Quantitative Microstructural Imaging for Clinical Use

Gian Franco Piredda
EPFL, 2021
Thèse EPFL

Résumé

Today, Magnetic Resonance Imaging (MRI) is a well-established medical imaging modality thanks to its excellent soft tissue contrast. Conventional MR image contrasts can be weighted towards one or more physical properties that discriminate different tissues, which represents one of the main advantages of MRI compared to other imaging techniques. However, conventional contrasts always depend on the combination of different tissue properties, imaging parameters and employed hardware. Quantitative MRI (qMRI) techniques allow moving from such relative contrast information to a single, absolute measure of one or more separate tissue properties.The measurement of water proton relaxation rates represents one major approach for quantitatively characterizing the human brain tissue microstructure with MRI. MR relaxation mechanisms depend on complex interactions among protons and between protons and their surrounding lattice. Hence, important determining factors of the physical parameters measured with qMRI are, for example, the concentration of water, macromolecules (for instance abundant in myelin) and paramagnetic atoms (e.g., iron). The exhibited sensitivity and specificity of qMRI acquisitions towards the microstructural properties of brain tissues drove an incremental investigation around qMRI metrics as biomarkers for alterations caused by disease. However, the practical use of qMRI in clinical settings is still hindered by difficulties in delivering precise quantification in an adequate resolution and within acquisition times comparable to conventional imaging. Moreover, to exploit the full potential of quantitative maps, normative values of physical parameters in healthy tissues are required, enabling the comparison of tissue properties from a single patient to normal values, potentially improving diagnosis and follow-up assessments.With a focus on brain relaxometry and myelin water imaging, this thesis aims at bringing qMRI closer to clinical routine by tackling challenges ranging from the image acquisition to its practical application. More specifically, a validated T2 relaxometry sequence for myelin imaging - the multi-echo gradient and spin echo sequence - has been implemented and subsequently accelerated by combining it with parallel imaging to achieve whole brain coverage in a clinical compatible acquisition time. The direct estimation of microstructural features from relaxometry data has been also investigated using a fast protocol for T1 and T2 mapping and a data-driven approach that takes advantage of recent advances in the machine learning domain. Finally, the clinical value of qMRI in conjunction with normative atlases of physical properties has been explored to detect personalized changes in tissue parameters that reflect the underlying pathology.

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https://infoscience.epfl.ch/record/289805?ln=fr

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Gian Franco Piredda
EPFL, 2021
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/289805?ln=fr

À propos de ce résultat

Concepts associés (19)

Concepts associés

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Publications associées (4)

Publications associées

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Variability and reproducibility of multi-echo T2 relaxometry: Insights from multi-site, multi-session and multi-subject MRI acquisitions

Elena Beanato, Julia Brügger, Andéol Geoffroy Cadic-Melchior, Erick Jorge Canales Rodriguez, Alessandro Daducci, Elda Fischi Gomez, Gabriel Girard, Tom Hilbert, Friedhelm Christoph Hummel, Tobias Kober, Philipp Johannes Koch, Takuya Morishita, Chang-Hyun Park, Gian Franco Piredda, Marco Pizzolato, Jean-Philippe Thiran, Maximilian Jonas Wessel, Thomas Yu

