Improving Lesion Detection in Children With Magnetic Resonance Imaging (MRI)-Negative Partial Epilepsy Using Diffusion Tensor Imaging

Improving Lesion Detection in Children With MRI-negative Partial Epilepsy Using Diffusion Tensor Imaging

Status

Completed

Phases

Unknown

Study type

Observational

Source

ClinicalTrials.gov

Registry ID

NCT00894478

Enrollment

Registered

2009-05-07

Start date

2009-05-31

Completion date

2012-05-31

Last updated

2013-09-10

For informational purposes only — not medical advice. Sourced from public registries and may not reflect the latest updates. Terms

Conditions

Localization-related Epilepsy, Partial Epilepsy

Keywords

MRI-Negative, Diffusion tensor imaging, Localization-related epilepsy, Partial Epilepsy, Children

Brief summary

Focal cortical dysplasia is one of the most common lesions responsible for medically refractory epilepsy in the pediatric population. In patients with medically intractable epilepsy, surgery is the only treatment that will lead to seizure freedom. The outcome of epilepsy surgery is worse in patients when there is no lesion identified on routine structural MRI, also known as MRI-negative partial epilepsy. Diffusion tensor imaging (DTI), a novel MRI technique, can be used to evaluate the integrity of the microstructure of the white matter, even when the white matter appears normal on routine MRI.

Detailed description

The aims of this study are firstly to identify DTI abnormalities in the white matter of children with MRI-negative partial epilepsy and MRI-visible FCD compared to normal controls; and secondly to determine if the location of DTI identified abnormalities correlate with the epileptogenic zone as defined using magnetoencephalography (MEG) dipole clusters. Our hypotheses are firstly DTI can demonstrate the anatomic delineation of white matter abnormalities in MRI-negative partial epilepsy and the alteration in DTI indices are similar in MRI-negative partial epilepsy and MRI-visible FCD, which is the positive control; and secondly the anatomical location of DTI identified abnormalities correlate with the epileptogenic zone as defined by MEG dipole clusters. The long-term goal of this study is to improve detection of subtle lesions in children with MRI-negative partial epilepsy so as to improve the surgical outcome of these patients who undergo epilepsy surgery for seizure control.

Interventions

PROCEDUREDiffusion Tensor Imaging (DTI)

MR and DTI: MRI and DTI will be done using 3.0T Philips MR scanner (Philips Medical Systems, Best, The Netherlands) using an eight channel head coil. DTI and axial 3D T1 will be performed on patients and controls. 1. DTI will be performed using single shot diffusion-weighted echo planar imaging, b=1000s/mm2 and 15 noncollinear directions (TR/TE=10,000/60 ms, slice thickness=2mm, field of view=22cm, matrix=112x112, NEX=2) 2. Axial 3D T1 (TR/TE=4.9/2.3 ms, slice thickness=1 mm, field of view = 24 cm, matrix=220x220, NEX=1) Patients will have additional sequences (axial and coronal T2, proton density and FLAIR) as part of their clinical scan

PROCEDUREMagnetoencephalography

MEG will be performed using a whole-head Omega 151-channel gradiometer system (VSM MedTech, Port Coquitalam, BC, Canada). At least 15 2-minute periods of spontaneous data will be recorded with a sampling rate for data acquisition of 625Hz, a bandpass filter of 10 to 70 Hz and a notch filter of 60 Hz.

Study design

Observational model

COHORT

Time perspective

CROSS_SECTIONAL

Eligibility

Sex/Gender

ALL

Age

6 Years to 18 Years

Healthy volunteers

Yes

Inclusion criteria

MRI negative partial epilepsy group: * Patients diagnosed with partial epilepsy according to the International League Against Epilepsy (ILAE) standard \[53\] * MRI study reported as normal * Age ranging from 6-18 years (DTI indices alter with myelination and the changes are most marked from birth to 4 years of age) MRI-visible FCD group: * Patients diagnosed with partial epilepsy according to the ILAE standard \[53\] * Visual assessment of MRI demonstrates one or more features of FCD * Cortical thickening * Alteration in sulci and gyri pattern, including deep sulci * Blurring of gray-white matter transition * T2 signal prolongation of the cortex and subcortical white matter * High T1 signal in the cortex * Age ranging from 6-18 years (DTI indices alter with myelination and the changes are most marked from birth to 4 years of age) Normal controls: * Subjects with no history of neurological diseases * Age ranging from 6-18 years (most children under the age of 6 years are unable to tolerate the MR examination without general anesthesia or sedation). * No requirement of general anesthesia or sedation

Exclusion criteria

* Subjects with contraindications for MR imaging (i.e. retained foreign bodies, implants) * Subjects with claustrophobia * Controls with a prior history of traumatic brain injury, neurological disorder, cerebral palsy, developmental delay or learning disability * Controls who require general anesthesia or sedation

Design outcomes

Primary

Measure	Time frame
Identify DTI changes in the white matter of children with MRI-negative partial epilepsy and MRI-visible FCD using voxel-by-voxel analysis of FA and MD maps compared to normal controls.	1 timepoint; immediately after MRI/DTI

Secondary

Measure	Time frame
Determine if the lobar location of abnormal FA and MD correlate with the lobar location of MEG defined epileptogenic zone in MRI-negative partial epilepsy and MRI-visible FCD.	1 timepoint; immediately after MRI/DTI

Countries

Canada

Outcome results

None listed

Source: ClinicalTrials.gov · Data processed: Feb 4, 2026