Nucleus pulposus structure and function assessed in shear using magnetic resonance elastography, quantitative MRI, and rheometry

Megan Co; Brian Raterman; Brett Klamer; Arunark Kolipaka; Benjamin Walter

doi:10.1002/jsp2.1335

Nucleus pulposus structure and function assessed in shear using magnetic resonance elastography, quantitative MRI, and rheometry

JOR Spine. 2024 May 13;7(2):e1335. doi: 10.1002/jsp2.1335. eCollection 2024 Jun.

Authors

Megan Co¹, Brian Raterman², Brett Klamer³, Arunark Kolipaka², Benjamin Walter^{1

4}

Affiliations

¹ Department of Biomedical Engineering The Ohio State University Columbus Ohio USA.
² Department of Radiology The Ohio State University Wexner Medical Center Columbus Ohio USA.
³ Department of Biomedical Informatics, Center for Biostatistics The Ohio State University Columbus Ohio USA.
⁴ Department of Orthopaedics The Ohio State University Wexner Medical Center Columbus Ohio USA.

Abstract

Background: In vivo quantification of the structure-function relationship of the intervertebral disc (IVD) via quantitative MRI has the potential to aid objective stratification of disease and evaluation of restorative therapies. Magnetic resonance elastography (MRE) is an imaging technique that assesses tissue shear properties and combined with quantitative MRI metrics reflective of composition can inform structure-function of the IVD. The objectives of this study were to (1) compare MRE- and rheometry-derived shear modulus in agarose gels and nucleus pulposus (NP) tissue and (2) correlate MRE and rheological measures of NP tissue with composition and quantitative MRI.

Method: MRE and MRI assessment (i.e., T1ρ and T2 mapping) of agarose samples (2%, 3%, and 4% (w/v); n = 3-4/%) and of bovine caudal IVDs after equilibrium dialysis in 5% or 25% PEG (n = 13/PEG%) was conducted. Subsequently, agarose and NP tissue underwent torsional mechanical testing consisting of a frequency sweep from 1 to 100 Hz at a rotational strain of 0.05%. NP tissue was additionally evaluated under creep and stress relaxation conditions. Linear mixed-effects models and univariate regression analyses evaluated the effects of testing method, %agarose or %PEG, and frequency, as well as correlations between parameters.

Results: MRE- and rheometry-derived shear moduli were greater at 100 Hz than at 80 Hz in all agarose and NP tissue samples. Additionally, all samples with lower water content had higher complex shear moduli. There was a significant correlation between MRE- and rheometry-derived modulus values for homogenous agarose samples. T1ρ and T2 relaxation times for agarose and tissue were negatively correlated with complex shear modulus derived from both techniques. For NP tissue, shear modulus was positively correlated with GAG/wet-weight and negatively correlated with %water content.

Conclusion: This work demonstrates that MRE can assess hydration-induced changes in IVD shear properties and further highlights the structure-function relationship between composition and shear mechanical behaviors of NP tissue.

Keywords: intervertebral disc; magnetic resonance elastography; shear properties.