BIOMAT Database Logo BIOMAT Database Logo

Fast fluid-attenuated inversion-recovery imaging: first experience with a 3D version in epilepsy. 1998

U C Wieshmann, and G J Barker, and M R Symms, and P A Bartlett, and J M Stevens, and S D Shorvon
Epilepsy Research Group, Institute of Neurology, London, UK. uwiesh@ion.ucl.ac.uk

We developed a 3D version of fast fluid-attenuated inversion-recovery imaging (FLAIR) which provides images with a slice thickness of 1.5 mm. We present our initial experience with 3D fast FLAIR in patients with epilepsy. We compared 3D fast FLAIR (slice thickness 1.5 mm), 2D fast FLAIR (slice thickness 5 mm) and a 3D spoiled GRASS (IRSPGR) sequence (slice thickness 1.5 mm) in 10 patients with lesional epilepsy (head injury 1, hippocampal sclerosis 2, low-grade glioma 2, dysembryoplastic neuroepithelial tumour 2, polymicrogyria 1, perinatal infarct 1 and presumed thrombosed aneurysm 1). Both 2D and 3D fast FLAIR sequences yielded higher conspicuity for lesions than the T1-weighted IRSPGR sequence, except in the patient with polymicrogyria. The extent of the lesion, in particular that of low-grade tumours, was best assessed on 3D fast FLAIR images. 3D fast FLAIR may be a useful additional tool especially for imaging low-grade tumours.

