Quantitative Susceptibility Mapping Differentiates between Blood Depositions and Calcifications in Patients with Glioblastoma

Deistung, Andreas; Schweser, Ferdinand; Wiestler, Benedikt; Abello, Mario; Roethke, Matthias; Sahm, Felix; Wick, Wolfgang; Nagel, Armin M.; Heiland, Sabine; Schlemmer, Heinz Peter; Bendszus, Martin; Reichenbach, Jürgen R.; Radbruch, Alexander

doi:10.1371/journal.pone.0057924

Cited by 152 publications

(142 citation statements)

References 42 publications

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“…34 SWI can effectively demonstrate intratumoral calcification as well, 23,70,76,112,118 with hypointensity seen on SW images, which correlates with CT findings (Fig. 4).…”

Section: Detecting and Diagnosing Brain Tumorssupporting

confidence: 61%

“…7,49 By monitoring changes in pre-and postrecanalization of the CVS, SWI can detect differences in CVS prominence before and after occlusion. 7 Thus, an equal CVS postrecanalization (that is, the appearance of similar veins in both hemispheres) is suggestive of a good clinical outcome, whereas a less prominent CVS (that is, veins in an occluded hemisphere are less prominent than veins in However, most studies 20,23,88 have focused on lesion detection in sporadic or familial cerebral cavernous malformations (CCMs), making it difficult to assess the sensitivity of SWI in detecting VMs other than CCMs.…”

Section: Monitoring Outcome In Strokementioning

confidence: 99%

“…52,53 Moreover, in more complex cases, SWI can help diagnose specific high-flow VMs, such as arteriovenous malformations (AVMs; Fig. 9), 53 and low-flow VMs, including CCM, 20,23,88 brain capillary telangiectasia, 28 or Sturge-Weber syndrome. 48,110 Most importantly, the findings from SWI, especially at ultrahigh fields (that is, 7 T), 29 are shown to correlate with histopathological studies.…”

Section: Monitoring Outcome In Strokementioning

confidence: 99%

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Magnetic resonance susceptibility weighted imaging in neurosurgery: current applications and future perspectives

Ieva¹,

Lam²,

Alcaide‐Leon

et al. 2015

JNS

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T he initial development of MR venography by Reichenbach et al. 90 laid the foundation for Haacke et al. 42 to apply the principles of MR venography in conventional MRI for broader usage in clinical and research settings. By utilizing magnitude and phase information, both of which are normally acquired from conventional MRI data, susceptibility weighted imaging (SWI) has an enhanced ability to detect microhemorrhages 4,12,26 and microvasculature. 26,27,41,92 It is a highly sensitive imaging modality able to depict magnetic substances, such as deoxygenated hemoglobin, with high contrast 42 and to help investigate neurological diseases, 82 grade tumors, 25,63 and assist in determining treatment or prognosis. 18,26,37,70,71,115 Over the past years, the SWI technique has found applications in the different fields of neurosurgery, namely neurooncology, vascular neurosurgery, neurotraumatolabbreviatioNs AVM = arteriovenous malformation; CCM = cerebral cavernous malformation; CMB = cerebral microbleed; CVS = cortical vessel sign; DAI = diffuse axonal injury; DBS = deep brain stimulation; DWI = diffusion-weighted imaging; GBM = glioblastoma multiforme; GCS = Glasgow Coma Scale; GPe = external globus pallidus; GPi = internal GP; GRE = gradient-recalled echo; ITSS = intratumoral susceptibility signal; mIP = minimum intensity projection; MRA = MR angiography; MS = multiple sclerosis; PD = proton density; PQ = percentagewise quantification; PWI = perfusion-weighted imaging; SN = substantia nigra; STN = subthalamic nucleus; SWI = susceptibility weighted imaging; TBI = traumatic brain injury; VM = vascular malformation. Susceptibility weighted imaging (SWI) is a relatively new imaging technique. Its high sensitivity to hemorrhagic components and ability to depict microvasculature by means of susceptibility effects within the veins allow for the accurate detection, grading, and monitoring of brain tumors. This imaging modality can also detect changes in blood flow to monitor stroke recovery and reveal specific subtypes of vascular malformations. In addition, small punctate lesions can be demonstrated with SWI, suggesting diffuse axonal injury, and the location of these lesions can help predict neurological outcome in patients. This imaging technique is also beneficial for applications in functional neurosurgery given its ability to clearly depict and differentiate deep midbrain nuclei and close submillimeter veins, both of which are necessary for presurgical planning of deep brain stimulation. By exploiting the magnetic susceptibilities of substances within the body, such as deoxyhemoglobin, calcium, and iron, SWI can clearly visualize the vasculature and hemorrhagic components even without the use of contrast agents. The high sensitivity of SWI relative to other imaging techniques in showing tumor vasculature and microhemorrhages suggests that it is an effective imaging modality that provides additional information not shown using conventional MRI. Despite SWI's clinical advantages, its implementation in MRI protocols is st...

