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Review ArticleAdult Brain
Open Access

Quantitative MRI in Multiple Sclerosis: From Theory to Application

M. Tranfa, G. Pontillo, M. Petracca, A. Brunetti, E. Tedeschi, G. Palma and S. Cocozza
American Journal of Neuroradiology December 2022, 43 (12) 1688-1695; DOI: https://doi.org/10.3174/ajnr.A7536

Abstract

SUMMARY: Quantitative MR imaging techniques allow evaluating different aspects of brain microstructure, providing meaningful information about the pathophysiology of damage in CNS disorders. In the study of patients with MS, quantitative MR imaging techniques represent an invaluable tool for studying changes in myelin and iron content occurring in the context of inflammatory and neurodegenerative processes. In the first section of this review, we summarize the physics behind quantitative MR imaging, here defined as relaxometry and quantitative susceptibility mapping, and describe the neurobiological correlates of quantitative MR imaging findings. In the second section, we focus on quantitative MR imaging application in MS, reporting the main findings in both the gray and white matter compartments, separately addressing macroscopically damaged and normal-appearing parenchyma.

ABBREVIATIONS:

bSSFP
balanced steady-state free precession
CL
cortical lesions
GRE
gradient recalled-echo
NAWM
normal-appearing white matter
PD
proton density
qMRI
quantitative MR imaging
QSM
quantitative susceptibility mapping
RF
radiofrequency

While conventional MR imaging plays an unquestionable role in the diagnosis and management of MS,1,2 it offers very limited information about the pathophysiology of tissue damage because conventional sequences are not able to detect subtle changes affecting WM and GM. Quantitative MR imaging (qMRI) bridges this gap, detecting brain microstructural alterations with high sensitivity and robustness to interscanner and interobserver variability, thus providing measures that can be compared among sites and longitudinal examinations. Furthermore, this technique has been successfully used to differentiate MS from other demyelinating diseases, such as neuromyelitis optica, which presents a different spectrum of relaxometry alterations3 and a peculiar spatial deep gray matter involvement,4 and also to characterize other conditions with different etiologies, from vascular disease to brain tumors.5,6 However, the applications of qMRI extend beyond the brain, being able to depict changes in liver iron concentration7 as well as the presence of fibrosis,8 and prostatic calcifications,9 and to evaluate cortical bone mineral density10 or myocardial structural alterations.11

Although the definition of qMRI is open to different interpretations, several advanced MR imaging techniques are usually grouped under this umbrella, including relaxometry, magnetic susceptibility, diffusion invariants, magnetization transfer, and, to some extent, perfusion parameters.12 Each of these techniques offers different, sometimes complementary, insights into the complex tissue alterations occurring in MS.13 In this light, it is noteworthy to remember that, while demyelination represents the end result of a complex phenomenon of inflammation, ultimately leading to axonal and neuronal degeneration, change in iron homeostasis is a crucial step in the pathophysiology of damage in MS, linked to microglial activation and modifications in oligodendrocyte functionality.14,15 Relaxometry plays a unique role, given that most of the above-mentioned qMRI techniques offer valuable and sensitive tools in myelin assessment but they lack iron-detection sensitivity. Indeed, relaxometry assesses abnormalities of iron and myelin, elements that are at the crossroads of the inflammatory and neurodegenerative components in MS pathophysiology.12

In this review, we summarize the role and the application of qMRI techniques, here defined as relaxometry (estimating R1, R2, R2*, and, by extension, proton density [PD]) and quantitative susceptibility mapping (QSM), to the study of patients with MS.

In the first section, we briefly describe the physics behind qMRI, together with its neurobiological correlates. In the second section, we summarize brain qMRI findings in MS for both the normal-appearing parenchyma and lesions in the GM and WM compartments.

qMRI Theory

Impact of Excitation Pulses and Significance of 3D Sequences.

The R1 and R2 relaxation rates, defined as the inverses of T1 and T2 relaxation times, measure the efficiency of the kinetics mechanisms restoring the thermal equilibrium of the longitudinal and transverse components of the spin isochromats. An isochromat represents the magnetic moment associated with a subset of nuclei (protons, for our purposes) whose cardinality is large enough to justify a classic description of its dynamics (in terms of the expectation value of the quantum magnetic moment operator) and whose spatial extent is small enough to assume a strictly uniform macroscopic magnetic field throughout the subset. The evolution of the isochromats in an MR imaging sequence (radiofrequency [RF] and gradient pulses) is strongly dependent on the flip angles they experience. This shows why accurate R1 and R2 mapping is only possible through 3D sequences, which, unlike 2D sequences, guarantee a roughly uniform RF excitation throughout each voxel.

Estimation of Quantitative Maps.

In general, the viable protocols for R1 and R2 mapping in neuroimaging routine rely on the acquisition of multiple 3D spoiled gradient recalled echo (GRE, for R1) and balanced steady-state free precession (bSSFP, for the additional information required to estimate R2) sequences at variable flip angles.16 However, several aspects need to be considered to obtain accurate relaxation maps. First, nonideal slab profiles can be accounted for with a dedicated sequence for flip angle mapping17 or through an iterative approach based on the information content of the estimated relaxation maps.18 The bias from nonideal RF spoiling can be removed according to the specific phase increment implemented by each vendor.19 Finally, to factor out the effects of off-resonance phenomena impacting the bSSFP images in the form of banding artifacts, one needs to adopt a modified version of the original bSSFP approach,18 based on a synthetic contrast from multiple phase-cycled bSSFP.20

The estimation of the free induction decay rate (R2*) is comparatively simpler because it depends only on the ratios of the signals at different TEs, with no RF pulses in between. It is usually obtained through a multi-GRE sequence with flip angles close to the Ernst angle for SNR convenience and, therefore, can be estimated on the basis of the same protocol structure adopted for R1 mapping.21

