Multiparametric MRI characterization of level dependent differences in lumbar muscle size, quality, and microstructure

Berry, David B.; Rodríguez‐Soto, Ana E.; Englund, Erin K; Shahidi, Bahar; Parra, Callan L.; Frank, Lawrence R.; Kelly, Karen R.; Ward, Samuel R.

doi:10.1002/jsp2.1079

Cited by 7 publications

(4 citation statements)

References 51 publications

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“…Our results here and in a previous, independent study (41) suggest that diffusion characteristics differ in the paraspinal muscles as a function of spinal segment. The observation of changing mean diffusivity over the span of the lumbar spine may draw into question the assumption of spatial uniformity, however we note that spatial consistency was assumed within one spinal segment, not across the entire spine.…”

Section: Discussionsupporting

confidence: 80%

“…The observation of changing mean diffusivity over the span of the lumbar spine may draw into question the assumption of spatial uniformity, however we note that spatial consistency was assumed within one spinal segment, not across the entire spine. Indeed, differences in IVIM parameters across the spinal segments are likely to reflect differences in structure and physiology of the paraspinal muscles from cranial to caudal, including differences in size (including the relative contribution of erector spinae vs. multifidus), tissue composition, and metabolic capacity (41)(42)(43). We also note that the IVIM parameters were generally more variable at L1 and L5, potentially due to respiratory motion at the superior extent and coil sensitivity at the inferior extent.…”

Section: Discussionmentioning

confidence: 84%

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Assessment of fitting methods and variability of IVIM parameters in muscles of the lumbar spine at rest

Englund,

Berry,

Behun

et al. 2024

Front. Musculoskelet. Disord.

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Intravoxel incoherent motion (IVIM) MRI provides insight into tissue diffusion and perfusion. Here, estimates of perfusion fraction (f), pseudo-diffusion coefficient (D*), and diffusion coefficient (D) obtained via different fitting methods are compared to ascertain (1) the optimal analysis strategy for muscles of the lumbar spine and (2) repeatability of IVIM parameters in skeletal muscle at rest. Diffusion-weighted images were acquired in the lumbar spine at rest in 15 healthy participants. Data were fit to the bi-exponential IVIM model to estimate f, D* and D using three variably segmented approaches based on non-linear least squares fitting, and a Bayesian fitting method. Assuming that perfusion and diffusion are temporally stable in skeletal muscle at rest, and spatially uniform within a spinal segment, the optimal analysis strategy was determined as the approach with the lowest temporal or spatial variation and smallest residual between measured and fit data. Inter-session repeatability of IVIM parameters was evaluated in a subset of 11 people. Finally, simulated IVIM signal at varying signal to noise ratio were evaluated to understand precision and bias. Experimental results showed that IVIM parameter values differed depending on the fitting method. A three-step non-linear least squares fitting approach, where D, f, and D* were estimated sequentially, generally yielded the lowest spatial and temporal variation. Solving all parameters simultaneously yielded the lowest residual between measured and fit data, however there was substantial spatial and temporal variability. Results obtained by Bayesian fitting had high spatial and temporal variability in addition to a large residual between measured and fit data. Simulations showed that all fitting methods can fit the IVIM data at signal to noise ratios >35, and that D* was the most challenging to accurately obtain. Overall, this study motivates use of a three-step non-linear least squares fitting strategy to quantify IVIM parameters in skeletal muscle.

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Section: Discussionsupporting

confidence: 80%

Section: Discussionmentioning

confidence: 84%

Assessment of fitting methods and variability of IVIM parameters in muscles of the lumbar spine at rest

Englund,

Berry,

Behun

et al. 2024

Front. Musculoskelet. Disord.

