SPECT and MRI findings in a case of extensive neuronal migration disorder

We report a 20-year-old male with epilepsy, mild mental retardation, growth asymmetry, and MRI and SPECT features of unilateral subcortical ectopic cortex. The neurological examination showed mild growth asymmetry, hemiparesis and hemihypoesthesia and pyramidal signs on the left side. EEG showed focal abnormality in the right frontotemporal region. MRI revealed pachygyria and severe heterotopia associated with some abnormalities of ventricles and cerebellum on the right. Cortical responses were absent on stimulation of the left median and tibial nerves. Central motor conduction time from cortex to left upper extremity was prolonged in magnetic stimulation test. SPECT using 99 mTc-HMPAO revealed increased perfusion of the right subcortical region as compared with those of overlying cortical mantle and opposite hemisphere. To our knowledge, there has been no report documenting such a large and extensive subcortical ectopic cortex which appears as a mass distorting and shifting the middle structure in an adult, such as in our case.     

So-called 'cryptogenic' partial seizures resulting from a subtle cortical dysgenesis due to a doublecortin gene mutation.

We report the case of a female suffering from resistant partial seizures, which were related to 'cryptogenic' epilepsy, as the cerebral cortex was considered normal on the initial MRI images. As her son is mentally retarded and has a pachygyria, the doublecortin gene, usually involved in band heterotopia or lissencephaly, was screened for mutations. A missense mutation was identified, shared by both the son and his mother, and a subtle discontinuous subcortical heterotopia was subsequently detected on the mother's MRI. The pathophysiology of epilepsy in this woman is discussed in the light of the role of doublecortin, not only in neuronal migration, but also in axonal growth and dendritic connectivity.     

Neuronal migration disorders, genetics, and epileptogenesis

Several malformation syndromes with abnormal cortical development have been recognized. Specific causative gene defects and characteristic electroclinical patterns have been identified for some. X-linked periventricular nodular heterotopia is mainly seen in female patients and is often associated with focal epilepsy. FLN1 mutations have been reported in all familial cases and in about 25% of sporadic patients. A rare recessive form of periventricular nodular heterotopia owing to ARGEF2 gene mutations has also been reported in children with microcephaly, severe delay, and early-onset seizures. Lissencephaly-pachygyria and subcortical band heterotopia represent a malformative spectrum resulting from mutations of either the LIS1 or the DCX (XLIS) gene. LIS1 mutations cause a more severe malformation posteriorly. Most children have severe developmental delay and infantile spasms, but milder phenotypes are on record, including posterior subcortical band heterotopia owing to mosaic mutations of LIS1. DCX mutations usually cause anteriorly predominant lissencephaly in male patients and subcortical band heterotopia in female patients. Mutations of the coding region of DCX were found in all reported pedigrees and in about 50% of sporadic female patients with subcortical band heterotopia. Mutations of XLIS have also been found in male patients with anterior subcortical band heterotopia and in female patients with normal brain magnetic resonance imaging. The thickness of the band and the severity of pachygyria correlate with the likelihood of developing severe epilepsy. Autosomal recessive lissencephaly with cerebellar hypoplasia, accompanied by severe delay, hypotonia, and seizures, has been associated with mutations of the reelin (RELN) gene. X-linked lissencephaly with corpus callosum agenesis and ambiguous genitalia in genotypic males is associated with mutations of the ARX gene. Affected boys have severe delay and infantile spasms with suppression-burst electroencephalograms. Early death is frequent. Carrier female patients can have isolated corpus callosum agenesis. Schizencephaly has a wide anatomoclinical spectrum, including focal epilepsy in most patients. Familial occurrence is rare. Initial reports of heterozygous mutations in the EMX2 gene have not been confirmed. Among several syndromes featuring polymicrogyria, bilateral perisylvian polymicrogyria shows genetic heterogeneity, including linkage to chromosome Xq28 in some pedigrees, autosomal dominant or recessive inheritance in others, and an association with chromosome 22q11.2 deletion in some patients. About 65% of patients have severe epilepsy. Recessive bilateral frontoparietal polymicrogyria has been associated with mutations of the GPR56 gene.     

Treatment of seizures in subcortical laminar heterotopia with corpus callosotomy and lamotrigine.

