A multi‐compartmental SE‐BOLD interpretation for stimulus‐related signal changes in diffusion‐weighted functional MRI

Kershaw, Jeff; Tomiyasu, Moyoko; Kashikura, Kenichi; Hirano, Yoshiyuki; Nonaka, Hiroi; Hirano, Minoru; Ikehira, Hiroo; Kanno, Iwao; Obata, Takayuki

doi:10.1002/nbm.1391

Cited by 14 publications

(18 citation statements)

References 41 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For instance, a study showed decreased apparent diffusion coefficient, implying increased normalized signal intensity for about 1.57% with b-value of 1443-1461 mm 2 /s and this result was consistent with our result that the normalized signal intensities increased for about 2.17% with b-value of 1400 mm 2 /s, Δ of 30 ms, and r of 10.1 μm [1]. In other studies, 1-2% increases of the raw signal intensities with the b-value of 1600-1800 mm 2 /s were reported [2], [3], [5]. In our simulations, we obtained 2.15-2.18% increases in the normalized signal intensities with the b-value of 1600-1800 mm 2 /s, Δ of 30 ms, and r of 10.1 μm.…”

Section: Discussionsupporting

confidence: 93%

An Explanation of Signal Changes in DW-fMRI: Monte Carlo Simulation Study of Restricted Diffusion of Water Molecules Using 3D and Two-Compartment Cortical Cell Models

Nagahara

Oida

Kobayashi

2013

IEICE Trans. Inf. & Syst.

View full text Add to dashboard Cite

SUMMARYDiffusion-weighted (DW)-functional magnetic resonance imaging (fMRI) is a recently reported technique for measuring neural activities by using diffusion-weighted imaging (DWI). DW-fMRI is based on the property that cortical cells swell when the brain is activated. This approach can be used to observe changes in water diffusion around cortical cells. The spatial and temporal resolutions of DW-fMRI are superior to those of blood-oxygenation-level-dependent (BOLD)-fMRI. To investigate how the DWI signal intensities change in DW-fMRI measurement, we carried out Monte Carlo simulations to evaluate the intensities before and after cell swelling. In the simulations, we modeled cortical cells as two compartments by considering differences between the intracellular and the extracellular regions. Simulation results suggested that DWI signal intensities increase after cell swelling because of an increase in the intracellular volume ratio. The simulation model with two compartments, which respectively represent the intracellular and the extracellular regions, shows that the differences in the DWI signal intensities depend on the ratio of the intracellular and the extracellular volumes. We also investigated the MPG parameters, b-value, and separation time dependences on the percent signal changes in DW-fMRI and obtained useful results for DW-fMRI measurements.

show abstract

Section: Discussionsupporting

confidence: 93%

An Explanation of Signal Changes in DW-fMRI: Monte Carlo Simulation Study of Restricted Diffusion of Water Molecules Using 3D and Two-Compartment Cortical Cell Models

Nagahara

Oida

Kobayashi

2013

IEICE Trans. Inf. & Syst.

View full text Add to dashboard Cite

show abstract

“…During activation, they hypothesize that the compartment with slower diffusion increases (because of cell swelling), causing the overall diffusion to decrease and the signal to therefore increase. However, a similar effect could arise for compartments with fixed volume (no swelling) that had different diffusion coefficients and T 2 values (40). As the b value changes, the signal contribution of the T 2 BOLD effect in each compartment would be determined by its diffusion coefficient, and the percent signal change would therefore depend on b value.…”