UI MeSH Term Description Entries
D007089 Image Enhancement Improvement of the quality of a picture by various techniques, including computer processing, digital filtering, echocardiographic techniques, light and ultrastructural MICROSCOPY, fluorescence spectrometry and microscopy, scintigraphy, and in vitro image processing at the molecular level. Image Quality Enhancement,Enhancement, Image,Enhancement, Image Quality,Enhancements, Image,Enhancements, Image Quality,Image Enhancements,Image Quality Enhancements,Quality Enhancement, Image,Quality Enhancements, Image
D007091 Image Processing, Computer-Assisted A technique of inputting two-dimensional or three-dimensional images into a computer and then enhancing or analyzing the imagery into a form that is more useful to the human observer. Biomedical Image Processing,Computer-Assisted Image Processing,Digital Image Processing,Image Analysis, Computer-Assisted,Image Reconstruction,Medical Image Processing,Analysis, Computer-Assisted Image,Computer-Assisted Image Analysis,Computer Assisted Image Analysis,Computer Assisted Image Processing,Computer-Assisted Image Analyses,Image Analyses, Computer-Assisted,Image Analysis, Computer Assisted,Image Processing, Biomedical,Image Processing, Computer Assisted,Image Processing, Digital,Image Processing, Medical,Image Processings, Medical,Image Reconstructions,Medical Image Processings,Processing, Biomedical Image,Processing, Digital Image,Processing, Medical Image,Processings, Digital Image,Processings, Medical Image,Reconstruction, Image,Reconstructions, Image
D008279 Magnetic Resonance Imaging Non-invasive method of demonstrating internal anatomy based on the principle that atomic nuclei in a strong magnetic field absorb pulses of radiofrequency energy and emit them as radiowaves which can be reconstructed into computerized images. The concept includes proton spin tomographic techniques. Chemical Shift Imaging,MR Tomography,MRI Scans,MRI, Functional,Magnetic Resonance Image,Magnetic Resonance Imaging, Functional,Magnetization Transfer Contrast Imaging,NMR Imaging,NMR Tomography,Tomography, NMR,Tomography, Proton Spin,fMRI,Functional Magnetic Resonance Imaging,Imaging, Chemical Shift,Proton Spin Tomography,Spin Echo Imaging,Steady-State Free Precession MRI,Tomography, MR,Zeugmatography,Chemical Shift Imagings,Echo Imaging, Spin,Echo Imagings, Spin,Functional MRI,Functional MRIs,Image, Magnetic Resonance,Imaging, Magnetic Resonance,Imaging, NMR,Imaging, Spin Echo,Imagings, Chemical Shift,Imagings, Spin Echo,MRI Scan,MRIs, Functional,Magnetic Resonance Images,Resonance Image, Magnetic,Scan, MRI,Scans, MRI,Shift Imaging, Chemical,Shift Imagings, Chemical,Spin Echo Imagings,Steady State Free Precession MRI
D001921 Brain The part of CENTRAL NERVOUS SYSTEM that is contained within the skull (CRANIUM). Arising from the NEURAL TUBE, the embryonic brain is comprised of three major parts including PROSENCEPHALON (the forebrain); MESENCEPHALON (the midbrain); and RHOMBENCEPHALON (the hindbrain). The developed brain consists of CEREBRUM; CEREBELLUM; and other structures in the BRAIN STEM. Encephalon
D001927 Brain Diseases Pathologic conditions affecting the BRAIN, which is composed of the intracranial components of the CENTRAL NERVOUS SYSTEM. This includes (but is not limited to) the CEREBRAL CORTEX; intracranial white matter; BASAL GANGLIA; THALAMUS; HYPOTHALAMUS; BRAIN STEM; and CEREBELLUM. Intracranial Central Nervous System Disorders,Brain Disorders,CNS Disorders, Intracranial,Central Nervous System Disorders, Intracranial,Central Nervous System Intracranial Disorders,Encephalon Diseases,Encephalopathy,Intracranial CNS Disorders,Brain Disease,Brain Disorder,CNS Disorder, Intracranial,Encephalon Disease,Encephalopathies,Intracranial CNS Disorder
D001932 Brain Neoplasms Neoplasms of the intracranial components of the central nervous system, including the cerebral hemispheres, basal ganglia, hypothalamus, thalamus, brain stem, and cerebellum. Brain neoplasms are subdivided into primary (originating from brain tissue) and secondary (i.e., metastatic) forms. Primary neoplasms are subdivided into benign and malignant forms. In general, brain tumors may also be classified by age of onset, histologic type, or presenting location in the brain. Brain Cancer,Brain Metastases,Brain Tumors,Cancer of Brain,Malignant Primary Brain Tumors,Neoplasms, Intracranial,Benign Neoplasms, Brain,Brain Neoplasm, Primary,Brain Neoplasms, Benign,Brain Neoplasms, Malignant,Brain Neoplasms, Malignant, Primary,Brain Neoplasms, Primary Malignant,Brain Tumor, Primary,Brain Tumor, Recurrent,Cancer of the Brain,Intracranial Neoplasms,Malignant Neoplasms, Brain,Malignant Primary Brain Neoplasms,Neoplasms, Brain,Neoplasms, Brain, Benign,Neoplasms, Brain, Malignant,Neoplasms, Brain, Primary,Primary Brain Neoplasms,Primary Malignant Brain Neoplasms,Primary Malignant Brain Tumors,Benign Brain Neoplasm,Benign Brain Neoplasms,Benign Neoplasm, Brain,Brain Benign Neoplasm,Brain Benign Neoplasms,Brain Cancers,Brain Malignant Neoplasm,Brain Malignant Neoplasms,Brain Metastase,Brain Neoplasm,Brain Neoplasm, Benign,Brain Neoplasm, Malignant,Brain Neoplasms, Primary,Brain Tumor,Brain Tumors, Recurrent,Cancer, Brain,Intracranial Neoplasm,Malignant Brain Neoplasm,Malignant Brain Neoplasms,Malignant Neoplasm, Brain,Neoplasm, Brain,Neoplasm, Intracranial,Primary Brain Neoplasm,Primary Brain Tumor,Primary Brain Tumors,Recurrent Brain Tumor,Recurrent Brain Tumors,Tumor, Brain
D004828 Epilepsies, Partial Conditions characterized by recurrent paroxysmal neuronal discharges which arise from a focal region of the brain. Partial seizures are divided into simple and complex, depending on whether consciousness is unaltered (simple partial seizure) or disturbed (complex partial seizure). Both types may feature a wide variety of motor, sensory, and autonomic symptoms. Partial seizures may be classified by associated clinical features or anatomic location of the seizure focus. A secondary generalized seizure refers to a partial seizure that spreads to involve the brain diffusely. (From Adams et al., Principles of Neurology, 6th ed, pp317) Abdominal Epilepsy,Digestive Epilepsy,Epilepsy, Focal,Epilepsy, Simple Partial,Focal Seizure Disorder,Gelastic Epilepsy,Partial Epilepsy,Partial Seizure Disorder,Seizure Disorder, Partial,Simple Partial Seizures,Amygdalo-Hippocampal Epilepsy,Benign Focal Epilepsy, Childhood,Benign Occipital Epilepsy,Benign Occipital Epilepsy, Childhood,Childhood Benign Focal Epilepsy,Childhood Benign Occipital Epilepsy,Epilepsy, Benign Occipital,Epilepsy, Localization-Related,Epilepsy, Partial,Occipital Lobe Epilepsy,Panayiotopoulos Syndrome,Partial Seizures, Simple, Consciousness Preserved,Rhinencephalic Epilepsy,Seizure Disorder, Focal,Subclinical Seizure,Uncinate Seizures,Abdominal Epilepsies,Amygdalo-Hippocampal Epilepsies,Benign Occipital Epilepsies,Digestive Epilepsies,Disorders, Focal Seizure,Disorders, Partial Seizure,Epilepsies, Abdominal,Epilepsies, Amygdalo-Hippocampal,Epilepsies, Benign Occipital,Epilepsies, Digestive,Epilepsies, Focal,Epilepsies, Gelastic,Epilepsies, Localization-Related,Epilepsies, Occipital Lobe,Epilepsies, Rhinencephalic,Epilepsies, Simple Partial,Epilepsy, Abdominal,Focal Epilepsies,Focal Epilepsy,Focal Seizure Disorders,Gelastic Epilepsies,Lobe Epilepsy, Occipital,Localization-Related Epilepsies,Localization-Related Epilepsy,Occipital Epilepsies, Benign,Occipital Epilepsy, Benign,Occipital Lobe Epilepsies,Partial Epilepsies,Partial Epilepsies, Simple,Partial Seizure Disorders,Partial Seizures, Simple,Rhinencephalic Epilepsies,Seizure Disorders, Focal,Seizure Disorders, Partial,Seizure, Subclinical,Seizure, Uncinate,Seizures, Simple Partial,Seizures, Subclinical,Seizures, Uncinate,Simple Partial Epilepsies,Subclinical Seizures,Uncinate Seizure
D006801 Humans Members of the species Homo sapiens. Homo sapiens,Man (Taxonomy),Human,Man, Modern,Modern Man
D012680 Sensitivity and Specificity Binary classification measures to assess test results. Sensitivity or recall rate is the proportion of true positives. Specificity is the probability of correctly determining the absence of a condition. (From Last, Dictionary of Epidemiology, 2d ed) Specificity,Sensitivity,Specificity and Sensitivity
D016477 Artifacts Any visible result of a procedure which is caused by the procedure itself and not by the entity being analyzed. Common examples include histological structures introduced by tissue processing, radiographic images of structures that are not naturally present in living tissue, and products of chemical reactions that occur during analysis. Artefacts,Artefact,Artifact