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“…34 SWI can effectively demonstrate intratumoral calcification as well, 23,70,76,112,118 with hypointensity seen on SW images, which correlates with CT findings (Fig. 4).…”

Section: Detecting and Diagnosing Brain Tumorssupporting

confidence: 61%

Section: Monitoring Outcome In Strokementioning

confidence: 99%

Section: Monitoring Outcome In Strokementioning

confidence: 99%

See 1 more Smart Citation

Magnetic resonance susceptibility weighted imaging in neurosurgery: current applications and future perspectives

Ieva¹,

Lam²,

Alcaide‐Leon

et al. 2015

JNS

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“…GRE phase imaging has been reported to be useful for differentiating calcifications from hemorrhages (3,8,11). Recently, it has been suggested that QSM can enable the differentiation of diamagnetic calcifications from paramagnetic hemorrhages (9,17,18). To our knowledge, this study is the first systematic evaluation of the diagnostic accuracy of QSM and comparison between QSM and GRE phase imaging in the assessment of calcifications and hemorrhages.…”

Section: Neuroradiology: Characterization Of Intracranial Calcificatimentioning

confidence: 91%

“…Chen et al (13,15,16) and has been suggested for differentiating diamagnetic calcifications from paramagnetic hemorrhages (9,17,18). We performed this study to compare GRE phase imaging and QSM in the detection of intracranial calcifications and hemorrhages.…”

Section: Neuroradiology: Characterization Of Intracranial Calcificatimentioning

confidence: 99%

Intracranial Calcifications and Hemorrhages: Characterization with Quantitative Susceptibility Mapping

Chen¹,

Zhu²,

Kovanlikaya³

et al. 2014

Radiology

221

129

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Purpose:To compare gradient-echo (GRE) phase magnetic resonance (MR) imaging and quantitative susceptibility mapping (QSM) in the detection of intracranial calcifications and hemorrhages. Materials and Methods:This retrospective study was approved by the institutional review board. Results:A total of 156 lesions were detected: 62 hemorrhages, 89 calcifications, and five mixed lesions containing both hemorrhage and calcification. Most of these lesions (146 of 151 lesions, 96.7%) had a dominant sign on QSM images suggestive of a specific diagnosis of hemorrhage or calcium, whereas half of these lesions (76 of 151, 50.3%) were heterogeneous on GRE phase images and thus were difficult to characterize. Averaged over the two independent observers for detecting hemorrhages, QSM achieved a sensitivity of 89.5% and a specificity of 94.5%, which were significantly higher than those at GRE phase imaging (71% and 80%, respectively; P , .05 for both readers). In the identification of calcifications, QSM achieved a sensitivity of 80.5%, which was marginally higher than that with GRE phase imaging (71%; P = .08 and .10 for the two readers), and a specificity of 93.5%, which was significantly higher than that with GRE phase imaging (76.5%; P , .05 for both readers). QSM achieved significantly better interobserver agreements than GRE phase imaging in the differentiation of hemorrhage from calcification (k: 0.91 vs 0.55, respectively; P , .05). Conclusion:QSM is superior to GRE phase imaging in the differentiation of intracranial calcifications from hemorrhages and with regard to the sensitivity and specificity of detecting hemorrhages and the specificity of detecting calcifications.q RSNA, 2013

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Diffusion propagators for hindered diffusion in open geometries

Ziener

Kampf

Kurz

2015

Concepts Magnetic Resonance

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The diffusion of spin‐bearing particles around simple geometrical objects like cylinders and spheres abides by the form of the diffusion propagator that specifies the probability of a particle to diffuse from one position to another within a specific time span. While diffusion propagators for diffusion inside a cylinder or sphere are well‐analyzed, diffusion propagators for hindered diffusion around these open geometries are rarely discussed in MR literature. Knowledge of such diffusion propagators for hindered diffusion allows quantifying the influence of diffusion processes on the MR signal around single vessels or blood residues and ultra‐small iron‐oxide particles, respectively, when there is no outer boundary present. In this work, analytical expressions for the diffusion propagator for hindered diffusion in one, two and three dimensions as well as the resulting correlation functions for diffusion in a dipole field around cylinders and spheres are derived. © 2015 Wiley Periodicals, Inc. Concepts Magn Reson Part A 44A: 150–159, 2015.

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Quantitative Susceptibility Mapping Differentiates between Blood Depositions and Calcifications in Patients with Glioblastoma

Cited by 152 publications

References 42 publications

Magnetic resonance susceptibility weighted imaging in neurosurgery: current applications and future perspectives

Magnetic resonance susceptibility weighted imaging in neurosurgery: current applications and future perspectives

Intracranial Calcifications and Hemorrhages: Characterization with Quantitative Susceptibility Mapping

Diffusion propagators for hindered diffusion in open geometries

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