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The Egyptian Journal of Radiology and Nuclear Medicine (2015) 46, 1129–1141
Egyptian Society of Radiology and Nuclear Medicine
The Egyptian Journal of Radiology andNuclearMedicine
www.elsevier.com/locate/ejrnmwww.sciencedirect.com
ORIGINAL ARTICLE
Assessment of the diagnostic reliability of brain CT
and MRI in pediatric epilepsy patients
Abbreviations: FCD, focal cortical dysplasia; AVM, arterio-venous
malformation; PVL, periventricular leukomalacia; TS, tuberous
sclerosis; CMV, cytomegalo virus; TB, tuberculosis; WM, white
matter; ADEM, acute disseminated encephalomyelitis; ADL,
adrenoleukodystrophy.* Corresponding author at: Department of Radiology, Sohag Faculty
of Medicine, Sohag University, Egypt. Tel.: +20 1224648517, +20
932307121.
E-mail address: m.elkousy@yahoo.com (M.H. Alam-Eldeen).
Peer review under responsibility of Egyptian Society of Radiology and
Nuclear Medicine.
http://dx.doi.org/10.1016/j.ejrnm.2015.07.0010378-603X � 2015 The Authors. The Egyptian Society of Radiology and Nuclear Medicine. Production and hosting by Elsevier B.V.This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).
Mohamad Hasan Alam-Eldeen *, Nahla Mohamed Ali Hasan
Department of Diagnostic Radiology, Sohag Faculty of Medicine, Sohag University, Egypt
Received 27 April 2015; accepted 4 July 2015
Available online 26 July 2015
KEYWORDS
Pediatric epilepsy;
CT;
MRI
Abstract Objective: Analysis of the role of CT and MRI in evaluation of pediatric epilepsy and
their diagnostic utility to detect various pathologic entities at one center.
Patients and methods: From April 2012 to April 2014, 181 children with epilepsy were underwent
standardized CT and or MRI in the Department of Diagnostic Radiology at Sohag University
Hospitals. We retrospectively analyzed whether lesions were detected and whether were precisely
characterized by CT and or MRI.
Results: Of the 181 patients included in the study, abnormalities were detected in 132 patients
(73%) while normal brain images were found in 49 patients (27%). Of the 74 patients had CT only,
abnormalities were detected in 73% while 27% were normal. Of the 89 patients underwent MRI
only, abnormalities were detected in 74% while 26% were normal. Of the 18 patients underwent
CT and MRI, abnormalities were detected in 67% while 33% were normal.
Conclusion: Seizure disorders are among the most frequent neurologic problems that occur in
childhood. MRI is the technique of choice and is superior to CT in identifying underlying cause.
However, CT can serve as a screening modality and MRI would be performed to define abnormal-
ities found on CT or in negative CT studies.� 2015 The Authors. The Egyptian Society of Radiology and Nuclear Medicine. Production and hosting
by Elsevier B.V. This is an open access article under the CC BY-NC-ND license (http://
creativecommons.org/licenses/by-nc-nd/4.0/).
1. Introduction
Epilepsy is a chronic condition characterized by recurrentunprovoked seizures displaying the clinical manifestation of
excessive, abnormal, unprovoked, synchronous discharges ofneurons (1). Childhood epilepsies are a heterogeneous groupof conditions that differ in their diagnostic criteria and man-agement and have dramatically different outcomes. There are
different classification systems for epilepsy, commonly accord-ing either anatomy or etiology. According to etiology, epilepsyis classified into developmental, neoplastic, vascular, post trau-
matic, inflammatory or infective conditions (1,2).
Table 1 Positive and negative findings in the different imaging
modalities used.
