicated software calculates the contributions of individual metabolites. The modelling of the individual metabolite contributions to the measured spectrum is referred to as spectral fitting. Through this spectral fitting, the metabolite concentrations needed for clinical diagnostics are determined. The most significant overlap in MRS spectra originates from the signals underlying the metabolite resonances, referred to as the macromolecular spectrum. The macromolecular spectrum contains the resonance frequencies of protons in proteins and peptides, which have a slightly faster signal decay than the smaller molecules (metabolites). Other contributors to the spectral overlap are residuals of the not entirely suppressed water signal or lipid signals originating from outside the volume of interest. A spline baseline is typically used in the fitting software to model these contributors. This work firstly investigated the impacts of different macromolecular spectra and spline baselines used in spectral fitting. Significant effects in the quantified metabolite concentrations were noticed, when the spline baseline flexibility was altered in the community “gold standard” software, LCModel. Therefore, the newly developed fitting algorithm proposed in this work, ProFit-v3, incorporates an automatic adaptive baseline flexibility determination. The ProFit-v3 software was then systematically evaluated to different perturbations and baseline effects. The quantified concentrations were compared to the ground truth (when known) and the LCModel software results. The second part of this work focuses on the modelling of the less investigated regions of the MRS spectrum. The downfield spectrum contains many resonance peaks unassigned to metabolite contributions. In this work, downfield spectral peaks were used to quantify intracellular pH. Additionally, for all downfield peaks T2 relaxation times, peak linewidths, and concentrations were calculated. Lastly, based on the quantified peak properties combined with previous literature measurements, the contributing molecules to the downfield peaks were assigned. The macromolecular spectrum was attributed by previous literature to contributions of amino acids in proteins and peptides, based on in vitro measurement of dialyzed cytosol. Moreover, the resonance frequencies of protein amino acids have been extensively collected into a protein database by the NMR community. Hence, this work proposes a modelling approach to quantify the in vivo measured macromolecular spectrum to individual amino acids. In conclusion, the investigation results and the proposed fitting software ProFit-v3 from this work should lead to improved quantification of 1H-MRS spectra. Lastly, the peak assignments in the downfield spectra and the proposed amino acid model promises possible future biomarkers for disease.

Published

2021

2. Combination of surface and ‘vertical’ loop elements improves receive performance of a human head transceiver array at 9.4 T

Author

Avdievich, N.I., primary, Giapitzakis, I.A., additional, Pfrommer, A., additional, Borbath, T., additional, and Henning, A., additional

Published

2017

3. Combination of surface and ‘vertical’ loop elements improves receive performance of a human head transceiver array at 9.4 T.

Author

Avdievich, N. I., Giapitzakis, I. A., Pfrommer, A., Borbath, T., and Henning, A.

Abstract

Ultra‐high‐field (UHF, ≥7 T) human magnetic resonance imaging (MRI) provides undisputed advantages over low‐field MRI (≤3 T), but its development remains challenging because of numerous technical issues, including the low efficiency of transmit (Tx) radiofrequency (RF) coils caused by the increase in tissue power deposition with frequency. Tight‐fit human head transceiver (TxRx) arrays improve Tx efficiency in comparison with Tx‐only arrays, which are larger in order to fit multi‐channel receive (Rx)‐only arrays inside. A drawback of the TxRx design is that the number of elements in an array is limited by the number of available high‐power RF Tx channels (commonly 8 or 16), which is not sufficient for optimal Rx performance. In this work, as a proof of concept, we developed a method for increasing the number of Rx elements in a human head TxRx surface loop array without the need to move the loops away from a sample, which compromises the array Tx performance. We designed and constructed a prototype 16‐channel tight‐fit array, which consists of eight TxRx surface loops placed on a cylindrical holder circumscribing a head, and eight Rx‐only vertical loops positioned along the central axis (parallel to the magnetic field B0) of each TxRx loop, perpendicular to its surface. We demonstrated both experimentally and numerically that the addition of the vertical loops has no measurable effect on the Tx efficiency of the array. An increase in the maximum local specific absorption rate (SAR), evaluated using two human head voxel models (Duke and Ella), measured 3.4% or less. At the same time, the 16‐element array provided 30% improvement of central signal‐to‐noise ratio (SNR) in vivo relative to a surface loop eight‐element array. The novel array design also demonstrated an improvement in the parallel Rx performance in the transversal plane. Thus, using this method, both the Rx and Tx performance of the human head array can be optimized simultaneously. [ABSTRACT FROM AUTHOR]