Once R1 and R2* (which rule the signal equation of the spoiled GRE sequence) have been obtained, PD is ideally obtained without further acquisitions. Nevertheless, the spatial sensitivity of the receiver coil for the brain is substantially inhomogeneous; therefore, an additional low-resolution acquisition of one of the sequences with the body coil helps to mitigate the inhomogeneity bias.22

Finally, the phase of the complex images acquired for R2* mapping permits QSM.23 The raw phase is first unwrapped and then filtered to remove the background component that is not associated with the local magnetization induced in the parenchyma by the main magnetic field.24 The filtered phase is finally processed to solve the inverse problem leading to the QSM.5 In this step, special care must be taken to avoid the occurrence of streaking artifacts that could impact the clinical value of the image by mimicking spurious anatomic structures (Fig 1).

FIG 1.
FIG 1.

An example of quantitative MR imaging maps. Along with findings of a conventional FLAIR sequence (A) are examples of R1 (B), PD (C), R2* (D), and QSM (E) maps from a 22 -year-old man with MS.

Importance of Denoising Schemes.

The mathematic problems associated with the qMRI protocols are typically ill-conditioned, thus leading to a detrimental noise propagation from the acquired images to the reconstructed maps. Therefore, besides the customary optimization of the acquisition protocol to maximize the SNR of the quantitative maps, a denoising step is warranted upstream of the qMRI pipeline. In this context, multispectral versions of the non-local means algorithms have been devised to account for the power distribution of noise in parallel imaging and to reconstruct the true signal from the raw statistical moments of the acquired images.25,26

Pathophysiologic Correlates of qMRI.

The pathophysiology of brain damage in MS is multifaceted, being characterized by a sequence of demyelination and partial remyelination events associated with neurodegeneration.27

Microglia activation within normal-appearing WM (NAWM) is one of the earliest and most prominent features in MS pathophysiology.28 Subsequently, a loss of integrity of the blood-brain barrier, driven by proinflammatory mediators produced by resident and endothelial cells, as well as indirect leukocyte-dependent damage,27 leads to focal demyelination. As the disease progresses, oligodendrocyte depletion occurs,29 as well as oligodendroglial iron release,30 secondary to the high concentration of proinflammatory cytokines produced by the chronically activated microglia,14 with these mechanisms ultimately resulting in oxidative stress via Fenton chemistry and reduced regenerative capacity.30

Because these different microstructural changes influence multiple MR imaging contrasts contemporarily, multiparameter qMRI represents the most apt approach to explore pathologic alterations occurring in the MS brain. The undeniable advantage of qMRI relies on the possibility of generating spatial maps in which each voxel corresponds to a numeric value reflecting the physical properties of the examined tissues, such as free water proportion (PD, R1, R2), myelination (R1, R2, R2*, QSM), or iron content (R2* and QSM).31,32

While PD is an established measure of the brain free water pool,33 with PD increase documented in the presence of vasogenic edema,34 R1 and R2 vary as a function of free water and myelin concentration, with a higher degree of myelination causing relaxation time shortening.35,36

With reference to iron, in normal brain tissue, it is mostly bound to ferritin in oligodendrocytes,37 and its presence is required for the activity of enzymes involved in myelin production and preservation.15 Along with myelin, iron accounts for the larger part of the MR imaging contrast obtained through R2* and QSM.38 However, whereas both iron and myelin determine an R2* increase, they play opposite roles in QSM. Given the paramagnetic properties of iron, an increase in its concentration is unequivocally coupled to an increase in susceptibility, while myelin, being a diamagnetic compound, influences susceptibility in the opposite direction.38

WM Lesions

Focal WM lesions represent the most typical expression of tissue damage in MS.39 According to their activity phase, WM lesions can be histologically subcategorized as early active, late active, chronic active (also described as slowly expanding or smoldering lesions), chronic inactive, and shadow plaques (remyelinated lesions).40

In early active lesions, inflammatory activity blooms from venules, following blood-brain barrier disruption and immune cell infiltration, thus leading to progressive demyelination and axonal loss with a centrifugal spread.41 From an MR imaging perspective, these phenomena are mirrored by the pattern of enhancement after gadolinium administration. Indeed, at this stage, lesions usually enhance centrifugally, with a more pronounced nodular appearance.42 As inflammation proceeds, cellular infiltrates grow and, combined with myelin breaking down and edema, result in decreased R1 and R2 values, coupled to increased PD values within lesions43 and transitional values in periplaque WM44 in comparison with NAWM. These findings are associated with a similar edema-driven R2* decrease, with no QSM changes because the loss of diamagnetic myelin is not detectable at this stage (Fig 2).45

FIG 2.
FIG 2.

Conventional and quantitative MR imaging findings of WM lesions at different stages. In the upper row, conventional findings (postgadolinium T1-weighted and precontrast T2-weighted, first and second images from left to right respectively) of a typical pattern of nodular enhancement in an early active lesion (arrows) showing isointense signal in QSM (third image, white box) and mild hypointensity in R2* map (fourth image). In late active lesions (middle row, arrows), a peripheral pattern of enhancement is present, coupled with an area of increased signal at QSM and a slightly more pronounced hypointensity on R2* maps compared with the previous stage. As lesion staging further increases, the lesion eventually enters its chronic inactive stage (lower row, arrows), characterized by absent gadolinium enhancement, a QSM hyperintensity, and a hypointense R2* signal. Modified with permission from Zhang et al.45