Imaging modality No of patients +ve Findings �ve FindingsI. CT 74 54 (73%) 20 (27%)
II. MRI 89 66 (74%) 23 (26%)
III. CT & MRI 18 12 (67%) 6 (33%)
Total 181 132 (73%) 49 (27%)
1130 M.H. Alam-Eldeen, N.M.A. Hasan
The role of neuroimaging is to detect an underlying cerebrallesion(s) that may be related to the child’s seizure disorder that
is associated in some cases with neurodevelopmental impair-ment. Imaging is obtained to establish etiology, to provideprognosis, and to plan appropriate clinical care (3). CT can
detect some abnormalities and easily detects conditions
Fig. 1 FCD. Axial FLAIR (A), T1 pre contrast (B) and T1 post con
frontal lobe that is of abnormal high signal on FLAIR with blurred j
Fig. 2 Schizencephaly. (A) Patient with Rt sided open lip schizenceph
nipple sign is evident on (C). (D–F) Patient with Lt sided open lip schiz
seen on CT and MRI.
associated with calcification such as found in congenital infec-tions. MRI is fundamental in epilepsy imaging, providingstructural, anatomical and pathologic informations (4).
Recent advances in MRI, have increased our understandingof the underlying disease process which is reflected on manage-ment of epilepsy (5).
In this study we analyzed whether lesions were detected andwhether they were precisely characterized by CT and standard-ized MRI and in which cases CT is a sufficient imaging tool for
pediatric epilepsy at one center.
2. Patients and methods
This retrospective hospital-based study included 181 pediatricpatients (96 boys and 85 girls, mean age was 4 years and3 months, ranged from 1 month to 17 years) that were clini-
cally diagnosed as having epilepsy and referred to the
trast (C) showing a non enhancing focal cortical thickening at Rt
unction with WM.
aly. (B and C) Patient with Rt sided closed lip schizencephaly, the
encephaly, the ectopic gray matter lining the cleft margins is clearly
Fig. 3 Semilobar holoprosencephaly. (A and B) Axial and coronal T2 showing semilobar holoprosencephaly, the sylvian fissures lie
more anterior than usual.
Fig. 4 Subependymal heterotopia. CT scan shows multiple
heterotopic gray matter nodules along subependymal region of Lt
lateral ventricle.
Fig. 5 Pachygyria. CT scan shows b
Assessment of the diagnostic reliability of brain CT and MRI 1131
Department of Diagnostic Radiology at Sohag UniversityHospitals for imaging assessment in the period from April
2012 to April 2014. Of the 181 patients included in the study,74 patients referred for CT scan only, 89 patients for MRI onlyand 18 patients for CT scan and MRI. Children with intracra-
nial tumors and CNS postoperative cases were excluded fromthe study due to absence of operative and histopathologicaldata.
2.1. CT technique
Unenhanced and when necessary enhanced (intravenousadministration of 2 ml/kg of Ultravist 300 mg/ml) brain
CT-scans were obtained on GE Lightspeed ultra 8 slicescanner with a slice thickness 5–8 mm.
2.2. MRI technique
MRI was performed on a 1.5T unit (Philips-Acheiva,Netherlands) using dedicated head coil. The protocol included
the following sequences: axial T1-weighted, T2-weighted, and
ilateral frontal lobes pachygyria.
Fig. 6 Polymicrogyria. CT scan shows focal polymicrogyria at
Rt parietal lobe.
Fig. 7 Bilateral underdeveloped operculum. CT scan shows
marked bilateral underdeveloped operculum with exposure of
insula.
1132 M.H. Alam-Eldeen, N.M.A. Hasan
fluid-attenuated inversion recovery (FLAIR) images; coronal
T2-weighted and sagittal T1-weighted images with the follow-ing parameters; T1-weighted spin-echo (TR – 450 ms; TE –15 ms), T2-weighted spin-echo (TR – 5509 ms; TE – 110 ms),
FLAIR images (TR – 900 ms; TE 140 ms). All MR imagesare obtained at a 5-mm section thickness with a 1 mm intersec-tion gap.
In patients with the epileptogenic zone in the temporal lobe,coronal images were acquired perpendicular to the hippocam-pal axis. Contrast enhanced spin-echo T1-weighted images
were performed after the intravenous administration of mag-nifest 0.2 ml/kg body weight in indicated cases.
2.3. Image analysis
The CT and MR images were reviewed by two radiologists forinterpretation. They were classified as normal and abnormal,with attempt to reach to a histopathologic diagnosis.
Fig. 8 Hypoxic ischemia. Non enhanced CT shows diffuse bilateral h
demarcation and sparing of thalami.