Published

2018

4. Chemiluminescence-based evaluation of styrene block copolymers' recyclability.

Author

Bumbac M, Zaharescu T, Nicolescu CM, Borbath T, and Borbath I

Abstract

The study presents the chemiluminescence based (CL) evaluation of the recyclability of linear styrene block copolymers. This analysis can provide insight into the material's degradation state and predict its suitability for further recycling cycles, helping to avoid unnecessary energy consumption during processing.The thermal stability of four similar copolymer structures - styrene-isoprene-styrene (SIS), styrene-butadiene-styrene (SBS) copolymers with different styrene/butadiene ratios, and styrene-ethylene-butadiene-styrene (SEBS) - was studied using isothermal and non-isothermal chemiluminescence (CL). The activation energies for oxidative degradation were calculated based on oxidation induction times indicated by the CL intensities evolution. The results, which highlight the influence of molecular structure on stability under aging conditions, as presented by the calculated for the activation energy (kJ mol -1 ), show the following sequence: SBS (styrene 30%) (117 kJ mol -1 ) ≈ SIS 120 (kJ mol -1 ) < SBS (styrene 40%) (176 kJ mol -1 ) < SEBS (180 kJ mol -1 ). The CL data were correlated with infrared (IR) spectroscopy and differential scanning calorimetry (DSC) data, providing a comprehensive understanding of the thermal stability and degradation mechanisms during recycling proces. The sequence of the composing units determines the degradation process, with weaker points predominantly attacked in the linear moieties of isoprene, butadiene, and vinyl segments. The experimental data indicate that SIS and SBS (30% styrene) copolymers degrade the fastest likely due to the rapid accumulation of hydroperoxide radicals. The SEBS copolymer also experiences significant degradation, but this occurs at higher temperatures (above 220 ⁰C) and progresses more gradually once it begins. In contrast, the SBS copolymer with 40% styrene content degrades more slowly and exhibits minimal mass loss, primarily due to the formation of less reactive keto degradation products., Competing Interests: Declarations Competing interests The authors declare no competing interests., (© 2024. The Author(s).)

Published

2024

5. Stability Qualification of Resins/Metallic Oxide Composites for Surface Oxidative Protection.

Author

Zaharescu T, Mirea R, Borbath T, and Borbath I

Abstract

The accelerated degradation of alkyd resins via γ-irradiation is investigated using non-isothermal chemiluminescence. The stability qualification is possible through the comparison of emission intensities on a temperature range starting from 100 °C up to 250 °C under accelerated degradation caused by radiolysis scission. The measurements achieved in the samples of cured state resin modified by various inorganic oxides reveal the influence of metallic traces on the aging amplitude, when the thermal resistance increases as the irradiation dose is augmented. Even though the unirradiated samples present a prominent chemiluminescence intensity peak at 80 °C, the γ-processed specimens show less intense spectra under the pristine materials and the oxidation starts smoothly after 75 °C. The values of activation energies required for oxidative degradation of the sample subjected to 100 kGy are significantly higher in the composite states than in the neat resin. The degradation mechanism of polymerized resins is discussed taking into account the effects of fillers on the stability of studied epoxy resin at various temperatures when the degradation and crosslinking are in competition for the decay of free radical.

Published

2024

6. The Contribution of BaTiO 3 to the Stability Improvement of Ethylene-Propylene-Diene Rubber: Part II-Doped Filler.

Author

Zaharescu T, Dumitru A, Borbath T, Ionescu I, Borbath I, and Boros TF

Abstract

The thermal and radiation stabilities of the formulations based on ethylene-propylene-diene rubber (EPDM), which contain barium titanate (BaTiO 3 ) doped with lanthanum and cerium oxides, were investigated by chemiluminescence and mechanical testing. The contributions of these doped fillers are related to the surface interaction between the structural defects (doping atoms, i.e., lanthanum and cerium) implanted in the filler lattice and the molecular fragments formed during the progress of degradation. These composite materials present extended durabilities with respect to the references; the oxidation periods are a minimum of three times longer than the corresponding times for pristine polymers. This behavior is associated with the scavenging activity of dopants. Mechanical testing has demonstrated the contributions of doped filler to the improvement of tensile strength and elongation at break by the restructuration of the polymer phase. Scanning electron microscopy images revealed the densification of materials in the presence of doped barium titanates. All the investigations constitute valid proof for the qualification of BaTiO 3 doped with Ce as the more efficient stabilizer compared to the same inorganic filler doped with La.