In late active lesions, showing a peripheral or ringlike pattern of enhancement,42 myelin degradation and removal become progressively more substantial, therefore influencing lesion magnetic susceptibility as assessed by QSM.45,46 At this stage, R1, R2, and PD values show the same pattern of changes as the early active lesions in comparison with NAWM, while in R2*, a further signal decrease is present, coupled to a QSM increase, especially in the lesion center, due to additional myelin debris removal45 by anti-inflammatory M2 macrophages.14 Although iron begins concentrating in M1 macrophages and activated microglia at a later stage,14 its levels may acutely increase following rapid oligodendrocyte destruction, counterbalancing myelin loss in R2* and reinforcing QSM hyperintensity in some lesions (Fig 2).47

When blood-brain barrier damage is resolved, MS lesions no longer show postgadolinium enhancement and are, therefore, categorized as chronic, further subdivided into active or inactive, depending on whether some degree of inflammatory activity persists.40 In chronic lesions, the combination of demyelination, hypocellularity, and free water fraction increase leads to R1 and R2 decrease, while PD increases, compared with early and late active lesions.43 Transition to chronicity is associated with a complex pattern of changes in iron content.38 Indeed, while iron concentration may decrease due to myelin sheaths and oligodendrocyte depletion,29,37 some degree of iron accumulation occurs, in parallel, within iron-laden macrophages and microglia at lesions borders.14,32 In chronic active lesions, this inflammation-related iron accumulation at the rim of the lesions is emphasized, leading to increased R2* and QSM values.45,46 With time, lesions eventually become chronic inactive or shadow plaques,40 with low R2* values but still high QSM signal, which only ultimately decreases in very late stages to resemble NAWM signal, due to iron depletion and partial remyelination (Fig 2).46

NAWM

Despite appearing spared by lesions on conventional MR imaging sequences, NAWM is characterized by complex microstructural changes reflecting inflammation, demyelination, gliosis, and axonal loss.28 The mechanisms underlying NAWM damage are mainly Wallerian degeneration of fibers transected by focal lesions and diffuse microglial activation.28,48 Axonal swelling and edema49 have also been observed globally in NAWM and, together with alteration in iron homeostasis, can be assessed through relaxation and magnetic susceptibility variations.24,38

The NAWM usually shows lower R1 and R2 and higher PD values, compared with the WM of healthy controls.50,51 These changes seem to be mostly related to inflammatory infiltration, with edema and myelin loss.49 A decrease in iron concentration has been observed in patients with MS in comparison with healthy controls using R2* maps.50 This reduced relaxation rate might be driven by iron release from oligodendrocytes during chronic inflammation.14,29 Most interesting, the iron level in NAWM, estimated by QSM, is not stationary but fluctuates according to the presence of inflammatory activity.52 Indeed, during the active phases of the disease, when iron begins to accumulate in newly forming lesions, NAWM magnetic susceptibility values appear to be similar to those observed in the WM of healthy controls,52 as also confirmed by ex vivo data.29 On the contrary, mean QSM values of the NAWM seem to increase in the absence of gadolinium-enhancing lesions, suggesting that iron might play a role in tissue regeneration during periods of disease inactivity.15

Main qMRI findings in the WM compartment are reported in Table 1.

View this table:
Table 1:

Major qMRI findings in MS—WM compartment

Deep Gray Matter

The major structures of the deep gray matter nuclei can be anatomically and functionally subdivided in the thalamus and basal ganglia, whose most relevant nuclei are the globus pallidus, putamen, and caudate nucleus. Given their relatively different histology, the thalamus and basal ganglia will be discussed separately.

Thalamus.

Thalamic involvement in MS has been documented by both ex-53-55 and in vivo53 studies. This region is not only a site of primary axonal damage, but given its high interconnectivity with other brain regions, it suffers from secondary degeneration caused by WM lesions involving thalamic projection fibers.53,54 Recently, a decrease in both thalamic iron content and concentration56-61 has been documented in patients with MS in comparison with healthy controls, with the most evident changes detected within the pulvinar.59,61

Previous studies, however, reported conflicting results,62-66 only partially ascribable to the physiologic nonlinear trajectory followed by thalamic iron concentration during the life span.67 Such conflicting data should be interpreted considering the impact of atrophy on iron concentration.57,68 In particular, the concept of R2* mass (the sum of all the R2* values in a specific region)57 was recently introduced as an index of iron content independent of atrophy. With this approach, the decrease in thalamic iron content has been confirmed,57 highlighting the importance of distinguishing between (and reporting both) iron concentration and content (Fig 3).56,57,59,60

FIG 3.
FIG 3.

Pattern of iron concentration, iron content, and myelin content changes in deep gray matter nuclei in MS. Results of voxelwise analyses comparing patients with MS with healthy controls, showing the presence of an increased iron concentration at the level of the basal ganglia (red-yellow), coupled with a decrease in iron and myelin content mainly affecting the thalami and, in particular, the pulvinar nuclei (blue-light blue). Modified with permission from Pontillo et al.59 HC indicates healthy control; 1-ρ, 1 minus P value.

Basal Ganglia.

