Assessment of intravoxel incoherent motion MRI with an artificial capillary network: analysis of biexponential and phase-distribution models

Moritz Jörg Schneider; Thomas Gaass; Jens Ricke; Julien Dinkel; Olaf Dietrich

doi:10.1002/mrm.27816

Assessment of intravoxel incoherent motion MRI with an artificial capillary network: analysis of biexponential and phase-distribution models

Magn Reson Med. 2019 Oct;82(4):1373-1384. doi: 10.1002/mrm.27816. Epub 2019 May 26.

Authors

Moritz Jörg Schneider^{1

2}, Thomas Gaass¹, Jens Ricke¹, Julien Dinkel^{1

2}, Olaf Dietrich¹

Affiliations

¹ Department of Radiology, University Hospital, LMU Munich, Munich, Germany.
² Comprehensive Pneumology Center, German Center for Lung Research, Munich, Germany.

Abstract

Purpose: To systematically analyze intravoxel incoherent motion (IVIM) MRI in a perfusable capillary phantom closely matching the geometry of capillary beds in vivo and to compare the validity of the biexponential pseudo-diffusion and the recently introduced phase-distribution IVIM model.

Methods: IVIM-MRI was performed at 12 different flow rates ( $0.2 \dots 2.4 m L / \min$ ) in a capillary phantom using 4 different DW-MRI sequences (2 with monopolar and 2 with flow-compensated diffusion-gradient schemes, with up to $16$ $b$ values between $0$ and $800 s / {mm}^{2}$ ). Resulting parameters from the assessed IVIM models were compared to results from optical microscopy.

Results: The acquired data were best described by a static and a flowing compartment modeled by the phase-distribution approach. The estimated signal fraction $f$ of the flowing compartment stayed approximately constant over the applied flow rates, with an average of $f = 0.451 \pm 0.023$ in excellent agreement with optical microscopy ( $f = 0.454 \pm 0.002$ ). The estimated average particle flow speeds $v = 0.25 \dots 2.7 mm / s$ showed a highly significant linear correlation to the applied flow. The estimated capillary segment length of approximately $189 u m$ agreed well with optical microscopy measurements. Using the biexponential model, the signal fraction $f$ was substantially underestimated and displayed a strong dependence on the applied flow rate.

Conclusion: The constructed phantom facilitated the detailed investigation of IVIM-MRI methods. The results demonstrate that the phase-distribution method is capable of accurately characterizing fluid flow inside a capillary network. Parameters estimated using the biexponential model, specifically the perfusion fraction $f$ , showed a substantial bias because the model assumptions were not met by the underlying flow pattern.

Keywords: DW-MRI; IVIM; capillary phantom; flow-compensated IVIM; intravoxel incoherent motion; perfusion.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Image Processing, Computer-Assisted / methods*
Magnetic Resonance Imaging / methods*
Models, Biological
Movement
Phantoms, Imaging