Published

2023

7. The Contribution of BaTiO 3 to the Stability Improvement of Ethylene-Propylene-Diene Rubber: Part I-Pristine Filler.

Author

Borbath T, Nicula N, Zaharescu T, Borbath I, and Boros TF

Abstract

This study presents the functional effects of BaTiO 3 powder loaded in ethylene-propylene-diene rubber (EPDM) in three concentrations: 0, 1, and 2.5 phr. The characterization of mechanical properties, oxidation strength, and biological vulnerability is achieved on these materials subjected to an accelerated degradation stimulated by their γ-irradiation at 50 and 100 kGy. The thermal performances of these materials are improved when the content of filler becomes higher. The results obtained by chemiluminescence, FTIR-ATR, and mechanical testing indicate that the loading of 2.5 phr is the most proper composition that resists for a long time after it is γ-irradiated at a high dose. If the oxidation starts at 176 °C in the pristine polymer, it becomes significant at 188 and 210 °C in the case of composites containing 1 and 2.5 phr of filler, respectively. The radiation treatment induces a significant stability improvement measured by the enlargement of temperature range by more than 1.5 times, which explains the durability growth for the radiation-processed studied composites. The extension of the stability period is also based on the interaction between degrading polymer substrate and particle surface in the composite richest in titanate fraction when the exposure is 100 kGy was analyzed. The mechanical testing as well as the FTIR investigation clearly delimits the positive effects of carbon black on the functionality of EPDM/BaTiO 3 composites. The contribution of carbon black is a defining feature of the studied composites based on the nucleation of the host matrix by which the polymer properties are effectively ameliorated.

Published

2023

8. Phosphorus transversal relaxation times and metabolite concentrations in the human brain at 9.4 T.

Author

Dorst J, Borbath T, Ruhm L, and Henning A

Subjects

Adenosine Triphosphate metabolism, Humans, Magnetic Resonance Spectroscopy, Phosphates metabolism, Brain diagnostic imaging, Brain metabolism, Phosphorus metabolism

Abstract

A method to estimate phosphorus ( 31 P) transversal relaxation times (T 2 s) of coupled spin systems is demonstrated. Additionally, intracellular and extracellular pH and relaxation-corrected metabolite concentrations are reported. Echo time (TE) series of 31 P metabolite spectra were acquired using stimulated echo acquisition mode (STEAM) localization. Spectra were fitted using LCModel with accurately modeled Versatile Simulation, Pulses and Analysis (VeSPA) basis sets accounting for J-evolution of the coupled spin systems. T 2 s were estimated by fitting a single exponential two-parameter model across the TE series. Fitted inorganic phosphate frequencies were used to calculate pH, and estimated relaxation times were used to determine the relaxation-corrected brain metabolite concentrations on an assumption of 3 mM γ-ATP. The method was demonstrated in healthy human brain at a field strength of 9.4 T. T 2 times of ATP and nicotinamide adenine dinucleotide (NAD) were shortest between 8 and 20 ms, followed by T 2 s of inorganic phosphate between 25 and 50 ms, and phosphocreatine with a T 2 of 100 ms. Phosphomonoesters and phosphodiesters had the longest T 2 s of about 130 ms. The measured T 2 s are comparable with literature values and fit in a decreasing trend with increasing field strengths. Calculated pHs and metabolite concentrations are also comparable with literature values., (© 2022 The Authors. NMR in Biomedicine published by John Wiley & Sons Ltd.)

Published

2022

9. Simultaneous detection of metabolite concentration changes, water BOLD signal and pH changes during visual stimulation in the human brain at 9.4T.

