Findings Regarding an Intracranial Hemorrhage on the Phase Image of a Susceptibility-Weighted Image (SWI), According to the Stage, Location, and Size.
10.13104/imri.2015.19.2.107
- Author:
Yoon Jung LEE
1
;
Song LEE
;
Jinhee JANG
;
Hyun Seok CHOI
;
So Lyung JUNG
;
Kook Jin AHN
;
Bum Soo KIM
;
Kang Hoon LEE
Author Information
1. Department of Radiology, Seoul St. Mary's Hospital, College of Medicine, The Catholic University of Korea, Seoul, Korea. hschoi@catholic.ac.kr
- Publication Type:Original Article
- Keywords:
Intracranial hemorrhage;
Phase map;
Susceptibility weighted imaging;
Magnetic resonance imaging
- MeSH:
Artifacts;
Axis, Cervical Vertebra;
Hematoma;
Hemorrhage;
Humans;
Intracranial Hemorrhages*;
Magnetic Resonance Imaging;
Retrospective Studies;
Subarachnoid Hemorrhage
- From:Investigative Magnetic Resonance Imaging
2015;19(2):107-113
- CountryRepublic of Korea
- Language:English
-
Abstract:
PURPOSE: Susceptibility weighted imaging (SWI) is a new magnetic resonance technique that can exploit the magnetic susceptibility differences of various tissues. Intracranial hemorrhage (ICH) looks a dark blooming on the magnitude images of SWI. However, the pattern of ICH on phase images is not well known. The purpose of this study is to characterize hemorrhagic lesions on the phase images of SWI. MATERIALS AND METHODS: We retrospectively enrolled patients with ICH, who underwent both SWI and precontrast CT, between 2012 and 2013 (n = 95). An SWI was taken, using the 3-tesla system. A phase map was generated after post-processing. Cases with an intracranial hemorrhage were reviewed by an experienced neuroradiologist and a trainee radiologist, with 10 years and 3 years of experience, respectively. The types and stages of the hemorrhages were determined in correlation with the precontrast CT, the T1- and T2-weighted images, and the FLAIR images. The size of the hemorrhage was measured by a one-directional axis on a magnitude image of SWI. The phase values of the ICH were qualitatively evaluated: hypo-, iso-, and hyper-intensity. We summarized the imaging features of the intracranial hemorrhage on the phase map of the SWI. RESULTS: Four types of hemorrhage are observed: subdural and epidural; subarachnoid; parenchymal hemorrhage; and microbleed. The stages of the ICH were classified into 4 groups: acute (n = 34); early subacute (n = 11); late subacute (n = 15); chronic (n = 8); stage-unknown microbleeds (n = 27). The acute and early subacute hemorrhage showed heterogeneous mixed hyper-, iso-, and hypo-signal intensity; the late subacute hemorrhage showed homogeneous hyper-intensity, and the chronic hemorrhage showed a shrunken iso-signal intensity with the hyper-signal rim. All acute subarachnoid hemorrhages showed a homogeneous hyper-signal intensity. All parenchymal hemorrhages (> 3 mm) showed a dipole artifact on the phase images; however, microbleeds of less than 3 mm showed no dipole artifact. Larger hematomas showed a heterogeneous mixture of hyper-, iso-, and hypo-signal intensities. CONCLUSION: The pattern of the phase value of the SWI showed difference, according to the type, stage, and size.