Focal and generalized cortical dysgeneses are sometimes seen on the magnetic resonance images (MRI) of patients with epilepsy. Subcortical laminar heterotopia are bilateral collections of gray matter in the centrum semiovale that resemble a band or "double cortex" on MRI. We studied one male and two female patients with subcortical laminar heterotopia who had moderate to severe developmental delay, early-onset epilepsy, and medically refractory seizures. Atonic, atypical absence, tonic, myoclonic, complex partial, and generalized tonic-clonic seizures were recorded. Interictal and ictal electroencephalographic patterns were generalized and, less commonly, multifocal. Two years after corpus callosotomy, one patient was free of generalized tonic-clonic and atonic seizures, but the other patient who had undergone callosotomy had no significant reduction in seizure frequency. With lamotrigine treatment, the patient who had not had surgery had complete cessation of monthly episodes of status epilepticus and a dramatic reduction of generalized tonic-clonic seizures, and the other patient who received lamotrigine had a 50% reduction of her atonic seizures. In patients with subcortical laminar heterotopia, atonic and generalized tonic-clonic seizures can be substantially reduced or eliminated by corpus callosotomy or treatment with lamotrigine.     

X-linked lissencephaly with absent corpus callosum and ambiguous genitalia (XLAG): clinical, magnetic resonance imaging, and neuropathological findings

X-linked lissencephaly with absent corpus callosum and ambiguous genitalia is a newly recognized syndrome responsible for a severe neurological disorder of neonatal onset in boys. Based on the observations of 3 new cases, we confirm the phenotype in affected boys, describe additional MRI findings, report the neuropathological data, and show that carrier females may exhibit neurological and magnetic resonance imaging abnormalities. In affected boys, consistent clinical features of X-linked lissencephaly with absent corpus callosum and ambiguous genitalia are intractable epilepsy of neonatal onset, severe hypotonia, poor responsiveness, genital abnormalities, and early death. On magnetic resonance imaging, a gyration defect consisting of anterior pachygyria and posterior agyria with a moderately thickened brain cortex, dysplastic basal ganglia and complete agenesis of the corpus callosum are consistently found. Neuropathological examination of the brain shows a trilayered cortex containing exclusively pyramidal neurons, a neuronal migration defect, a disorganization of the basal ganglia, and gliotic and spongy white matter. Finally, females related to affected boys may have mental retardation and epilepsy, and they often display agenesis of the corpus callosum. These findings expand the phenotype of X-linked lissencephaly with absent corpus callosum and ambiguous genitalia, may help in the detection of carrier females in affected families, and give arguments for a semidominant X-linked mode of inheritance.     

Genetic Malformations of the Cerebral Cortex and Epilepsy

Summary:  We reviewed the epileptogenic cortical malformations for which a causative gene has been cloned or a linkage obtained. X-linked bilateral periventricular nodular heterotopia (BPNH) consists of typical BPNH with epilepsy in female patients and prenatal lethality in most males. About 90% of patients have focal epilepsy. Filamin A mutations have been reported in all families and in ∼20% of sporadic patients. A rare recessive form of BPNH also has been reported. Most cases of lissencephaly–pachygyria are caused by mutations of LIS1 and XLIS genes. LIS1 mutations cause a more severe malformation posteriorly. Most children have isolated lissencephaly, with severe developmental delay and infantile spasms, but milder phenotypes have been recorded. XLIS usually causes anteriorly predominant lissencephaly in male patients and subcortical band heterotopia (SBH) in female patients. Thickness of the band and severity of pachygyria correlate with the likelihood of developing Lennox–Gastaut syndrome. Mutations of the coding region of XLIS are found in all reported pedigrees and in 50% of sporadic female patients with SBH. Autosomal recessive lissencephaly with cerebellar hypoplasia; accompanied by severe delay, hypotonia, and seizures, has been associated with mutations of the RELN gene. Schizencephaly has a wide anatomoclinical spectrum, including focal epilepsy in most patients. Familial occurrence is rare. Initial reports of heterozygous mutations in the EMX2 gene need confirmation. Among several syndromes featuring polymicrogyria, bilateral perisylvian polymicrogyria shows genetic heterogeneity, including linkage to Xq28 in some pedigrees, autosomal recessive inheritance in others, and association with 22q11.2 deletion in some patients. About 65% of patients have severe epilepsy, often Lennox–Gastaut syndrome. Recessive bilateral frontal polymicrogyria has been linked to chromosome 16q12.2–21.     