Author

Dorst J, Borbath T, Landheer K, Avdievich N, and Henning A

Subjects

Brain metabolism, Glutamic Acid metabolism, Humans, Hydrogen-Ion Concentration, Lactic Acid metabolism, Photic Stimulation, Magnetic Resonance Imaging methods, Water metabolism

Abstract

This study presents a method to directly link metabolite concentration changes and BOLD response in the human brain during visual stimulation by measuring the water and metabolite signals simultaneously. Therefore, the metabolite-cycling (MC) non-water suppressed semiLASER localization technique was optimized for functional 1 H MRS in the human brain at 9.4 T. Data of 13 volunteers were acquired during a 26:40 min visual stimulation block-design paradigm. Activation-induced BOLD signal was observed in the MC water signal as well as in the NAA-CH 3 and tCr-CH 3 singlets. During stimulation, glutamate concentration increased 2.3 ± 2.0% to a new steady-state, while a continuous increase over the whole stimulation period could be observed in lactate with a mean increase of 35.6 ± 23.1%. These increases of Lac and Glu during brain activation confirm previous findings reported in literature. A positive correlation of the MC water BOLD signal with glutamate and lactate concentration changes was found. In addition, a pH decrease calculated from a change in the ratio of PCr to Cr was observed during brain activation, particularly at the onset of the stimulation.

Published

2022

10. Relaxation-corrected macromolecular model enables determination of 1 H longitudinal T 1 -relaxation times and concentrations of human brain metabolites at 9.4T.

Author

Wright AM, Murali-Manohar S, Borbath T, Avdievich NI, and Henning A

Subjects

Brain Chemistry, Gray Matter metabolism, Humans, Macromolecular Substances metabolism, Brain diagnostic imaging, Brain metabolism, White Matter metabolism

Abstract

Purpose: Ultrahigh field MRS has improved characterization of the neurochemical profile. To compare results obtained at 9.4T to those from lower field strengths, it is of interest to quantify the concentrations of metabolites measured. Thus, measuring T 1 -relaxation times is necessary to correct for T 1 -weighting that occurs in acquisitions for single-voxel spectroscopy and spectroscopic imaging. A macromolecule (MM) simulation model was developed to fit MM contributions to the short TE inversion series used to measure T 1 -relaxation times., Methods: An inversion series with seven time points was acquired with metabolite-cycled STEAM to estimate T 1 -relaxation times of metabolites. A short TE was employed in this study to retain signals from metabolites with short T 2 -relaxation times and J-couplings. The underlying macromolecule spectrum was corrected by developing a sequence-specific, relaxation-corrected simulated MM model. Quantification of metabolite peaks was performed using internal water referencing and relaxation corrections., Results: T 1 -relaxation times for metabolites range from approximately 750 to approximately 2000 ms and approximately 1000 to approximately 2400 ms in gray matter (GM)- and white matter (WM)- rich voxels, respectively. Quantification of metabolites was compared between GM and WM voxels, as well as between results that used a simulated MM spectrum against those that used an experimentally acquired MM spectrum. Metabolite concentrations are reported in mmol/kg quantities., Conclusion: T 1 -relaxation times are reported for nonsinglet resonances for the first time at 9.4T by use of a MM simulation model to account for contributions from the MM spectrum. In addition to T 1 -relaxation times, quantification results of metabolites from GM- and WM-rich voxels are reported., (© 2021 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published

2022

11. ProFit-1D-A 1D fitting software and open-source validation data sets.

Author

Borbath T, Murali-Manohar S, Dorst J, Wright AM, and Henning A

Subjects

Brain, Magnetic Resonance Spectroscopy, Algorithms, Software

Abstract

Purpose: Accurate and precise MRS fitting is crucial for metabolite concentration quantification of 1 H-MRS spectra. LCModel, a spectral fitting software, has shown to have certain limitations to perform advanced spectral fitting by previous literature. Herein, we propose an open-source spectral fitting algorithm with adaptive spectral baseline determination and more complex cost functions., Theory: The MRS spectra are characterized by several parameters, which reflect the environment of the contributing metabolites, properties of the acquisition sequence, or additional disturbances. Fitting parameters should accurately describe these parameters. Baselines are also a major contributor to MRS spectra, in which smoothness of the spline baselines used for fitting can be adjusted based on the properties of the spectra. Three different cost functions used for the minimization problem were also investigated., Methods: The newly developed ProFit-1D fitting algorithm is systematically evaluated for simulations of several types of possible in vivo parameter variations. Although accuracy and precision are tested with simulated spectra, spectra measured in vivo at 9.4 T are used for testing precision using subsets of averages. ProFit-1D fitting results are also compared with LCModel., Results: Both ProFit-1D and LCModel fitted the spectra well with induced parameter and baseline variations. ProFit-1D proved to be more accurate than LCModel for simulated spectra. However, LCModel showed a somewhat increased precision for some spectral simulations and for in vivo data., Conclusion: The open-source ProFit-1D fitting algorithm demonstrated high accuracy while maintaining precise metabolite concentration quantification. Finally, through the newly proposed cost functions, new ways to improve fitting were shown., (© 2021 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published

2021

12. In vivo macromolecule signals in rat brain 1 H-MR spectra at 9.4T: Parametrization, spline baseline estimation, and T 2 relaxation times.

