Magnetic resonance imaging for quantitative flow measurement in infants with hydrocephalus: a prospective study

Leliefeld, Paul H.; Gooskens, R. H. J. M.; Vincken, Koen L.; Ramos, L. M. P.; Tulleken, C. A. F.; Kappelle, L. Jaap; Hanlo, Patrick W.

doi:10.3171/ped/2008/2/9/163

Cited by 31 publications

(19 citation statements)

References 68 publications

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“…The method used in the present study is identical to the one suggested by Leliefeld et al 20 In 2 of the hydrocephalus cases, the CBF was very low initially (27 and 23 ml/100 g/min, similar to Leliefeld and colleagues' findings). However, in 1 case, CBF was normal at 67 ml/100 g/min.…”

supporting

confidence: 69%

“…27 Leliefeld et al used an MRI-based technique to simultaneously measure cerebral inflow via the carotid and basilar arteries and brain parenchymal volume to obtain quantitative data on CBF. 20 In a study of 15 infants from 1 day to 7 months of age, the mean CBF before shunting was 25 ml/100 g/min, which increased to 50 ml/100 g/min following treatment with a shunt. A doubling of CBF after shunting suggests a significant increase in vascular resistance before shunt placement as well as rapid improvement with a reduction in resistance post-shunt insertion.…”

Section: ©Aans 2014mentioning

confidence: 99%

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Hemodynamically significant venous collapse underlying neonatal hydrocephalus

Bateman¹

2014

PED

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Object It is known that CSF diversion in neonatal hydrocephalus can significantly increase cerebral blood flow, suggesting that a rapidly reversible elevation in vascular resistance underlies this disorder. Various sites of vascular compression have been described in the literature, from the arterioles to the capillary bed to the venules and sinuses. The purpose of this study was to define the site of the hemodynamically significant vascular compression seen in neonatal hydrocephalus. Methods The author performed a retrospective review of all patients who, in the first 28 days of life, had undergone 3-T MRI examination, including MR venography and susceptibility weighted scanning, at a tertiary care referral hospital in the period from April 2010 to April 2013. The maximum size of the subependymal veins over the thalamus and transverse sinuses was measured. Results Three children with hydrocephalus were identified, and 10 children with a normal ventricular size served as controls. The subependymal veins were twice as prominent and the transverse sinuses were half as large in the patients with hydrocephalus compared with those in controls. Conclusions The hemodynamically significant elevation in vascular resistance, which occurs in neonatal hydrocephalus, appears to be located in the venous sinuses.

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confidence: 69%

Section: ©Aans 2014mentioning

confidence: 99%

Hemodynamically significant venous collapse underlying neonatal hydrocephalus

Bateman¹

2014

PED

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“…22 Recently, 2D phase-contrast MRA has shown that carotid and basilar arterial flow rates are reduced in infants with hydrocephalus. 23 However, 2D phase-contrast MRA does not directly measure CBF at the tissue level and may be hampered by long scanning times and flow-sensitive technical challenges. 24,25 In contrast, arterial spin-labeled (ASL) MR imaging perfusion directly measures tissue perfusion without requiring long scanning times, contrast, or radioisotope injection.…”

mentioning

confidence: 99%

Hydrocephalus Decreases Arterial Spin-Labeled Cerebral Perfusion

Yeom¹,

Lober²,

Alexander³

et al. 2014

AJNR Am J Neuroradiol

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“…Nowadays, magnetic resonance is already being used associated with other resources to aim of investigating pathophysiological characteristics of several diseases, mainly the neurological ones [11][12][13] . However, most studies, both experimental and clinical, use MRI equipment of field higher than 1.0T.…”

Section: 1t Magnetic Resonance Image In the Study Of Experimental Hmentioning

confidence: 99%

0.1T magnetic resonance image in the study of experimental hydrocephalus in rats. Accuracy of the method in the measurements of the ventricular size

Castro¹,

Machado

Catalão³

et al. 2012

Acta Cir. Bras.

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PURPOSE: To investigate the accuracy of 1.0T Magnetic Resonance Imaging (MRI) to measure the ventricular size in experimental hydrocephalus in pup rats. METHODS: Wistar rats were subjected to hydrocephalus by intracisternal injection of 20% kaolin (n=13). Ten rats remained uninjected to be used as controls. At the endpoint of experiment animals were submitted to MRI of brain and killed. The ventricular size was assessed using three measures: ventricular ratio (VR), the cortical thickness (Cx) and the ventricles area (VA), performed on photographs of anatomical sections and MRI. RESULTS: The images obtained through MR present enough quality to show the lateral ventricular cavities but not to demonstrate the difference between the cortex and the white matter, as well as the details of the deep structures of the brain. There were no statistically differences between the measures on anatomical sections and MRI of VR and Cx (p=0.9946 and p=0.5992, respectively). There was difference between VA measured on anatomical sections and MRI (p<0.0001). CONCLUSION: The parameters obtained through 1.0T MRI were sufficient in quality to individualize the ventricular cavities and the cerebral cortex, and to calculate the ventricular ratio in hydrocephalus rats when compared to their respective anatomic slice.

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Magnetic resonance imaging for quantitative flow measurement in infants with hydrocephalus: a prospective study

Cited by 31 publications

References 68 publications

Hemodynamically significant venous collapse underlying neonatal hydrocephalus

Hemodynamically significant venous collapse underlying neonatal hydrocephalus

Hydrocephalus Decreases Arterial Spin-Labeled Cerebral Perfusion

0.1T magnetic resonance image in the study of experimental hydrocephalus in rats. Accuracy of the method in the measurements of the ventricular size

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