Quantitative magnetic resonance imaging (qMRI) can increase the specificity and sensitivity of conventional weighted MRI to underlying pathology by comparing meaningful physical or chemical parameters, measured in physical units, with normative values acquired in a healthy population. This study focuses on multi-echo T2 relaxometry, a qMRI technique that probes the complex tissue microstructure by differentiating compartment-specific T2 relaxation times. However, estimation methods are still limited by their sensitivity to the underlying noise. Moreover, estimating the model's parameters is challenging because the resulting inverse problem is ill-posed, requiring advanced numerical regularization techniques. As a result, the estimates from distinct regularization strategies are different. In this work, we aimed to investigate the variability and reproducibility of different techniques for estimating the transverse relaxation time of the intra- and extra-cellular space (TIE2 ) in gray (GM) and white matter (WM) tissue in a clinical setting, using a multi-site, multi-session, and multi-run T2 relaxometry dataset. To this end, we evaluated three different techniques for estimating the T2 spectra (two regularized non-negative least squares methods and a machine learning approach). Two independent analyses were performed to study the effect of using raw and denoised data. For both the GM and WM regions, and the raw and denoised data, our results suggest that the principal source of variance is the inter-subject variability, showing a higher coefficient of variation (CoV) than those estimated for the inter-site, inter-session, and inter-run, respectively. For all reconstruction methods studied, the CoV ranged between 0.32 and 1.64%. Interestingly, the inter-session variability was close to the inter-scanner variability with no statistical differences, suggesting that TIE2 is a robust parameter that could be employed in multi-site neuroimaging studies. Furthermore, the three tested methods showed consistent results and similar intra-class correlation (ICC), with values superior to 0.7 for most regions. Results from raw data were slightly more reproducible than those from denoised data. The regularized non-negative least squares method based on the L-curve technique produced the best results, with ICC values ranging from 0.72 to 0.92.

2022

Chargement

Dinuclear gadolinium (III) chelates

Jéröme Costa

In 2003, the Nobel Assembly at the Karolinska Institute has awarded the Nobel Prize in Medicine or Physiology to Paul Lauterbur and Peter Mansfield for their seminal discoveries concerning the development of Magnetic Resonance Imaging (MRI), a non-invasive diagnosis technique notably used in medicine to visualize the human internal organs and to distinguish between healthy and pathological cells. For this purpose, contrast agents are valuable tools that enhance this distinction which is resulting from the difference in the water content of the different tissues. These drugs are used nowadays in more than 30% of the 60 millions MRI examinations performed each year. And both numbers are still growing fast. Most of the contrast agents contain a paramagnetic ion (GdIII) that accelerates the relaxation of the water protons by providing them a new relaxation pathway. Relaxivity is a way of quantifying the contrast agent efficiency and is governed by four key parameters: hydration number of the lanthanide ion, water exchange rate, electronic relaxation rate and rotational correlation time of the system. A judicious simultaneous optimization of these parameters is predicted to result in a 20-fold increase in relaxivity compared to the currently used contrast agents. In this work, with the aim of increasing the relaxivity and better understanding the involved mechanisms, the synthesis and physico-chemical characterization of new dinuclear GdIII complexes, based on thoroughly studied monomeric equivalents, were performed. We particularly stressed the outmost importance of introducing rigidity together with the increased size of the system, for a flexible assembly will hinder the relaxivity gain brought by the higher molecular weight. This rigidity is induced by using an aromatic linker between the chelating subunits or by means of the self-assembling properties of terpyridine units around FeII or RuII. We investigated the thermodynamic stability, which in crucial for toxicological reason, the spectrophotometric properties, and the rotational and water exchange dynamics of these complexes. As a result, a remarkable increase in relaxivity is obtained for all the studied compounds with respect to the clinically used actual contrast agents. Finally, insights into a promising novel class of MRI contrast agents acting simultaneously as luminescence probes are provided.