Author

Simicic D, Rackayova V, Xin L, Tkáč I, Borbath T, Starcuk Z Jr, Starcukova J, Lanz B, and Cudalbu C

Subjects

Animals, Macromolecular Substances metabolism, Rats, Brain diagnostic imaging, Brain metabolism, Brain Chemistry

Abstract

Purpose: Reliable detection and fitting of macromolecules (MM) are crucial for accurate quantification of brain short-echo time (TE) 1 H-MR spectra. An experimentally acquired single MM spectrum is commonly used. Higher spectral resolution at ultra-high field (UHF) led to increased interest in using a parametrized MM spectrum together with flexible spline baselines to address unpredicted spectroscopic components. Herein, we aimed to: (1) implement an advanced methodological approach for post-processing, fitting, and parametrization of 9.4T rat brain MM spectra; (2) assess the concomitant impact of the LCModel baseline and MM model (ie, single vs parametrized); and (3) estimate the apparent T 2 relaxation times for seven MM components., Methods: A single inversion recovery sequence combined with advanced AMARES prior knowledge was used to eliminate the metabolite residuals, fit, and parametrize 10 MM components directly from 9.4T rat brain in vivo 1 H-MR spectra at different TEs. Monte Carlo simulations were also used to assess the concomitant influence of parametrized MM and DKNTMN parameter in LCModel., Results: A very stiff baseline (DKNTMN ≥ 1 ppm) in combination with a single MM spectrum led to deviations in metabolite concentrations. For some metabolites the parametrized MM showed deviations from the ground truth for all DKNTMN values. Adding prior knowledge on parametrized MM improved MM and metabolite quantification. The apparent T 2 ranged between 12 and 24 ms for seven MM peaks., Conclusion: Moderate flexibility in the spline baseline was required for reliable quantification of real/experimental spectra based on in vivo and Monte Carlo data. Prior knowledge on parametrized MM improved MM and metabolite quantification., (© 2021 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published

2021

13. Contribution of macromolecules to brain 1 H MR spectra: Experts' consensus recommendations.

Author

Cudalbu C, Behar KL, Bhattacharyya PK, Bogner W, Borbath T, de Graaf RA, Gruetter R, Henning A, Juchem C, Kreis R, Lee P, Lei H, Marjańska M, Mekle R, Murali-Manohar S, Považan M, Rackayová V, Simicic D, Slotboom J, Soher BJ, Starčuk Z Jr, Starčuková J, Tkáč I, Williams S, Wilson M, Wright AM, Xin L, and Mlynárik V

Subjects

Adult, Aged, Aged, 80 and over, Humans, Lipids chemistry, Magnetic Resonance Imaging, Metabolome, Middle Aged, Models, Theoretical, Signal Processing, Computer-Assisted, Young Adult, Brain diagnostic imaging, Consensus, Expert Testimony, Macromolecular Substances metabolism, Proton Magnetic Resonance Spectroscopy

Abstract

Proton MR spectra of the brain, especially those measured at short and intermediate echo times, contain signals from mobile macromolecules (MM). A description of the main MM is provided in this consensus paper. These broad peaks of MM underlie the narrower peaks of metabolites and often complicate their quantification but they also may have potential importance as biomarkers in specific diseases. Thus, separation of broad MM signals from low molecular weight metabolites enables accurate determination of metabolite concentrations and is of primary interest in many studies. Other studies attempt to understand the origin of the MM spectrum, to decompose it into individual spectral regions or peaks and to use the components of the MM spectrum as markers of various physiological or pathological conditions in biomedical research or clinical practice. The aim of this consensus paper is to provide an overview and some recommendations on how to handle the MM signals in different types of studies together with a list of open issues in the field, which are all summarized at the end of the paper., (© 2020 John Wiley & Sons, Ltd.)

Published

2021

14. In vivo characterization of downfield peaks at 9.4 T: T 2 relaxation times, quantification, pH estimation, and assignments.