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“…It has been suggested that multifidus was the primary stabilizer of the lumbar spine whereas the erector spinae helped to stabilize the lumbar spine and conveyed motion of the trunk. 57 A recent study also showed that obese patients had fatty paraspinal muscles at the upper lumbar levels and IVDD/Modic changes at the lower lumbar levels. 58 In this study, we observed that patients with LBP had more fatty infiltration in their erector spinae at L2-L3 and L3-L4 levels concomitant with milder fatty infiltration in the multifidus at the corresponding levels and spinal degeneration (severe IVDD and Modic changes) at the lower lumbar levels.…”

Section: Discussionmentioning

confidence: 95%

Section: Discussionmentioning

confidence: 99%

Fatty infiltration of the erector spinae at the upper lumbar spine could be a landmark for low back pain

Ekşi,

Özcan‐Ekşi

2023

Pain Practice

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PurposeIntervertebral disc degeneration (IVDD), Modic changes, and fatty infiltration in the paraspinal muscles are possible causes of low back pain (LBP). Multifidus has been the most commonly blamed paraspinal muscle in the etiology of LBP. However, it contributes to 20% of the extensor moment on the lumbar spine. In the present study, we aimed to identify whether patients with LBP and asymptomatic subjects differed in terms of intervertebral discs, end‐plates, and fatty infiltration in their paraspinal muscles.MethodsConsecutive women and men, who visited the spine outpatient clinics with chronic LBP and had lumbar spine MRI for their LBP without leg pain were included. Asymptomatic subjects without LBP/leg pain for the last year were recruited. Modic changes, IVDD, and fatty infiltration in the paraspinal muscles were evaluated on lumbar spine magnetic resonance imagings of the patients with LBP and age‐, gender‐ and BMI‐matched asymptomatic controls.ResultsLow back pain was closely associated with fatty infiltration in the paraspinal muscles at all lumbar levels whereas it had association with severe IVDD and Modic changes at lower lumbar levels. Multifidus at the lower lumbar levels was the fattiest paraspinal muscle in both asymptomatic subjects and patients with LBP. Patients with LBP had severe fatty infiltration in the erector spinae at the upper lumbar levels.ConclusionSevere IVDD and Modic changes were more common at lower lumbar levels in patients with LBP. Both asymptomatic subjects and those with LBP had fatty multifidus at lower lumbar levels, whereas those with LBP had fatty infiltration in the erector spinae at upper lumbar levels. We suggest that fatty infiltration could have started in the multifidus. The erector spinae had greater contribution to the lumbar extension compared to the multifidus. Thus, LBP could develop when the quality of the erector spinae at the upper lumbar levels impairs due to fatty infiltration.

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From Voxels to Physiology: A Review of Diffusion Magnetic Resonance Imaging Applications in Skeletal Muscle

Berry,

Gordon,

Adair

et al. 2024

Magnetic Resonance Imaging

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Skeletal muscle has a classic structure function relationship; both skeletal muscle microstructure and architecture are directly related to force generating capacity. Biopsy, the gold standard for evaluating muscle microstructure, is highly invasive, destructive to muscle, and provides only a small amount of information about the entire volume of a muscle. Similarly, muscle fiber lengths and pennation angles, key features of muscle architecture predictive of muscle function, are traditionally studied via cadaveric dissection. Noninvasive techniques such as diffusion magnetic resonance imaging (dMRI) offer quantitative approaches to study skeletal muscle microstructure and architecture. Despite its prevalence in applications for musculoskeletal research, clinical adoption is hindered by a lack of understanding regarding its sensitivity to clinically important biomarkers such as muscle fiber cross‐sectional area. This review aims to elucidate how dMRI has been utilized to study skeletal muscle, covering fundamentals of muscle physiology, dMRI acquisition techniques, dMRI modeling, and applications where dMRI has been leveraged to noninvasively study skeletal muscle changes in response to disease, aging, injury, and human performance.Level of Evidence5Technical EfficacyStage 2

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Multiparametric MRI characterization of level dependent differences in lumbar muscle size, quality, and microstructure

Cited by 7 publications

References 51 publications

Assessment of fitting methods and variability of IVIM parameters in muscles of the lumbar spine at rest

Assessment of fitting methods and variability of IVIM parameters in muscles of the lumbar spine at rest

Fatty infiltration of the erector spinae at the upper lumbar spine could be a landmark for low back pain

From Voxels to Physiology: A Review of Diffusion Magnetic Resonance Imaging Applications in Skeletal Muscle

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