EPFL2005

Chargement

During the last two decades, magnetic resonance imaging (MRI) has evolved into one of the most powerful techniques in medical diagnosis. Among the various medical diagnostic modalities, such as X-ray or ultra-sound imaging, MRI is the technique of choice especially because of its non-invasive character, the absence of ionizing radiations and its high spatial resolution. The principle of an MRI examination relies on the relaxation of water protons in the human body placed in a magnetic field after radiofrequency excitations. MRI is sensitive to the nature of the soft tissues, to the proton density and to the relaxation rate of protons to produce a contrast. The development of MRI is closely related to the successful use of paramagnetic contrast agents, essentially gadolinium(III) complexes. Unlike contrast agents used in other clinical imaging techniques, the MRI contrast agents are not themselves imaged but rather enhance the nuclear relaxation rate of water protons in their vicinity. The use of MRI contrast agents induces not only a better image contrast and a better delineating of diseased tissues but also a shortening of the examination time. Since the discovery of GdIII chelates as MRI contrast agents, a lot of effort has been made to increase their relaxivity, i.e. the gauge of efficiency of the contrast agent. In the work presented in this thesis, two groups of paramagnetic compounds have been studied: GdIII poly(amino carboxylates) and GdIII trapped in carbon cage compounds. For traditional monohydrated GdIII poly(amino carboxylate) complexes, the Solomon- Bloembergen-Morgan equations predict maximum proton relaxivities of 100 mM-1 s-1, instead of 4-5 mM-1 s-1 for commercial agents, when the three most important influencing factors, the rotation, the electron spin relaxation and the water exchange rate are simultaneously optimized. On the basis of structural considerations in the inner sphere of nine-coordinate, monohydrated GdIII poly(amino carboxylate) complexes, we succeeded in accelerating the water exchange by inducing steric compression around the water binding site. We modified the common DTPA5- ligand by replacing one ethylene bridge of the amine backbone by a propylene one (EPTPA5--based ligand), leading to a water exchange rate two orders of magnitude higher than that for the commercial [Gd(DTPA)(H2O)]2-. The replacement of two ethylene bridges (DPTPA5-) results in the elimination of the water molecule from the inner sphere. Although the thermodynamic stability of [Gd(EPTPA-bz-NO2)(H2O)]2- is reduced to a slight extent in comparison to [Gd(DTPA)(H2O)]2-, it is stable enough to be used in medical diagnosis. The next step to obtain high relaxivity contrast agents is the covalent coupling of GdIII EPTPA complexes to three generations (5, 7 and 9) of PAMAM dendrimers to ensure fast water exchange rate and slow rotation. These macromolecular GdIII complexes allow high relaxivities with maximum values at magnetic fields presently used in clinical applications thanks to slow molecular tumbling. The relaxivities show a strong and reversible pH dependency for all three dendrimer generations. This smart behaviour originates from the pHdependent rotational dynamics of the dendrimer skeleton. From the studies on the monomeric and dendrimeric GdIII EPTPA complexes, general considerations have been proposed about the crucial need of more rigid macromolecular assemblies to obtain the highest relaxivity values predicted by the Solomon-Bloembergen-Morgan equations. Water-soluble fullerenes and carbon nanotubes have shown a great potential for various biological and medical applications. Gadofullerenes have been proposed not only as high relaxivity contrast agents thanks to the high number of water molecules close to the paramagnetic centre and their slow tumbling arising from aggregation phenomena but also as smart pH-responsive drugs. Proton relaxivity was proposed as an ideal aggregation-state sensor for the disruption of the water-soluble Gd@C60(OH)x (x ≈ 27) and Gd@C60[C(COOH)2]10 aggregates upon salt addition. This phenomenon has important implications for biological or biomedical applications of fullerene-based materials, since real biological fluids present a rather high salt concentration. With the aim of gaining more insight into the paramagnetic relaxation mechanism induced by water-soluble gadofullerenes, an NMR analysis with the common techniques used for GdIII MRI contrast agents allowed a comparison between the aggregated and the disaggregated systems. In analogy to C60 buckyballs, ultra-short single-walled nanotubes have been loaded with Gd3+ aqua-ions clusters. These Gdn3+@US-tubes, which self-organise into bundles-like structures, exhibit relaxivities up to 90 times higher (depending on the magnetic field) than that of any GdIII-based MRI contrast agent in current clinical use.

EPFL2005

Chargement

EPFL2005

Dinuclear gadolinium (III) chelates

Jéröme Costa

EPFL2005

Variability and reproducibility of multi-echo T2 relaxometry: Insights from multi-site, multi-session and multi-subject MRI acquisitions

2022