Author

Borbath T, Murali-Manohar S, Wright AM, and Henning A

Subjects

Humans, Hydrogen-Ion Concentration, Magnetic Resonance Spectroscopy, Water, Brain diagnostic imaging, Protons

Abstract

Purpose: Relaxation times are a valuable asset when determining spectral assignments. In this study, apparent T 2 relaxation times ( T 2 app ) of downfield peaks are reported in the human brain at 9.4 T and are used to guide spectral assignments of some downfield metabolite peaks., Methods: Echo time series of downfield metabolite spectra were acquired at 9.4 T using a metabolite-cycled semi-LASER sequence. Metabolite spectral fitting was performed using LCModel V6.3-1L while fitting a pH sweep to estimate the pH of the homocarnosine (hCs) imidazole ring. T 2 app were calculated by fitting the resulting relative amplitudes of the peaks to a mono-exponential decay across the TE series. Furthermore, estimated tissue concentrations of molecules were calculated using the relaxation times and internal water as a reference., Results: T 2 app of downfield metabolites are reported within a range from 16 to 32 ms except for homocarnosine with T 2 app of 50 ms. Correcting T 2 app for exchange rates ( T 2 c o r r ) resulted in relaxation times between 20 and 33 ms. The estimated pH values based on hCs imidazole range from 7.07 to 7.12 between subjects. Furthermore, analyzing the linewidths of the downfield peaks and their T 2 app contribution led to possible peak assignments., Conclusion: T 2 app relaxation times were longer for the assigned metabolite peaks compared to the unassigned peaks. Tissue pH estimation in vivo with proton MRS and simultaneous quantification of amide protons at 8.30 ± 0.15 ppm is likely possible. Based on concentration, linewidth, and exchange rates measurements, tentative peak assignments are discussed for adenosine triphosphate (ATP), N-acetylaspartylglutamate (NAAG), and urea., (© 2020 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published

2021

15. A novel method to measure T 1 -relaxation times of macromolecules and quantification of the macromolecular resonances.

Author

Murali-Manohar S, Wright AM, Borbath T, Avdievich NI, and Henning A

Subjects

Brain Chemistry, Humans, Macromolecular Substances metabolism, Magnetic Resonance Imaging, Vibration, Brain diagnostic imaging, Brain metabolism, White Matter metabolism

Abstract

Purpose: Macromolecular peaks underlying metabolite spectra influence the quantification of metabolites. Therefore, it is important to understand the extent of contribution from macromolecules (MMs) in metabolite quantification. However, to model MMs more accurately in spectral fitting, differences in T 1 relaxation times among individual MM peaks must be considered. Characterization of T 1 -relaxation times for all individual MM peaks using a single inversion recovery technique is difficult due to eventual contributions from metabolites. On the contrary, a double inversion recovery (DIR) technique provided flexibility to acquire MM spectra spanning a range of longitudinal magnetizations with minimal metabolite influence. Thus, a novel method to determine T 1 -relaxation times of individual MM peaks is reported in this work., Methods: Extensive Bloch simulations were performed to determine inversion time combinations for a DIR technique that yielded adequate MM signal with varying longitudinal magnetizations while minimizing metabolite contributions. MM spectra were acquired using DIR-metabolite-cycled semi-LASER sequence. LCModel concentrations were fitted to the DIR signal equation to calculate T 1 -relaxation times., Results: T 1 -relaxation times of MMs range from 204 to 510 ms and 253 to 564 ms in gray- and white-matter rich voxels respectively at 9.4T. Additionally, concentrations of 13 MM peaks are reported., Conclusion: A novel DIR method is reported in this work to calculate T 1 -relaxation times of MMs in the human brain. T 1 -relaxation times and relaxation time corrected concentrations of individual MMs are reported in gray- and white-matter rich voxels for the first time at 9.4T., (© 2020 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.)

Published

2021

16. T 2 relaxation times of macromolecules and metabolites in the human brain at 9.4 T.

Author

Murali-Manohar S, Borbath T, Wright AM, Soher B, Mekle R, and Henning A

Subjects

Brain Chemistry, Humans, Macromolecular Substances metabolism, Magnetic Resonance Spectroscopy, Brain diagnostic imaging, Brain metabolism, Magnetic Resonance Imaging