Section: Discussionmentioning

confidence: 94%

Evidence for a vascular contribution to diffusion FMRI at high b value

Miller

Bulte

Devlin

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

Recent work has suggested that diffusion-weighted functional magnetic resonance imaging (FMRI) with strong diffusion weighting (high b value) detects neuronal swelling that is directly related to neuronal firing. This would constitute a much more direct measure of brain activity than current methods and represent a major advance in neuroimaging. However, it has not been firmly established that the observed signal changes do not reflect residual vascular effects, which are known to exist at low b value. This study measures the vascular component of diffusion FMRI directly by using hypercapnia, which induces blood flow changes in the absence of a change in neuronal firing. Hypercapnia elicits a similar diffusion FMRI response to a visual stimulus including a rise in percent signal change with increasing b value, which was reported for visual activation. Analysis of the response timing found no evidence for an early response at high b value, which has been reported as evidence for a nonhemodynamic response. These results suggest that a large component of the diffusion FMRI signal at high b value is vascular rather than neuronal.brain activation ͉ diffusion MRI ͉ functional MRI ͉ neuronal swelling F unctional neuroimaging has enabled major advances in the study of normal and pathological brain function. However, the methods that provide the greatest coverage and spatial resolution, including positron emission tomography (1, 2) and magnetic resonance imaging (MRI) (3, 4), are indirect measures of neuronal activity based on metabolically driven changes in blood flow. These hemodynamic measures suffer from spatial and temporal confounds (5, 6), are nonlinearly related to neuronal firing (7,8), and depend on baseline hemodynamics that are uncoupled from the activity of interest (9, 10). An imaging method that detects neuronal activity more directly while achieving whole-brain coverage would therefore represent a significant advance for neuroscience.One alternative method is diffusion-weighted functional MRI (DFMRI), which attenuates the MRI signal in a manner that depends on the amount of motion (diffusion and flow) in the underlying tissue. In general, this attenuation is described by a factor exp(ϪbD), where D is the apparent diffusion coefficient of the local tissue, and b is an acquisition parameter that describes the strength of diffusion contrast. At low b value, true diffusive motion is more difficult to detect, and the ''apparent diffusion'' is dominated by local blood flow (11)(12)(13)(14). In general, diffusion weighting is directional, so that attenuation depends on the diffusion and flow parameters along the applied direction. Different signal sources have been proposed in DFMRI depending on the b value. Early work used low b value, which is thought to reflect tissue perfusion (11-16). Recent work suggested that DFMRI at high b value detects cellular swelling that is a direct consequence of neural firing (17, 18), which would constitute a more direct measure of neuronal activity.A recent study at high b valu...

show abstract

“…Also, our model simplifies the diffusion properties of water in brain matter, which cannot be described assuming isotropic diffusion characterized by a single diffusion coefficient (40). In a very recent study, Kershaw et al (11) explained their findings in DFMRI experiments by means of a model that considers a slow-and a fast-diffusing pool, indicating that the diffusion characteristics could be crucial to explain DFRMI findings.…”

Section: Discussionmentioning

confidence: 95%

“…Thus, one can safely assume that it is exclusively caused by the interaction between diffusion weighting gradients and background gradients. In the study by Fujita (41), a scaling law, b ¼ DÁTE/r 2 , was derived that allows a set of results calculated for a specific diffusion constant (D) and vessel radius (r) to be applied to a situation with the same b but different D and r. Noting that the largest extravascular SE-BOLD signal changes occur when b lies between 2 and 4, it is possible to estimate the range of vessel sizes that are most sensitive for molecules diffusing with a specific diffusion coefficient (11). Our results suggest that this range also depends on the size of the bvalue if a sequence is chosen that does not minimize cross-terms.…”

Section: Discussionmentioning

confidence: 99%

“…At the cortical surface, a small decrease in the ADC was found (10), which may also have arisen from a functional reduction in the partial volume of the cerebrospinal fluid. In a very recent contribution, Kershaw et al (11) have proposed that the observation of an overall decrease in diffusion can be explained by decomposing the signal in fractions from slow-and fast-diffusing molecules with distinct BOLD signal characteristics. The interpretation and the observability of the diffusion changes during activation as observed using FMRI is still a matter of debate.…”

Section: Introductionmentioning

confidence: 98%

See 1 more Smart Citation

BOLD background gradient contributions in diffusion‐weighted fMRI—comparison of spin‐echo and twice‐refocused spin‐echo sequences

2010

View full text Add to dashboard Cite

The interaction ('cross terms') between diffusion-weighting gradients and susceptibility-induced background gradient fields around vessels has an impact on apparent diffusion coefficient (ADC) measurements and diffusion-weighted functional magnetic resonance imaging (DFMRI) experiments. Monte-Carlo (MC) simulations numerically integrating the Bloch equations for a large number of random walks in a vascular model were used to investigate to what extent such interactions would influence the extravascular signal change as well as the ADC change observed in DFMRI experiments. The vascular model consists of a set of independent, randomly oriented, infinite cylinders whose internal magnetic susceptibility varies as the state changes between rest and activation. In such a network, the cross terms result in the observation of a functional increase in ADC accompanied by a descending percent signal change with increasing diffusion weighting. It is shown that the twice-refocused spin-echo sequence permits sufficient yet not total suppression of such effects compared to the standard Stejskal-Tanner spin-echo diffusion weighting under experimentally relevant conditions.

show abstract

A multi‐compartmental SE‐BOLD interpretation for stimulus‐related signal changes in diffusion‐weighted functional MRI

Cited by 14 publications

References 41 publications

An Explanation of Signal Changes in DW-fMRI: Monte Carlo Simulation Study of Restricted Diffusion of Water Molecules Using 3D and Two-Compartment Cortical Cell Models

An Explanation of Signal Changes in DW-fMRI: Monte Carlo Simulation Study of Restricted Diffusion of Water Molecules Using 3D and Two-Compartment Cortical Cell Models

Evidence for a vascular contribution to diffusion FMRI at high b value

BOLD background gradient contributions in diffusion‐weighted fMRI—comparison of spin‐echo and twice‐refocused spin‐echo sequences

Contact Info

Product

Resources

About