The basal ganglia are also the site of both demyelination69 and neurodegeneration, with reduced neuronal density, axonal damage, and oligodendrocytes loss.44,55

Similar to what we described for the thalamus, the progressive damage of the basal ganglia leads to atrophy.69 Here, studies have more consistently reported an increase in R2*58,64-66,70,71 or susceptibility61,64,66,70,72 in patients with MS compared with controls, suggesting a progressive iron accumulation, beyond the analogous physiologic process detectable in healthy individuals.73

Nonetheless, these findings should also be interpreted in view of the effect of atrophy on tissue iron concentration.57 Indeed, even with stable regional iron content, volume reduction leads to increased mean iron concentration.57 In particular, a prominent decline in iron content with time in all basal ganglia has been demonstrated, coupled with an increased or stable iron concentration compared with controls at the level of putamen, caudate nucleus, and globus pallidus.60,72 In line with these results, some recent studies failed to identify any difference between patients with MS and controls in terms of iron content,59 while others reported a decrease of this parameter in the putamen and caudate nucleus of patients with MS (Fig 3).56,57

Cortical Lesions

From a relaxometry perspective, no studies have investigated R1 changes in cortical lesions (CL). However, beyond demyelination, CL are characterized by a decreased iron load, a feature that allows differentiating them from a normal-appearing cortex through the evaluation of R2* maps, as shown in postmortem samples.74,75 In particular, the progressive destruction of iron-rich myelin sheaths and oligodendrocytes76 and the subsequent uptake of iron and myelin debris by activated macrophages and microglia lead to decreased R2* values in CL.77 On the other hand, QSM has been used to analyze the heterogeneity of CL in different disease stages,78 showing a mixed pattern of appearance. While QSM-hyperintense CL have been more frequently observed in patients with relapsing-remitting MS, QSM-hypointense CL are mostly identified in subjects with a secondary-progressive phenotype.78 While the increased susceptibility might be due to iron release from oligodendrocytes, typical of the inflammatory phase of the disease, the reduced susceptibility might be linked to iron depletion in chronic lesions.29

Normal-Appearing Cortex

Similar to the NAWM, the cortex, which does not show signal changes on conventional MR imaging, is subject, from a pathologic standpoint, to neuronal and axonal loss occurring regardless of demyelination.76,79 The assessment of relaxometry and QSM changes in normal-appearing cortex is confounded by the physiologic layer-specific iron content,80 which represents the main source of cortical R2*81 and susceptibility contrast.36 Nevertheless, a decrease in both R1 and R2* values has been reported in MS in normal-appearing cortex, accounting for demyelination and iron depletion, respectively.50 Consistent with the hypothesis of cortical demyelination triggered by chemokines produced by lymphocytic infiltrates in the meningeal compartment,82 a recent study has reported coherent cortical gradients of R1 and R2*, oriented from the subpial layer to the WM interface.83 In the same study, QSM showed a lack of sensitivity in distinguishing the different layers, probably due to the counteracting effects of diamagnetic myelin and paramagnetic iron modifications.83

The main qMRI findings of the GM compartment are reported in Table 2.

View this table:
Table 2:

Major qMRI findings in MS—GM compartment

CONCLUSIONS

In this review, we offered a comprehensive overview of qMRI applications in MS, while also describing the theory behind map generation and the most likely histologic correlates of qMRI findings. The multiparameter nature of qMRI has already allowed researchers to gain additional, valuable insights about the multifaceted pathophysiology of brain damage in MS. Given the increasing accessibility to quantitative sequences on novel MR imaging scanners, in the near future, qMRI will also likely play a fundamental role in clinical practice as a sensitive tool to quantitatively assess brain damage in patients with MS, with relevant implications for prognostic stratification and treatment-response evaluation.