Nonsyndromic mental retardation and cryptogenic epilepsy in women with doublecortin gene mutations

DCX mutations cause mental retardation in male subjects with lissencephalypachygyria and in female subjects with subcortical band heterotopia (SBH). We observed four families in which carrier women had normal brain magnetic resonance imaging (MRI) and mild mental retardation, with or without epilepsy. Affected male subjects had SBH or pachygyria-SBH. In two families, the phenotype was mild in both genders. In the first family, we found a tyr138his mutation that is predicted to result in abnormal folding in the small hinge region. In the second family, we found an arg178cys mutation at the initial portion of R2, in the putative beta-sheet structure. Carrier female subjects with normal MRI showed no somatic mosaicism or altered X-inactivation in lymphocytes, suggesting a correlation between mild mutations and phenotypes. In the two other families, with severely affected boys, we found arg76ser and arg56gly mutations within the R1 region that are predicted to affect DCX folding, severely modifying its activity. Both carrier mothers showed skewed X-inactivation, possibly explaining their mild phenotypes. Missense DCX mutations may manifest as non-syndromic mental retardation with cryptogenic epilepsy in female subjects and SBH in boys. Mutation analysis in mothers of affected children is mandatory, even when brain MRI is normal.     

Genes that regulate neuronal migration in the cerebral cortex.

Malformations of cortical development are increasingly recognized as causes of mental retardation and epilepsy. However, little is known about the molecular and biochemical signals that control the proliferation, migration, and organization of the cells involved in normal cerebral cortical development. Analysis of genes required for cortical development will help elucidate the pathogenesis of some epilepsies. In humans, two striking examples of abnormal cortical development, with varying degrees of epilepsy and mental retardation, are 'double cortex' and lissencephaly. Double cortex (DC), also known as subcortical band heterotopia, shows an abnormal band of neurons in the white matter underlying a relatively normal cortex. In pedigrees, DC often occurs in females, whereas affected males show more severe lissencephaly (XLIS), i.e. an abnormally thick cortex with decreased or absent surface convolutions. We and others have identified a novel brain specific gene, doublecortin, that is mutated in Double Cortex/X-linked lissencephaly (DC/XLIS) patients. Although the cellular function of doublecortin (DCX) is unknown, sequence analysis reveals a cytoplasmic protein with potential MAP kinase phosphorylation sites, as well as a site that is likely to be phosphorylated by c-Abl, suggesting that doublecortin functions as an intracellular signaling molecule critical for the migration of developing neurons. Interestingly, the scrambler mouse mutant demonstrates abnormal lamination with some similarity to lissencephaly and reflects a mutation in the murine homolog of the Drosophila disabled gene, mdab1, which binds c-Abl. Although a direct interaction between doublecortin and mDab1 has not been demonstrated, it is plausible that these two proteins may be part of a common signaling pathway. Therefore, abnormalities in signal transduction may be an underlying mechanism for the neuronal migration defects in DC/XLIS and the scrambler mouse, but further research is necessary to determine how such abnormalities give rise to cortical malformations and epilepsy.     

Gray matter heterotopia

Gray matter heterotopia are common malformations of cortical development. From a clinical perspective, affected patients are best divided into three groups: subependymal, subcortical, and band heterotopia (also called double cortex). Symptomatic women with subependymal heterotopia typically present with partial epilepsy during the second decade of life; development and neurologic examinations up to that point are typically normal. Symptoms in men with subependymal heterotopia vary, depending on whether they have the X-linked or autosomal form. Men with the X-linked form more commonly have associated CNS and visceral anomalies; their development is typically abnormal. Symptomatic men with the autosomal variety have clinical courses similar to symptomatic women. Both men and women with subcortical heterotopia typically have congenital fixed neurologic deficits and develop partial epilepsy during the second half of the first decade of life. The more extensive the subcortical heterotopia, the greater the deficit; bilateral heterotopia are almost invariably associated with severe developmental delay or mental retardation. In general, band heterotopia are seen exclusively in women; men with a mutation of the related gene (called XLIS or DCX) usually die in utero or have a much more severe brain anomaly. Symptoms in affected women vary from normal to severe developmental delay or mental retardation; the severity of the syndrome is related to the thickness of the band of arrested neurons. Nearly all affected patients that come to medical attention have epilepsy, with partial complex and atypical absence epilepsy being the most common syndromes. Some of the more severely affected patients develop attacks.     

