# A Subtracted‐Added‐Divided Inversion Recovery (dSIR) Approach to Visualise the Effects of Microstructure on T1 Contrast in Human White Matter

**Authors:** Risto A. Kauppinen, Jeromy Thotland, Pramod K. Pisharady, Christophe Lenglet, Michael Garwood

PMC · DOI: 10.1002/nbm.70070 · Nmr in Biomedicine · 2025-05-29

## TL;DR

This paper introduces a new MRI technique called dSIR to better visualize how white matter microstructure affects T1 contrast in the brain.

## Contribution

The dSIR approach enhances visualization of microstructure effects on T1 contrast in white matter using algebraic manipulation of MRI images.

## Key findings

- dSIR contrast is 1.6 times higher at 7T compared to 3T, improving visualization of white matter microstructure effects.
- dSIR reveals angular patterns in white matter tracts oriented at high angles to the magnetic field.
- dSIR successfully visualizes intratissue T1 differences caused by microstructural features like axon orientation and size.

## Abstract

Recent evidence has demonstrated that several white matter (WM) microstructural features, such as axon diameter, fibre configurations and fibre orientation in respect to the magnetic field influence T1 relaxation. The effects from microstructural features on T1 are small in size, thus, visualising the effects of WM microstructure remains challenging in standard T1 weighted MRI in vivo. Here, we have studied an algebraic approach involving subtraction, addition and division of closely spaced inversion time images in WM imaging, the so‐called dSIR approach. Images collected with short TI (300 ms at 3T and 600 ms at 7T) and long TI (600 ms at 3T and 1000 ms at 7T) with MP2RAGE MRI were combined using the dSIR processing. dSIR signal intensities were compared with absolute T1 images. We found that dSIR was linearly related with T1 relaxation time over approximately 200 ms both at 3T and 7T. The slope of the dSIR versus T1 plot was 1.6 times greater at 7T than at 3T indicative of higher dSIR contrast at 7T. dSIR contrast revealed WM tracts that are oriented with high angle (fibre‐to‐field angle > 75°), in addition, dSIR signal showed angular patterns that closely resembled those of T1 at both fields. The dSIR contrast due to intratissue T1 difference of order of ~50 ms generated by microstructural features, including axon fibre orientation as well as by the presence of large and giant axons in somato‐motor subsection of corpus callosum were visualised. It is concluded that dSIR signal mimics T1 and that the dSIR contrast is higher at 7T than at 3T; thus, the approach will help to visualise the effects of microstructure on T1 to evaluate WM integrity.

TI images collected with short (300ms/600ms, 3T/7T) and long TI (600ms/1000ms, 3T/7T) were processed using the dSIR approach to visualise effects of white matter (WM) microstructure on T1 contrast. Short T1 resulting from relaxation anisotropy in WM tracts with close to perpendicular orientation to B0 was visualised by excellent dSIR contrast against adjacent WM [Figure A (3T) and B (7T)]. dSIR provides a means to visualise the effects of microstructure on T1 to evaluating WM integrity.

## Full-text entities

- **Chemicals:** T1 (MESH:C103828)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12120812/full.md

## References

37 references — full list in the complete paper: https://tomesphere.com/paper/PMC12120812/full.md

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Source: https://tomesphere.com/paper/PMC12120812