Footnotes

Indicates open access to non-subscribers at www.ajnr.org

References

  1. 1.
    1. Rovira À,
    2. Wattjes MP,
    3. Tintoré M, et al
    ; MAGNIMS Study Group. Evidence-based guidelines: MAGNIMS consensus guidelines on the use of MRI in multiple sclerosis-clinical implementation in the diagnostic process. Nat Rev Neurol 2015;11:47182 doi:10.1038/nrneurol.2015.106 pmid:26149978
  2. 2.
    1. Wattjes MP,
    2. Ciccarelli O,
    3. Reich DS, et al
    ; North American Imaging in Multiple Sclerosis Cooperative MRI Guidelines Working Group. MAGNIMS-CMSC-NAIMS consensus recommendations on the use of MRI in patients with multiple sclerosis. Lancet Neurol 2021;20:65370 doi:10.1016/S1474-4422(21)00095-8 pmid:34139157
  3. 3.
    1. Hagiwara A,
    2. Otsuka Y,
    3. Andica C, et al
    . Differentiation between multiple sclerosis and neuromyelitis optica spectrum disorders by multiparametric quantitative MRI using convolutional neural network. J Clin Neurosci 2021;87:5558 doi:10.1016/j.jocn.2021.02.018 pmid:33863534
  4. 4.
    1. Pudlac A,
    2. Burgetova A,
    3. Dusek P, et al
    . Deep gray matter iron content in neuromyelitis optica and multiple sclerosis. BioMed Res Int 2020;2020:6492786 doi:10.1155/2020/6492786 pmid:32509866
  5. 5.
    1. Deistung A,
    2. Schweser F,
    3. Reichenbach JR
    . Overview of quantitative susceptibility mapping. NMR Biomed 2017;30:e3569 doi:10.1002/nbm.3569 pmid:27434134
  6. 6.
    1. Seiler A,
    2. Nöth U,
    3. Hok P, et al
    . Multiparametric quantitative MRI in neurological diseases. Front Neurol 2021;12:640239 doi:10.3389/fneur.2021.640239 pmid:33763021
  7. 7.
    1. Li J,
    2. Lin H,
    3. Liu T, et al
    . Quantitative susceptibility mapping (QSM) minimizes interference from cellular pathology in R2* estimation of liver iron concentration. J Magn Reson Imaging 2018;48:106979 doi:10.1002/jmri.26019 pmid:29566449
  8. 8.
    1. Banerjee R,
    2. Pavlides M,
    3. Tunnicliffe EM, et al
    . Multiparametric magnetic resonance for the non-invasive diagnosis of liver disease. J Hepatol 2014;60:6977 doi:10.1016/j.jhep.2013.09.002 pmid:24036007
  9. 9.
    1. Straub S,
    2. Laun FB,
    3. Emmerich J, et al
    . Potential of quantitative susceptibility mapping for detection of prostatic calcifications. J Magn Reson Imaging 2017;45:88998 doi:10.1002/jmri.25385 pmid:27418017
  10. 10.
    1. Jerban S,
    2. Lu X,
    3. Jang H, et al
    . Significant correlations between human cortical bone mineral density and quantitative susceptibility mapping (QSM) obtained with 3D cones ultrashort echo time magnetic resonance imaging (UTE-MRI). Magn Reson Imaging 2019;62:10410 doi:10.1016/j.mri.2019.06.016 pmid:31247253
  11. 11.
    1. Karur GR,
    2. Hanneman K
    . Cardiac MRI T1, T2, and T2* mapping in clinical practice. Advances in Clinica Radiology 2019;1:2741 doi:10.1016/j.yacr.2019.03.001
  12. 12.
    1. Granziera C,
    2. Wuerfel J,
    3. Barkhof F, et al
    ; MAGNIMS Study Group. Quantitative magnetic resonance imaging towards clinical application in multiple sclerosis. Brain 2021;144:12961311 doi:10.1093/brain/awab029 pmid:33970206
  13. 13.
    1. Pontillo G,
    2. Cocozza S,
    3. Lanzillo R, et al
    . Determinants of deep gray matter atrophy in multiple sclerosis: a multimodal MRI study. AJNR Am J Neuroradiol 2019;40:99106 doi:10.3174/ajnr.A5915 pmid:30573464
  14. 14.
    1. Mehta V,
    2. Pei W,
    3. Yang G, et al
    . Iron is a sensitive biomarker for inflammation in multiple sclerosis lesions. PLoS One 2013;8:e57573 doi:10.1371/journal.pone.0057573 pmid:23516409
  15. 15.
    1. Möller HE,
    2. Bossoni L,
    3. Connor JR, et al
    . Iron, myelin, and the brain: neuroimaging meets neurobiology. Trends Neurosci 2019;42:384401 doi:10.1016/j.tins.2019.03.009 pmid:31047721
  16. 16.
    1. Deoni SC,
    2. Rutt BK,
    3. Peters TM
    . Rapid combined T1 and T2 mapping using gradient recalled acquisition in the steady state. Magn Reson Med 2003;49:51526 doi:10.1002/mrm.10407 pmid:12594755
  17. 17.
    1. Yarnykh VL
    . Actual flip-angle imaging in the pulsed steady state: a method for rapid three-dimensional mapping of the transmitted radiofrequency field. Magn Reson Med 2007;57:192200 doi:10.1002/mrm.21120 pmid:17191242
  18. 18.
    1. Palma G,
    2. Tedeschi E,
    3. Borrelli P, et al
    . A novel multiparametric approach to 3D quantitative MRI of the brain. PLoS One 2015;10:e0134963 doi:10.1371/journal.pone.0134963 pmid:26284778
  19. 19.
    1. Baudrexel S,
    2. Nöth U,
    3. Schüre JR, et al
    . T1 mapping with the variable flip angle technique: a simple correction for insufficient spoiling of transverse magnetization. Magn Reson Med 2018;79:308292 doi:10.1002/mrm.26979 pmid:29052267
  20. 20.
    1. Björk M,
    2. Ingle RR,
    3. Gudmundson E, et al
    . Parameter estimation approach to banding artifact reduction in balanced steady-state free precession. Magn Reson Med 2014;72:88092 doi:10.1002/mrm.24986 pmid:24166591
  21. 21.
    1. Monti S,
    2. Borrelli P,
    3. Tedeschi E, et al