3. Results
Of the 181 patients included in the study, abnormalities weredetected in 132 patients (73%) while normal brain images were
found in 49 patients (27%).Of the 74 patients underwent CT only, abnormalities
detected in 54 patients (73%) while 20 patients (27%) were nor-
mal and they did not undergo MRI. Of the 89 patients under-went MRI only, abnormalities detected in 66 patients (74%)while 23 patients (26%) were normal. Of the 18 patients
underwent CT and MRI, abnormalities detected in 12 patient(67%) while 6 patients (33%) were normal (Table 1).
In descending order of frequency, the abnormalities thatwas detected on either CT or MRI in the 132 patients was as
follows: cortical malformation disorders in 50 patients (37.9%), vascular lesions in 22 patients (16.6%), phakomatoses in20 patients (15%), infective and inflammatory lesions in 15
patients (11.4%), white matter disorders in 13 patients
ypodensity of cerebral hemispheres with loss of gray–white matter
Fig. 9 AVM. Axial T1 pre contrast (A), axial T1 post contrast (B), axial T2 (C) and coronal and sagittal T1 post contrast (D) showing
Lt parietal parasagittal AVM.
Assessment of the diagnostic reliability of brain CT and MRI 1133
(9.8%), encephalomalacia in 8 patients (6%) and mesial tem-poral sclerosis in 4 patients (3.3%).
Of the 50 patients with cortical malformation disorders;FCD was found in 11 patients, MRI only was done for 9patients while MRI and CT were done for 2 patients (none
was diagnosed on CT and all of them were diagnosed onMRI) (Fig. 1); schizencephaly was found in 9 patients, 4 wereunderwent CT only (3 open lip and 1 closed lip), 4 were under-went MRI only (2 open lip and 2 closed lip) and 1 patient had
CT and MRI and was diagnosed on both as open lip (Fig. 2);holoprosencephaly was found in 7 patients, CT only was donefor 3 (1 was alobar and 2 were semilobar), MRI only was done
for 3 (2 were semilobar and 1 was lobar) and CT and MRIwere done for 1 patient (diagnosed as semilobar on CTand MRI) (Fig. 3); heterotopia was found in 6 patients, 4
had MRI only and were diagnosed as nodular heterotopia, 2had CT and MRI (1 was diagnosed as subependymal hetero-topia on CT and MRI while one was diagnosed as nodular
heterotopia on MRI only and was not evident on CT)(Fig. 4); hemimegalencephaly was found on 5 patients, all of
them were underwent MRI only; pachygyria was found in 5patients and was focal on all, 2 had CT only and 3 had MRI
only (Fig. 5); polymicrogyria was found in 4 patients andwas focal in all of them, 3 had MRI only and 1 had bothCT and MRI and it was evident on both CT and MRI
(Fig. 6); bilateral underdeveloped operculum was found in 3patients all were underwent CT only (Fig. 7).
Vascular lesions were diagnosed in 22 patients; hypoxicischemic changes were found in 9 patients, 5 had CT only
and 4 had MRI only (Fig. 8); AVM was found in 4 patientsand was parenchymal in all cases, 2 were underwent CT onlyand 2 were underwent MRI only (Fig. 9); multifocal ischemia
due to vasculitis was found in 3 patients who were underwentMRI only (Fig. 10) and the diagnosis was supported by theclinical history; PVL was found in 3 patients, 2 had CT only
and 1 had MRI only (Fig. 11); hydranencephaly was found in3 patients who were underwent CT only (Fig. 12).
Phakomatoses were diagnosed in 20 patients; TS was found
in 14 patients, all of them were underwent CT only and theyhad cortical and subependymal calcified tubers with two of
Fig. 10 Multifocal ischemia in patient with nephrotic syndrome. Axial FLAIR (A), T1 (B), T2 (C) and DWI (D) showing bilateral
multifocal cortical ischemia.
Fig. 11 Periventricular leukomalacia. Non enhanced CT shows bilateral foci of PVL with reduced thickness of the white matter and mild
dilated ventricles posteriorly.
1134 M.H. Alam-Eldeen, N.M.A. Hasan
them had giant cell astrocytoma (Fig. 13); Sturge–Weber syn-drome was found in 6 patients, 2 had CT only, 3 had MRIonly, 1 had CT and MRI and was evident on both (Fig. 14).