Related Publications

U C Wieshmann, and G J Barker, and M R Symms, and P A Bartlett, and J M Stevens, and S D Shorvon
Brain: gadolinium-enhanced fast fluid-attenuated inversion-recovery MR imaging.
April 1999, Radiology,
U C Wieshmann, and G J Barker, and M R Symms, and P A Bartlett, and J M Stevens, and S D Shorvon
Double inversion recovery imaging of the brain: initial experience and comparison with fluid attenuated inversion recovery imaging.
January 1998, Magnetic resonance imaging,
U C Wieshmann, and G J Barker, and M R Symms, and P A Bartlett, and J M Stevens, and S D Shorvon
Initial clinical experience in MR imaging of the brain with a fast fluid-attenuated inversion-recovery pulse sequence.
October 1994, Radiology,
U C Wieshmann, and G J Barker, and M R Symms, and P A Bartlett, and J M Stevens, and S D Shorvon
Fluid-attenuated inversion-recovery SSFP imaging.
December 2006, Journal of magnetic resonance imaging : JMRI,
U C Wieshmann, and G J Barker, and M R Symms, and P A Bartlett, and J M Stevens, and S D Shorvon
Fluid-attenuated inversion-recovery imaging of hemichorea.
October 2003, Neuroradiology,
U C Wieshmann, and G J Barker, and M R Symms, and P A Bartlett, and J M Stevens, and S D Shorvon
Comparison of multishot echo-planar fluid-attenuated inversion-recovery imaging with fast spin-echo fluid-attenuated inversion-recovery and T2-weighted imaging in depiction of white matter lesions.
January 2002, Journal of computer assisted tomography,
U C Wieshmann, and G J Barker, and M R Symms, and P A Bartlett, and J M Stevens, and S D Shorvon
Fast fluid-attenuated inversion-recovery MR of intracranial infections.
May 1997, AJNR. American journal of neuroradiology,
U C Wieshmann, and G J Barker, and M R Symms, and P A Bartlett, and J M Stevens, and S D Shorvon
Fast Quantitative Magnetic Resonance Imaging Evaluation of Hydrocephalus Using 3-Dimensional Fluid-Attenuated Inversion Recovery: Initial Experience.
January 2024, Journal of computer assisted tomography,
U C Wieshmann, and G J Barker, and M R Symms, and P A Bartlett, and J M Stevens, and S D Shorvon
Population-Based Prevalence of Infarctions on 3D Fluid-Attenuated Inversion Recovery (FLAIR) Imaging.
August 2022, Journal of stroke and cerebrovascular diseases : the official journal of National Stroke Association,
U C Wieshmann, and G J Barker, and M R Symms, and P A Bartlett, and J M Stevens, and S D Shorvon
Cerebral gliomas and metastases: assessment with contrast-enhanced fast fluid-attenuated inversion-recovery MR imaging.
February 1999, Radiology,
Copied contents to your clipboard!