    . RESUME: turning an SWI acquisition into a fast qMRI protocol. PLoS One 2017;12:e0189933 doi:10.1371/journal.pone.0189933 pmid:29261786
  22. 22.
    1. Monti S,
    2. Pontillo G,
    3. Russo C, et al
    . RESUMEN: a flexible class of multi-parameter qMRI protocols. Phys Med 2021;88:2336 doi:10.1016/j.ejmp.2021.04.005 pmid:34171573
  23. 23.
    1. Li W,
    2. Wang N,
    3. Yu F, et al
    . A method for estimating and removing streaking artifacts in quantitative susceptibility mapping. Neuroimage 2015;108:11122 doi:10.1016/j.neuroimage.2014.12.043 pmid:25536496
  24. 24.
    1. Li W,
    2. Wu B,
    3. Liu C
    . Quantitative susceptibility mapping of human brain reflects spatial variation in tissue composition. Neuroimage 2011;55:164556 doi:10.1016/j.neuroimage.2010.11.088 pmid:21224002
  25. 25.
    1. Aja-Fernández S,
    2. Pieciak T,
    3. Vegas-Sánchez-Ferrero G
    . Spatially variant noise estimation in MRI: a homomorphic approach. Med Image Anal 2015;20:18497 doi:10.1016/j.media.2014.11.005 pmid:25499191
  26. 26.
    1. Borrelli P,
    2. Palma G,
    3. Tedeschi E, et al
    . Improving signal-to-noise ratio in susceptibility weighted imaging: a novel multicomponent non-local approach. PLoS One 2015;10:e0126835 doi:10.1371/journal.pone.0126835 pmid:26030293
  27. 27.
    1. Filippi M,
    2. Bar-Or A,
    3. Piehl F, et al
    . Multiple sclerosis. Nat Rev Dis Primers 2018;4:43 doi:10.1038/s41572-018-0041-4 pmid:30410033
  28. 28.
    1. Allen IV,
    2. McQuaid S,
    3. Mirakhur M, et al
    . Pathological abnormalities in the normal-appearing white matter in multiple sclerosis. Neurolo Sci 2001;22:14144 doi:10.1007/s100720170012 pmid:11603615
  29. 29.
    1. Hametner S,
    2. Wimmer I,
    3. Haider L, et al
    . Iron and neurodegeneration in the multiple sclerosis brain. Ann Neurol 2013;74:84861 doi:10.1002/ana.23974 pmid:23868451
  30. 30.
    1. Stephenson E,
    2. Nathoo N,
    3. Mahjoub Y, et al
    . Iron in multiple sclerosis: roles in neurodegeneration and repair. Nat Rev Neurol 2014;10:45968 doi:10.1038/nrneurol.2014.118 pmid:25002107
  31. 31.
    1. Weiskopf N,
    2. Edwards LJ,
    3. Helms G, et al
    . Quantitative magnetic resonance imaging of brain anatomy and in vivo histology. Nat Rev Phys 2021;3:57088 doi:10.1038/s42254-021-00326-1
  32. 32.
    1. Wisnieff C,
    2. Ramanan S,
    3. Olesik J, et al
    . Quantitative susceptibility mapping (QSM) of white matter multiple sclerosis lesions: Interpreting positive susceptibility and the presence of iron. Magn Reson Med 2015;74:56470 doi:10.1002/mrm.25420 pmid:25137340
  33. 33.
    1. Tofts PS
    1. Tofts PS
    . PD: proton density of tissue water. In: Tofts PS. Quantitative MRI of the Brain: Measuring Changes Caused by Disease. Wiley Online Library; 2003:85109
  34. 34.
    1. Eis M,
    2. Els T,
    3. Hoehn-Berlage M
    . High resolution quantitative relaxation and diffusion MRI of three different experimental brain tumors in rat. Magn Reson Med 1995;34:83544 doi:10.1002/mrm.1910340608 pmid:8598810
  35. 35.
    1. Schmierer K,
    2. Wheeler-Kingshott CA,
    3. Tozer DJ, et al
    . Quantitative magnetic resonance of postmortem multiple sclerosis brain before and after fixation. Magn Reson Med 2008;59:26877 doi:10.1002/mrm.21487 pmid:18228601
  36. 36.
    1. Stüber C,
    2. Morawski M,
    3. Schäfer A, et al
    . Myelin and iron concentration in the human brain: a quantitative study of MRI contrast. Neuroimage 2014;93 Pt 1:95106 doi:10.1016/j.neuroimage.2014.02.026 pmid:24607447
  37. 37.
    1. Bagnato F,
    2. Hametner S,
    3. Yao B, et al
    . Tracking iron in multiple sclerosis: a combined imaging and histopathological study at 7 Tesla. Brain 2011;134:360215 doi:10.1093/brain/awr278 pmid:22171355
  38. 38.
    1. Hametner S,
    2. Endmayr V,
    3. Deistung A, et al
    . The influence of brain iron and myelin on magnetic susceptibility and effective transverse relaxation: a biochemical and histological validation study. Neuroimage 2018;179:11733 doi:10.1016/j.neuroimage.2018.06.007 pmid:29890327
  39. 39.
    1. van der Valk P,
    2. De Groot CJ
    . Staging of multiple sclerosis (MS) lesions: pathology of the time frame of MS. Neuropathol Appl Neurobiol 2000;26:210 doi:10.1046/j.1365-2990.2000.00217.x pmid:10736062
  40. 40.
    1. Frischer JM,
    2. Weigand SD,
    3. Guo Y, et al
    . Clinical and pathological insights into the dynamic nature of the white matter multiple sclerosis plaque. Ann Neurol 2015;78:71021 doi:10.1002/ana.24497 pmid:26239536
  41. 41.
    1. Tallantyre EC,
    2. Brookes MJ,
    3. Dixon JE, et al
    . Demonstrating the perivascular distribution of MS lesions in vivo with 7-Tesla MRI. Neurology 2008;70:207678 doi:10.1212/01.wnl.0000313377.49555.2e pmid:18505982
  42. 42.
    1. Gaitán MI,
    2. Shea CD,
    3. Evangelou IE, et al
    . Evolution of the blood-brain barrier in newly forming multiple sclerosis lesions. Ann Neurol 2011;70:2229 doi:10.1002/ana.22472 pmid:21710622
  43. 43.
    1. Blystad I,
    2. Håkansson I,
    3. Tisell A, et al