Infective or inflammatory lesions were diagnosed in 15patients; congenital CMV was found in 7 patients, all of themwere underwent CT only and show diffuse cerebral atrophy,
ventriculomegaly and periventricular calcification (Fig. 15);
encephalitis was found in 6 patients, all of them were under-went MRI only and the diagnosis was supported by the clinicalhistory (Fig. 16), TB was found in 2 patients, one had CT only
and one had MRI only (Fig. 17) and the diagnosis was sup-ported by clinical history and laboratory findings.
White matter disorders were diagnosed in 13 patients;
diffuse WM dysmyelinating disorder was found in 6 patients
Fig. 12 Hydranencephaly. Non enhanced CT shows complete bilateral absence of cerebral parenchymas which are replaced by CSF.
Fig. 13 Tuberous sclerosis. (A and B) Non enhanced CT shows multiple calcified subependymal and cortical tubers. (C) Non enhanced
CT in a different patient with TS and Lt sided giant cell astrocytoma.
Fig. 14 Sturge Weber syndrome. Non enhanced CT (A), axial T2 (B) and axial FLAIR (V) clearly showing the characteristic cortical
calcification on CT and the gliosis and atrophy on MRI.
Assessment of the diagnostic reliability of brain CT and MRI 1135
and all had MRI only, ADEM was found in 3 patients and allhad MRI only (Fig. 18), ADL was found on 2 patients, 1 hadCT only and 1 had MRI only (Fig. 19), Alexander’s disease
was found in 2 patients and both had MRI only (Fig. 20).
Encephalomalacia was found in 8 patients, 5 were under-went CT only and 3 were underwent MRI only (5 were multi-focal with history of hypoxic ischemia and 3 were due to old
infarctions) (Fig. 21). Mesial temporal sclerosis was found in
Fig. 15 Congenital CMV infection. Non enhanced CT shows cerebral atrophy, ventriculomegaly and bilateral periventricular
calcification.
Fig. 16 Encephalitis. Axial FLAIR (A), T2 (B), DWI (C) and T1
post contrast (D) showing encephalitis along Rt fronto-parietal
lobes. Another smaller area also noted on Lt side.
1136 M.H. Alam-Eldeen, N.M.A. Hasan
4 patients, all of them had CT and MRI and were diagnosed
on MRI while they were not evident on CT (Fig. 22) (Tables2–4).
4. Discussion
Presence of seizures constitutes a symptom of an underlyingcentral nervous system disorder that requires thorough investi-
gations and management plan. The etiological factorsdiffer markedly in children (6). Congenital infection andperinatal ischemia are diagnostic considerations in neonates.
In infants below 1.5 years, mesial temporal sclerosis is not a
consideration. After 1.5 years, the yield of structural pathologyis highest (1).
Neuroimaging plays an essential role in noninvasively local-
izing epileptogenic foci in the pediatric population (1). CT candetect many structural abnormalities and offers some advan-tages with regard to identifying calcification as found incongenital infections, calcified tubers in TS and gyral calcifica-
tion in Sturge–Weber syndrome. In our study, 74 patientsunderwent CT only, lesions were identified in 54 patients(73%), 12 patients had cortical malformations disorders, 12
had vascular lesions, 16 had phakomatoses, 8 had infectivelesions, 1 had WM disease and 5 had encephalomalacia.
Being much more sensitive than CT, MRI is the technique
of choice in identifying the underlying cause in epilepsy (7,8).This is related to its high resolution structural imaging, supe-rior soft tissue contrast and multiplanar imaging capability
which allow visualization of epileptogenic substrates withgreater sensitivity and accuracy (9). In our study, 89 patientswere underwent MRI only, lesions were identified in 66patients (74%), cortical malformations disorders were found
in 31 patients, vascular lesions in 10, phakomatoses in 3, infec-tive lesions in 7, WM diseases in 12 and encephalomalacia in 3.