Abstract

Purpose: Relaxation times can contribute to spectral assignment. In this study, effective T 2 relaxation times ( T 2 eff ) of macromolecules are reported for gray and white matter-rich voxels in the human brain at 9.4 T. The T 2 eff of macromolecules are helpful to understand their behavior and the effect they have on metabolite quantification. Additionally, for absolute quantification of metabolites with magnetic resonance spectroscopy, appropriate T 2 values of metabolites must be considered. The T 2 relaxation times of metabolites are calculated after accounting for TE/sequence-specific macromolecular baselines., Methods: Macromolecular and metabolite spectra for a series of TEs were acquired at 9.4 T using double inversion-recovery metabolite-cycled semi-LASER and metabolite-cycled semi-LASER, respectively. The T 2 relaxation times were calculated by fitting the LCModel relative amplitudes of macromolecular peaks and metabolites to a mono-exponential decay across the TE series. Furthermore, absolute concentrations of metabolites were calculated using the estimated relaxation times and internal water as reference., Results: The T 2 eff of macromolecules are reported, which range from 13 ms to 40 ms, whereas, for metabolites, they range from 40 ms to 110 ms. Both macromolecular and metabolite T 2 relaxation times are observed to follow the decreasing trend, with increasing B 0 . The linewidths of metabolite singlets can be fully attributed to T 2 and B 0 components. However, in addition to these components, macromolecule linewidths have contributions from J-coupling and overlapping resonances., Conclusion: The T 2 relaxation times of all macromolecular and metabolite peaks at 9.4 T in vivo are reported for the first time. Metabolite relaxation times were used to calculate the absolute metabolite concentrations., (© 2020 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals, Inc. on behalf of International Society for Magnetic Resonance in Medicine.)

Published

2020

17. Durability of LDPE/UHMWPE Composites under Accelerated Degradation.

Author

Zaharescu T, Râpă M, Blanco I, Borbath T, and Borbath I

Abstract

This study presents a detailed analysis of thermal and radiation resistances of low density polyethylene (LDPE)/ultra-high molecular weight polyethylene (UHMWPE) blends containing hydroxyapatite as functional filler and rosemary acting as antioxidant against oxidative degradation. Three main procedures, chemiluminescence (CL), Fourier transform infrared spectroscopy (FTIR), and differential scanning calorimetry (DSC), were applied for the determination of the degree of degradation when these materials are subjected to heat and radiation action. The crystallinity was also assessed for the characterization of diffusion peculiarities. The contributions of the mixing components are discussed based on their oxidation strength. The activation energies required for the oxidative degradation of the studied formulations were calculated.

Published

2020

18. Investigation of the influence of macromolecules and spline baseline in the fitting model of human brain spectra at 9.4T.

Author

Giapitzakis IA, Borbath T, Murali-Manohar S, Avdievich N, and Henning A

Subjects

Adult, Brain Chemistry, Female, Healthy Volunteers, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Spectroscopy, Male, Occipital Lobe diagnostic imaging, Occipital Lobe metabolism, Parietal Lobe diagnostic imaging, Protons, Signal-To-Noise Ratio, Brain diagnostic imaging, Brain metabolism, Macromolecular Substances metabolism

Abstract

Purpose: In this study, the influence of experimentally measured macromolecules and spline baseline on the quantification results of proton MRS data was investigated., Methods: Proton MRS spectra from the left parietal lobe and the occipital lobe were acquired at 9.4T in the human brain using metabolite-cycled semi-LASER. Then, the left parietal lobe data, along with the occipital lobe, spectra were quantified and the influence of the inclusion of experimentally measured macromolecular basis sets in the fitting model was evaluated. Furthermore, the effect of the stiffness of the fitted spline baselines on the resulting metabolite concentrations was evaluated., Results: In general, concentrations were higher for metabolites in occipital lobe than the left parietal lobe. The inclusion of an experimentally acquired measured macromolecular basis set from another brain region neither affected the quantification results nor the resulting spline baselines significantly. A highly flexible spline baseline led to overestimation or underestimation of metabolite concentrations. Differences of above 15% in the quantification of metabolite levels for both lobes were observed for several metabolites using LCModel default settings for spline baselines and macromolecules in comparison to stiffer spline baselines., Conclusion: Fitting with the default LCModel macromolecular basis set and spline baseline model had significant influence in the resulting spline baselines, leading to large deviations both in the concentrations and fitted macromolecular components. The number of knots in the spline may create overflexible baselines, which can potentially lead to quantification errors. Interestingly, the interchange of macromolecular basis set between occipital lobe and left parietal lobe spectra had less influence on the quantification results compared to the default LCModel settings., (© 2018 International Society for Magnetic Resonance in Medicine.)

Published

2019