    . Quantitative MRI for analysis of active multiple sclerosis lesions without gadolinium-based contrast agent. AJNR Am J Neuroradiol 2016;37:94100 doi:10.3174/ajnr.A4501 pmid:26471751
  44. 44.
    1. Hagiwara A,
    2. Hori M,
    3. Yokoyama K, et al
    . Utility of a multiparametric quantitative MRI model that assesses myelin and edema for evaluating plaques, periplaque white matter, and normal-appearing white matter in patients with multiple sclerosis: a feasibility study. AJNR Am J Neuroradiol 2017;38:23742 doi:10.3174/ajnr.A4977 pmid:27789453
  45. 45.
    1. Zhang Y,
    2. Gauthier SA,
    3. Gupta A, et al
    . Quantitative susceptibility mapping and R2* measured changes during white matter lesion development in multiple sclerosis: myelin breakdown, myelin debris degradation and removal, and iron accumulation. AJNR Am J Neuroradiol 2016;37:162935 doi:10.3174/ajnr.A4825 pmid:27256856
  46. 46.
    1. Chen W,
    2. Gauthier SA,
    3. Gupta A, et al
    . Quantitative susceptibility mapping of multiple sclerosis lesions at various ages. Radiology 2014;271:18392 doi:10.1148/radiol.13130353 pmid:24475808
  47. 47.
    1. Harrison DM,
    2. Li X,
    3. Liu H, et al
    . Lesion heterogeneity on high-field susceptibility MRI is associated with multiple sclerosis severity. AJNR Am J Neuroradiol 2016;37:144753 doi:10.3174/ajnr.A4726 pmid:26939635
  48. 48.
    1. Dziedzic T,
    2. Metz I,
    3. Dallenga T, et al
    . Wallerian degeneration: a major component of early axonal pathology in multiple sclerosis. Brain Pathol 2010;20:97685 doi:10.1111/j.1750-3639.2010.00401.x pmid:20477831
  49. 49.
    1. Filippi M,
    2. Rocca MA,
    3. Barkhof F, et al
    ; Attendees of the Correlation between Pathological MRI Findings in MS Workshop. Association between pathological and MRI findings in multiple sclerosis. Lancet Neurol 2012;11:34960 doi:10.1016/S1474-4422(12)70003-0 pmid:22441196
  50. 50.
    1. Lommers E,
    2. Simon J,
    3. Reuter G, et al
    . Multiparameter MRI quantification of microstructural tissue alterations in multiple sclerosis. Neuroimage Clin 2019;23:101879 doi:10.1016/j.nicl.2019.101879 pmid:31176293
  51. 51.
    1. West J,
    2. Aalto A,
    3. Tisell A, et al
    . Normal-appearing and diffusely abnormal white matter in patients with multiple sclerosis assessed with quantitative MR. PLoS One 2014;9:e95161 doi:10.1371/journal.pone.0095161 pmid:24747946
  52. 52.
    1. Chen W,
    2. Zhang Y,
    3. Mu K, et al
    . Quantifying the susceptibility variation of normal-appearing white matter in multiple sclerosis by quantitative susceptibility mapping. AJR Am J Roentgenol 2017;209:88994 doi:10.2214/AJR.16.16851 pmid:28705068
  53. 53.
    1. Cifelli A,
    2. Arridge M,
    3. Jezzard P, et al
    . Thalamic neurodegeneration in multiple sclerosis. Ann Neurol 2002;52:65053 doi:10.1002/ana.10326 pmid:12402265
  54. 54.
    1. Mahajan KR,
    2. Nakamura K,
    3. Cohen JA, et al
    . Intrinsic and extrinsic mechanisms of thalamic pathology in multiple sclerosis. Ann Neurol 2020;88:8192 doi:10.1002/ana.25743 pmid:32286701
  55. 55.
    1. Vercellino M,
    2. Masera S,
    3. Lorenzatti M, et al
    . Demyelination, inflammation, and neurodegeneration in multiple sclerosis deep gray matter. J Neuropathol Exp Neurol 2009;68:489502 doi:10.1097/NEN.0b013e3181a19a5a pmid:19525897
  56. 56.
    1. Elkady AM,
    2. Cobzas D,
    3. Sun H, et al
    . Five year iron changes in relapsing-remitting multiple sclerosis deep gray matter compared to healthy controls. Mult Scler Relat Disord 2019;33:10715 doi:10.1016/j.msard.2019.05.028 pmid:31181540
  57. 57.
    1. Hernández-Torres E,
    2. Wiggermann V,
    3. Machan L, et al
    . Increased mean R2* in the deep gray matter of multiple sclerosis patients: have we been measuring atrophy? J Magn Reson Imaging 2019;50:20108 doi:10.1002/jmri.26561 pmid:30511803
  58. 58.
    1. Khalil M,
    2. Langkammer C,
    3. Pichler A, et al
    . Dynamics of brain iron levels in multiple sclerosis: a longitudinal 3T MRI study. Neurology 2015;84:23962402 doi:10.1212/WNL.0000000000001679 pmid:25979698
  59. 59.
    1. Pontillo G,
    2. Petracca M,
    3. Monti S, et al
    . Unraveling deep gray matter atrophy and iron and myelin changes in multiple sclerosis. AJNR Am J Neuroradiol 2021;42:122330 doi:10.3174/ajnr.A7093 pmid:33888456
  60. 60.
    1. Schweser F,
    2. Hagemeier J,
    3. Dwyer MG, et al
    . Decreasing brain iron in multiple sclerosis: the difference between concentration and content in iron MRI. Hum Brain Mapp 2021;42:146374 doi:10.1002/hbm.25306 pmid:33378095
  61. 61.
    1. Zivadinov R,
    2. Tavazzi E,
    3. Bergsland N, et al
    . Brain iron at quantitative MRI is associated with disability in multiple sclerosis. Radiology 2018;289:48796 doi:10.1148/radiol.2018180136 pmid:30015589
  62. 62.
    1. Cobzas D,
    2. Sun H,
    3. Walsh AJ, et al
    . Subcortical gray matter segmentation and voxel-based analysis using transverse relaxation and quantitative susceptibility mapping with application to multiple sclerosis. J Magn Reson Imaging 2015;42:160110 doi:10.1002/jmri.24951 pmid:27418017
  63. 63.
    1. Lebel RM,
    2. Eissa A,