MRI has superiority on CT in the diagnosis of some causes
of epilepsy specially in patients with mesial temporal sclerosisand small FCD that will not be identified by CT (3,8). In ourstudy, 18 patients were underwent both CT and MRI, lesions
were identified in 12 patients (67%), 2 cases of FCD were diag-nosed by MRI and not identified on CT, one case diagnosed asopen lip schizencephaly by CT and MRI, one case diagnosedas semilobar holoprosencephaly by CT and MRI, 2 cases of
gray matter heterotopia; one was diagnosed as subependymalheterotopia on CT and MRI while the other one was diag-nosed as subcortical nodular heterotopia on MRI and was
not evident on CT, one case was diagnosed as focal polymicr-ogyria by CT and MRI, one case diagnosed as Sturge–Webersyndrome by CT and MRI with the calcification was evident
on CT, and 4 cases were diagnosed as mesial temporal sclerosisby MRI that were not detected by CT.
However, some, but not all, causes of pediatric epilepsy are
not detectable with conventional MRI (4,10). In our study, nolesions detected in 23 patients (26%) from the 89 patients
Fig. 17 Tuberculosis. Post contrast CT showing extra and intra-axial enhancing nodular lesions.
Table 2 Etiological entities diagnosed by CT and MRI.
Etiology No (%) On CT On MRI CT & MRI
I. Cortical malformation disorders 50 (37.9%)
A. Focal cortical dysplasia 11 – 9 2
B. Schizencephaly 9 4 4 1
C. Holoprosencephaly 7 3 3 1
D. Heterotopia 6 – 4 2
E. Hemimegalencephaly 5 – 5 –
F. Pachygyria 5 2 3 –
G. Polymicrogyria 4 – 3 1
H. Bilateral underdeveloped operculum 3 3 – –
II. Vascular 22 (16.6%)
A. Hypoxic ischemia 9 5 4 –
B. AVM 4 2 2 –
C. Vasculitis 3 – 3 –
D. Periventricular leukomalacia 3 2 1 –
E. Hydranencephaly 3 3 – –
III. Phakomatoses 20 (15%)
A. Tuberous sclerosis 14 14 – –
B. Sturge Weber syndrome 6 2 3 1
IV. Infective/inflammatory 15 (11.4%)
A. Congenital CMV 7 7 – –
B. Encephalitis 6 – 6 –
C. TB 2 1 1 –
V. White Matter disorders 13 (9.8%)
A. Diffuse WM disease 6 – 6 –
B. ADEM 3 – 3 –
C. Adrenoleukodystrophy 2 1 1 –
D. Alexander’s disease 2 – 2 –
VI. Encephalomalacia 8 (6%) 5 3 –
VII. Mesial temporal sclerosis 4 (3.3%) – – 4
Total 132 (100) 54 66 12
Assessment of the diagnostic reliability of brain CT and MRI 1137
underwent MRI only and no lesions detected in 6 patients(33%) from the 18 patients underwent both CT and MRI.
Cortical malformation disorders group is one of the com-monest causes for epilepsy in infants and children, accountingfor 10–50% of the pediatric epilepsy cases (11–13). It was
found in 50 patients (37.9%) in our study. It is important torecognize that in many lesions, CT changes are similar to thosefound in MRI studies (21). In our study, one case was
diagnosed as open lip schizencephaly on CT and MRI, onecase was diagnosed as semilobar holoprosencephaly on CT
and MRI, one case was diagnosed as subependymal hetero-topia on CT and MRI and one case was diagnosed as focalpolymicrogyria on CT and MRI.
CT scan however can fail to make the diagnosis in morethan 30% of affected patients (14). MRI allowed increasedrecognition and more accurate diagnosis (14,15). In our study,
Fig. 18 ADEM. Axial T2 (A) and FLAIR (B) showing bilateral multiple discrete patches of bright signals affecting gray and white
matter.
Fig. 19 Adrenoleukodystrophy. Non enhanced CT showing bilateral almost symmetrical white matter hypodensity at posterior parietal
lobes.
Fig. 20 Alexander’s disease. Axial T2 (A) and FLAIR (B) showing bilateral almost symmetrical white matter hyperintensity at a fronto-
parietal distribution.
1138 M.H. Alam-Eldeen, N.M.A. Hasan
Fig. 21 Encephalomalacia. (A) Non enhanced CT shows bilat-
eral multifocal areas of encephalomalacia with cerebral atrophy.
(B) Non enhanced CT of different patient with Lt fronto-parietal
lobes encephalomalacia.
