Viscoelastic Profiling of Rare Pediatric Extracranial Tumors using Multifrequency MR Elastography: A Pilot Study
Abstract
Objectives: Magnetic resonance elastography (MRE) is a noninvasive technique for assessing the viscoelastic properties of soft biological tissues in vivo, with potential relevance for pediatric tumor evaluation. This study aimed to evaluate the feasibility of multifrequency MRE in children with solid tumors and to report initial findings on stiffness and fluidity across rare pediatric tumor entities. Additionally, the potential of viscoelastic properties as biomarkers of tumor malignancy was explored. Materials and Methods: Ten pediatric patients (mean age, 5.7 +/- 4.8 years; four female) with extracranial solid tumors underwent multifrequency MRE. Shear waves at 30 - 70 Hz were subsequently generated and measured with a phase-sensitive single-shot spin-echo planar imaging sequence. The obtained shear wave fields were processed by wavenumber (k-)based multi-frequency inversion to reconstruct tumor stiffness and fluidity. The viscoelastic properties within the tumors were quantified and correlated with the apparent diffusion coefficient (ADC). In addition, differences in stiffness and fluidity were assessed across the histopathologically confirmed tumor entities, which were stratified into malignancy-based groups. Results: MRE was successfully performed in all patients in under five minutes. Differences in viscoelastic properties were observed among tumor entities: Stiffness, fluidity, and their spatial variability increased significantly with tumor malignancy. Furthermore, a significant inverse correlation was observed between stiffness and tumor ADC values. Conclusion: Multifrequency MRE was feasible in pediatric MRI and provided insight into tumor biomechanics. Preliminary data revealed differences in stiffness and fluidity across pediatric solid tumors correlating with malignancy. MRE holds promise for diagnosis and classification of pediatric tumor entities and their malignancy.