    3. Seres P, et al
    . Quantitative high-field imaging of sub-cortical gray matter in multiple sclerosis. Mult Scler 2012;18:43341 doi:10.1177/1352458511428464 pmid:22032862
  64. 64.
    1. Rudko DA,
    2. Solovey I,
    3. Gati JS, et al
    . Multiple sclerosis: improved identification of disease-relevant changes in gray and white matter by using susceptibility-based MR imaging. Radiology 2014;272:85164 doi:10.1148/radiol.14132475 pmid:24828000
  65. 65.
    1. Walsh AJ,
    2. Blevins G,
    3. Lebel RM, et al
    . Longitudinal MR imaging of iron in multiple sclerosis: an imaging marker of disease. Radiology 2014;270:18696 doi:10.1148/radiol.13130474 pmid:23925273
  66. 66.
    1. Fujiwara E,
    2. Kmech JA,
    3. Cobzas D, et al
    . Cognitive implications of deep gray matter iron in multiple sclerosis. AJNR Am J Neuroradiol 2017;38:94248 doi:10.3174/ajnr.A5109 pmid:28232497
  67. 67.
    1. Hallgren B,
    2. Sourander P
    . The effect of age on the non-haemin iron in the human brain. Neurochem 1958;3:4151 doi:10.1111/j.1471-4159.1958.tb12607.x pmid:13611557
  68. 68.
    1. Eshaghi A,
    2. Marinescu RV,
    3. Young AL, et al
    . Progression of regional grey matter atrophy in multiple sclerosis. Brain 2018;141:166577 doi:10.1093/brain/awy088 pmid:29741648
  69. 69.
    1. Haider L,
    2. Simeonidou C,
    3. Steinberger G, et al
    . Multiple sclerosis deep grey matter: the relation between demyelination, neurodegeneration, inflammation and iron. J Neurol Neurosurg Psychiatry 2014;85:138695 doi:10.1136/jnnp-2014-307712 pmid:24899728
  70. 70.
    1. Elkady AM,
    2. Cobzas D,
    3. Sun H, et al
    . Progressive iron accumulation across multiple sclerosis phenotypes revealed by sparse classification of deep gray matter. J Magn Reson Imaging 2017;46:146473 doi:10.1002/jmri.25682 pmid:28301067
  71. 71.
    1. Ropele S,
    2. Kilsdonk ID,
    3. Wattjes MP, et al
    . Determinants of iron accumulation in deep grey matter of multiple sclerosis patients. Mult Scler 2014;20:169298 doi:10.1177/1352458514531085 pmid:24787429
  72. 72.
    1. Hagemeier J,
    2. Zivadinov R,
    3. Dwyer MG, et al
    . Changes of deep gray matter magnetic susceptibility over 2 years in multiple sclerosis and healthy control brain. Neuroimage Clin 2018;18:100716 doi:10.1016/j.nicl.2017.04.008 pmid:29868452
  73. 73.
    1. Haacke EM,
    2. Cheng NY,
    3. House MJ, et al
    . Imaging iron stores in the brain using magnetic resonance imaging. Magn Reson Imaging 2005;23:125 doi:10.1016/j.mri.2004.10.001 pmid:15733784
  74. 74.
    1. Jonkman LE,
    2. Fleysher L,
    3. Steenwijk MD, et al
    . Ultra-high field MTR and qR2* differentiates subpial cortical lesions from normal-appearing gray matter in multiple sclerosis. Mult Scler 2016;22:130614 doi:10.1177/1352458515620499 pmid:26672996
  75. 75.
    1. Yao B,
    2. Hametner S,
    3. van Gelderen P, et al
    . 7 Tesla magnetic resonance imaging to detect cortical pathology in multiple sclerosis. PLoS One 2014;9:e108863 doi:10.1371/journal.pone.0108863 pmid:25303286
  76. 76.
    1. Peterson JW,
    2. L,
    3. Mörk S, et al
    . Transected neurites, apoptotic neurons, and reduced inflammation in cortical multiple sclerosis lesions. Ann Neurol 2001;50:389400 doi:10.1002/ana.1123 pmid:11558796
  77. 77.
    1. Fischer MT,
    2. Wimmer I,
    3. Höftberger R, et al
    . Disease-specific molecular events in cortical multiple sclerosis lesions. Brain 2013;136:17991815 doi:10.1093/brain/awt110 pmid:23687122
  78. 78.
    1. Castellaro M,
    2. Magliozzi R,
    3. Palombit A, et al
    . Heterogeneity of cortical lesion susceptibility mapping in multiple sclerosis. AJNR Am J Neuroradiol 2017;38:108795 doi:10.3174/ajnr.A5150 pmid:28408633
  79. 79.
    1. Magliozzi R,
    2. Howell OW,
    3. Reeves C, et al
    . A Gradient of neuronal loss and meningeal inflammation in multiple sclerosis. Ann Neurol 2010;68:47793 doi:10.1002/ana.22230 pmid:20976767
  80. 80.
    1. Fukunaga M,
    2. Li TQ,
    3. van Gelderen P, et al
    . Layer-specific variation of iron content in cerebral cortex as a source of MRI contrast. Proc Natl Acad Sci U S A 2010;107:383439 doi:10.1073/pnas.0911177107 pmid:20133720
  81. 81.
    1. Bagnato F,
    2. Hametner S,
    3. Boyd E, et al
    . Untangling the R2* contrast in multiple sclerosis: a combined MRI-histology study at 7.0 Tesla. PLoS One 2018;13:e0193839 doi:10.1371/journal.pone.0193839 pmid:29561895
  82. 82.
    1. Magliozzi R,
    2. Reynolds R,
    3. Calabrese M
    . MRI of cortical lesions and its use in studying their role in MS pathogenesis and disease course. Brain Pathol 2018;28:73542 doi:10.1111/bpa.12642 pmid:30020563
  83. 83.
    1. Lema Dopico A,
    2. Choi S,
    3. Hua J, et al
    . Multi-layer analysis of quantitative 7 T magnetic resonance imaging in the cortex of multiple sclerosis patients reveals pathology associated with disability. Mult Scler 2021;27:204051 doi:10.1177/1352458521994556 pmid:33596719
  • Received January 12, 2022.
  • Accepted after revision February 22, 2022.
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