Functional MRI in double cortex: functionality of heterotopia

ARTICLE ABSTRACT: A 12-year-old boy with epilepsy and subcortical laminar heterotopia (band heterotopia) underwent a functional MRI protocol to study voluntary motor activity in the hand. Finger tapping produced an activation of a contralateral limited and focused frontal cortical area both in the subcortical band heterotopia and the overlying cortex. Despite its epileptogenic activity, subcortical laminar heterotopia seems to be responsible for part of the functional activity of the brain. This has to be pointed out for epilepsy surgery resecting cortical dysplasia.     

Magnetic Resonance Imaging in Developmental Disorders of the Cerebral Cortex

Summary: Developmental disorders of the neocortex are commonly associated with epilepsy. The development of magnetic resonance imaging (MRI) has advanced our understanding of these disorders by permitting accurate recognition and clinical correlation during life. These disorders have multiple etiologies and are dependent on the time of injury to the developing nervous system. MRI has permitted the classification of these malformations in three major groups: generalized disorders, unilateral hemispheric, and focal disorders. Generalized disorders include lissencephaly, pachygyria, band heterotopia, and subependymal heterotopias. Hemimegalencephaly comprised the unilateral disorder. Focal lesions include focal cortical dysplasia, polymicrogyria, schizencephaly, and focal subcortical heterotopias. The information provided by MRI, in conjunction with the clinicoelectrographic features, is extremely important in the recognition of these syndromes and for the appropriate medical and surgical management of those patients with epilepsy.     

The evolving MR imaging appearance of lissencephaly: a case report

MR imaging of a patient with epilepsy and psychomotor retardation at 5 months revealed parieto-occipital pachygyria with almost normal cortical appearance and thickness in the frontal region; this appearance evolved into diffuse pachygyria at 7 years. The change of the MR imaging findings may have resulted from myelination in the intracortical and subcortical fibers. It is important for clinicians to be aware of the longitudinal changes of the cerebral cortex in lissencephaly.     

Epileptogenic brain malformations: clinical presentation, malformative patterns and indications for genetic testing.

We review here those malformations of the cerebral cortex which are most often observed in epilepsy patients, for which a genetic basis has been elucidated or is suspected and give indications for genetic testing. There are three forms of lissencephaly (agyria-pachygyria) resulting from mutations of known genes, which can be distinguished because of their distinctive imaging features. They account for about 85% of all lissencephalies. Lissencephaly with posteriorly predominant gyral abnormality is caused by mutations of the LIS1 gene on chromosome 17. Anteriorly predominant lissencephaly in hemizygous males and subcortical band heterotopia (SBH) in heterozygous females are caused by mutations of the XLIS(or DCX) gene. Mutations of the coding region of XLIS were found in all reported pedigrees, and in most sporadic female patients with SBH. Missense mutations of both LIS1 and XLIS genes have been observed in some of the rare male patients with SBH. Autosomal recessive lissencephaly with cerebellar hypoplasia has been associated with mutations of the reelin gene. With few exceptions, children with lissencephaly have severe developmental delay and infantile spasms early in life. Patients with SBH have a mild to severe mental retardation with epilepsy of variable severity and type. X-linked bilateral periventricular nodular heterotopia (BPNH) consists of typical BPNH with focal epilepsy in females and prenatal lethality in males. About 88% of patients have focal epilepsy. Filamin A (FLNA) mutations have been reported in some families and in sporadic patients. Additional, possibly autosomal recessive gene(s) are likely to be involved in causing BPNH non-linked to FLN1. Tuberous sclerosis (TS) is a dominant disorder caused by mutations in at lest two genes, TSC1 and TSC2. 75% of cases are sporadic. Most patients with TS have epilepsy. Infantile spasms are a frequent early manifestation of TS. Schizencephaly (cleft brain) has a wide anatomo-clinical spectrum, including focal epilepsy in most patients. Familial occurrence is rare. Heterozygous mutations in the EMX2 gene have been reported in some patients. However, at present, there is no clear indication on the possible pattern of inheritance and on the practical usefulness that mutation detection in an individual with schizencephaly would carry in terms of genetic counselling. Amongst several syndromes featuring polymicrogyria, bilateral perisylvian polymicrogyria had familial occurrence on several occasions. Genetic heterogeneity is likely, including autosomal recessive, X-linked dominant, X-linked recessive inheritance and association to 22q11.2 deletions. FISH analysis for 22q11.2 is advisable in all patients with perisylvian polymicrogyria. Parents of an affected child with normal karyotype should be given up to a 25% recurrence risk.     