Fig. 22 Mesial temporal sclerosis. Coronal T2 shows abnormal
bright signal at Rt hippocampus with dilated Rt temporal horn.
Table 3 Comparison of the diagnostic effectiveness between
CT and MRI in the 12 patients who were underwent both CT
and MRI and had shown +ve findings.
Etiology No +ve on CT +ve on MRI
Focal cortical dysplasia 2 0 2
Schizencephaly 1 1 1
Holoprosencephaly 1 1 1
Heterotopia 2 1 2
Polymicrogyria 1 1 1
Sturge Weber syndrome 1 1 1
Mesial temporal sclerosis 4 – 4
Total 12 5 12
Assessment of the diagnostic reliability of brain CT and MRI 1139
2 cases of FCD were diagnosed by MRI while they were notevident on CT, one case of subcortical nodular heterotopia
was diagnosed by MRI while it was not evident on CT.FCD is one of the most common forms of focal develop-
mental disorders constituting approximately 25% of patients
(13,16). On MRI, it is seen as focal cortical thickening that
Table 4 Categories of specific disease processes diagnosed by CT a
Etiology No Category 1
Schizencephaly 9 Open (6)
Holoprosencephaly 7 Alobar (1)
Heterotopia 6 Nodular (5)
ATS 14 Giant cell astrocyto
Encephalomalacia 8 Post hypoxia (5)
is hyperintense in T2 and FLAIR and hypointense in T1.The abnormal signal may extend to the underlying WM with
blurring of the gray–white matter interface. It is usually foundin frontal or temporal lobes, although it can occur in any loca-tion (10,17). It is infrequently associated with edema or gliosis
(18). In our study, from the 50 patients with cortical malforma-tion disorders, FCD was found in 11 patients (22%), all ofthem were in the frontal lobe and were associated with mild
blurring of underlying gray–white matter interface. No edemaor gliosis was found.
In schizencephaly, adjacent areas of polymicrogyria orpachygyria may be seen (14). It can be unilateral or bilateral
and tends to involve the insular, precentral and postcentralregions (13). Closed lip schizencephaly is characterized bythe presence of an indentation in the ependymal surface, the
so-called nipple sign (14). In our study, 3 cases were diagnosedas closed lip schizencephaly and all showed the nipple sign. Ofthe 6 cases diagnosed as open lip schizencephaly, one case was
detected in the precentral region and spared the insula.In holoprosencephaly, it is found that the sylvian fissures
were found more anterior than usual with respect to the frontof the brain (19). This is in agreement with our results as the
sylvian fissures were present in an abnormal anterior location.The most common type of heterotopic gray matter is the
subependymal nodular type. It can be isolated or associated
with other anomalies of the brain (20). It can be associatedwith mesial temporal sclerosis (21). Mild ventricular dilationmight be seen (18,22). Single case was diagnosed as subependy-
mal heterotopia in our study and it was associated with mildventricular dilatation but no other anomalies were detected.
In hemimegalencephaly, there is unilateral focal or diffuse
dysplastic cortical thickening. Commonly, there is indistinctgray–white matter junction, ipsilateral WM myelination disor-ders, heterotopias, lissencephaly and polymicrogyria (10,23).In the 5 cases of hemimegalencephaly in our study, dysplastic
cortex of the contralateral cerebral hemisphere was detected inone case.
nd or MRI.
Category 2 Category 3
Closed (3)
Semilobar (5) Lobar (1)
Subependymal (1)
ma (2)
Post infarction (3)
1140 M.H. Alam-Eldeen, N.M.A. Hasan
Pachygyria or incomplete lissencephaly represents a fewlarge, thick and smooth gyri, with shallow sulci. It can be uni-lateral or bilateral, focal or diffuse (24,25). In the 5 cases of
pachygyria in our study, it was focal in all cases and was accu-rately diagnosed by CT in 2 cases and by MRI in 3 cases.
