Published online before print March 28, 2013, doi: 10.3174/ajnr.A3571
AJNR 2013 34: E72

T.M. Mehemed^a and A. Yamamoto^a
aDepartment of Diagnostic Imaging and Nuclear Medicine
Kyoto University Graduate School of Medicine
Kyoto, Japan

We read with interest the article entitled “Detection of Intratumoral Calcification in Oligodendrogliomas by Susceptibility-Weighted MR Imaging”1 and would like to comment on the appearance of calcification on the high-pass-filtered phase images.

The authors reported that the paramagnetic (authors wrote “diamagnetic”) hemorrhagic component of the tumor would cause a negative phase shift and appear as dark signal on the high-pass-filtered phase images, while the diamagnetic (authors wrote “paramagnetic”) intratumoral calcifications would cause an opposite positive phase shift and appear as bright signal on the high-pass-filtered phase images. This description is true, but only in the case of right-handed MR imaging systems, while in left-handed MR imaging systems, the complete opposite signal would be seen: Paramagnetic substances would appear bright, while diamagnetic substances would appear dark.2,3

In Figs 2D and 3D of the above-mentioned article, the high-pass-filtered phase images are those of a left-handed MR imaging system, evident by the bright signal of the veins (paramagnetic deoxyhemoglobin).3

The article showed that high-pass-filtered phase images can depict intratumoral calcification in oligodendrogliomas better than conventional MR images; this finding has been reported before.4 Understanding the contrast appearance of high-pass-filtered phase images on left-handed versus right-handed MR imaging systems would make distinguishing diamagnetic calcification from paramagnetic hemorrhage a much easier task and prevent any possible confusion.

References

1. Zulfiqar M, Dumrongpisutikul N, Intrapiromkul J, et al. Detection of intratumoral calcification in oligodendrogliomas by susceptibility-weighted MR imaging. AJNR Am J Neuroradiol 2012;33:858–64 » Abstract/FREE Full Text
2. Duyn J, Speck O. Brain Anatomy with Phase. In: Haacke EM, ReichenbachJR. Susceptibility Weighted Imaging in MRI: Basic Concepts and Clinical Applications. Hoboken, New Jersey: John Wiley & Sons; 2011:121–36 » Search Google Scholar
3. Mittal S, Thomas B, Wu Z, et al. Novel approaches to imaging brain tumors. In: Haacke EM, Reichenbach JR. Susceptibility Weighted Imaging in MRI: Basic Concepts and Clinical Applications. Hoboken, New Jersey: John Wiley & Sons; 2011:151–70 » Search Google Scholar
4. Wu Z, Mittal S, Kish K, et al. Identification of calcification with MRI using susceptibility-weighted imaging: a case study. J Magn Reson Imaging 2009;29:177–82 » CrossRef » Medline