Polymicrogyria may be unilateral or bilateral, frontal, fron-
toparietal, perisylvian, parieto-occipital or generalized (26,27).In localized form, the remaining cortical gray matter may beabnormal (28). The 4 patients with polymicrogyria in our
study were of unilateral frontoparietal pattern and were notassociated with other cortical abnormality. Poly-microgyriamay occur adjacent to the borders of schizencephaly (14). Inthe 9 cases with schizencephaly in our study, there was no asso-
ciated polymicrogyria.In bilateral underdeveloped operculum, CT shows symmet-
rical bilateral enlarged sylvian fissures, underdevelopment of
the operculum, exposed insula, with or without normallyformed insular gyri (29–31). The 3 cases of bilateral underde-veloped operculum in our study showed bilateral enlarged syl-
vian fissures, underdeveloped operculum and exposed insula.Normal gyral pattern was seen in 2 cases while polymicrogyriapattern was seen in one case.
In periventricular leukomalacia, there are hyperintense fociin the periventricular WM on T2 and FLAIR associated withreduced thickness predominantly in the periatrial regions withcompensatory focal ventricular enlargement (32). Our 3 cases;
2 of them diagnosed on CT; showed the typical describedpattern.
The best diagnostic clue in tuberous sclerosis is calcified
subependymal nodules and subependymal giant cell astrocy-toma. Cortical, subcortical tubers are present in 70–95%, witha predilection of the frontal and parietal lobes (1,33). Calcified
subependymal and cortical tubers were found in the 14 cases oftuberous sclerosis in our study and subependymal giant cellastrocytoma was found in 2 cases.
On CT, Sturge–Weber syndrome has characteristic gyri-form calcifications, more commonly affect the parieto-occipital areas, with underlying focal brain atrophy.Leptomeningeal enhancement is well seen on MRI and the
areas of gliosis are well seen on T2 and FLAIR (10,34). Inthe 6 cases diagnosed in our study, the calcification was evidentby CT, gliosis was evident by MRI and focal atrophy was evi-
dent by CT and MRI.CT is highly sensitive for the depiction and localization of
calcification in cases of congenital CMV infection.
Calcification is commonly thick and chunky, commonly seenin periventricular regions but may occur in basal ganglia andbrain parenchyma. Congenital CMV infection is also charac-terized by cerebral atrophy and ventriculomegaly (35). A vari-
ety of associated migrational abnormalities like lissencephaly,pachygyria, and polymicrogyria have been reported (36). The7 cases diagnosed as congenital CMV infection in our study
were underwent CT and showed typical thick periventricularcalcification, cerebral atrophy and ventriculomegaly with noany associated anomalies.
Adrenoleukodystrophy is characterized by symmetric WMdemyelination in the peritrigonal regions that extends acrossthe corpus callosum splenium. It may then spread outward
and cephalad as a confluent lesion. The subcortical WM is rel-atively spared in the early stage (37). The 2 cases in our studyhad a symmetrical peritrigonal distribution.
Alexander disease has a predilection for the frontal lobesWM early in its course then progresses posteriorly to the pari-etal WM and internal and external capsules. The subcortical
WM is affected early in the disease course (37). The 2 casesin our study had an almost symmetrical bilateral fronto-parietal distribution.
The major findings of mesial temporal sclerosis on MRI arehippocampal atrophy, abnormal T2 hyperintense signal inmesial temporal region and dilatation of the ipsilateral tempo-
ral horn. Secondary findings include loss of internal architec-ture, atrophy of the ipsilateral fornix and mammillary body,and temporal lobe volume loss (1,10). The 4 cases of mesialtemporal sclerosis in our study were diagnosed on MRI and
not on CT, they showed abnormal hyperintense signal onmesial temporal region with mild dilatation of adjacent tempo-ral horn.
5. Conclusion
Seizure disorders are among the most frequent neurologic
problems that occur in childhood. Neuroimaging plays anessential role in noninvasively localizing epileptogenic foci.MRI is the technique of choice and is superior to CT in iden-
tifying underlying cause. However, CT is more widely avail-able than MRI, less expensive, and can diagnose manyabnormalities. So, CT can serve as a screening modality and
MRI would be performed to define abnormalities found onCT or in �ve CT studies.
5.1. Limitations
Our study has limitations. First, CT and MRI were not done inall patients, so the precise sensitivity of CT and MRI in diag-nosis could not be gained. Second, in the patients who under-
went CT only and diagnosed as normal, MRI was notperformed to confirm absence of lesions.
Conflict of Interest
We have no conflict of interest to declare.
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