Genotype-phenotype correlation in lissencephaly and subcortical band heterotopia: the key questions answered

Lissencephaly and subcortical band heterotopia are closely related cortical malformations and are true disorders of neuronal migration. The genetic basis of approximately 70% of classic lissencephaly and 80% of typical subcortical band heterotopia is known. Most are due to abnormalities within the LIS1 or DCX genes, with abnormalities ranging from single basepair substitutions to contiguous gene deletions. Understanding the genetic basis of these disorders has led to the elucidation of the molecular and developmental mechanisms that are adversely affected. There is a robust correlation between many of the clinical aspects of lissencephaly or subcortical band heterotopia and the type and location of mutations in the affected gene. Using this knowledge, the clinician can predict with some accuracy which gene is likely to be affected based on the clinical and imaging features. This review answers some of the key questions regarding the genotype-phenotype correlation for lissencephaly and subcortical band heterotopia.     

Molecular Genetics of Neuronal Migration Disorders

Cortical malformations associated with defects in neuronal migration result in severe developmental consequences including intractable epilepsy and intellectual disability. Genetic causes of migration defects have been identified with the advent and widespread use of high-resolution MRI and genetic techniques. Thus, the full phenotypic range of these genetic disorders is becoming apparent. Genes that cause lissencephaly, pachygyria, subcortical band heterotopia, and periventricular nodular heterotopias have been defined. Many of these genes are involved in cytoskeletal regulation including the function of microtubules (LIS1, TUBA1A,TUBB3, and DCX) and of actin (FilaminA). Thus, the molecular pathways regulating neuronal migration including the cytoskeletal pathways appear to be defined by human mutation syndromes. Basic science, including cell biology and animal models of these disorders, has informed our understanding of the pathogenesis of neuronal migration disorders and further progress depends on the continued integration of the clinical and basic sciences.     

Late-onset epilepsy associated with regional brain cortical dysplasia.

RATIONALE: Cortical dysplasia (CD) designates a diverse group of malformations resulting from one or more abnormalities in the development of the cerebral cortex. The clinical manifestations of CD are varied, probably depending on the type, location and extent of CD. Epilepsy is a potential late manifestation of any cortical malformation. To our knowledge, however, no study has focused specifically on late onset of epilepsy in patients with localized CD. MATERIAL AND METHODS: We studied patients with localized CD confirmed by MRI. Patients were divided into 2 groups according to age at onset of epilepsy. Group 1 included patients in whom the first seizure occurred up to the age of 12 (early-onset group) and group 2 included patients in whom the first seizure occurred after the age of 12 (late-onset group). The two groups were compared with regard to the type of CD, clinical findings and EEG findings. RESULTS: Thirty-three patients with various forms of CD were studied. Onset of epilepsy occurred in adolescence or adulthood in 9 cases (37%). In 6 of these (17% overall), the first seizure occurred in adulthood. CD were posterior bilateral pachygyria (1), unilateral polymicrogyria (3), focal dysplasia with subcortical gray matter heterotopia (1), perisylvian bilateral polymicrogyria (1), bioccipital polymicrogyria (1) and bilateral nodular periventricular gray matter heterotopia (2). The incidence of neurological signs was lower in the late-onset group. Mental retardation was moderate or absent, thus allowing a fairly normal lifestyle. All patients presented partial seizures with a lower incidence of drug resistance (p < 0.01). EEG demonstrated preservation of background activity and absence of diffuse or multifocal abnormalities. CONCLUSION: Onset of epilepsy with various forms of CD may be delayed until adolescence or adulthood. Prognosis of epilepsy is usually more favorable in these cases.     

Familial periventricular heterotopia: missense and distal truncating mutations of the FLN1 gene

OBJECTIVE: To examine the clinical and MRI associations in bilateral periventricular nodular heterotopia (BPNH) (MIM # 300049) in two families segregating a missense mutation and a C-terminal deletion of the filamin 1(FLN1) gene. BACKGROUND: Classical familial BPNH, an X-linked dominant disorder, has been associated with protein truncations or splicing mutations, which tend to cluster at the N-terminal of the FLN1 protein, causing severe predicted loss of the protein function. The clinical syndrome includes symmetrical contiguous nodular heterotopia lining the lateral ventricles, epilepsy, mild retardation to normal cognitive level in affected females, and prenatal lethality in hemizygous boys. METHODS: Clinical examination, cognitive testing, MRI, mutation analysis (direct sequencing, single-strand conformation polymorphism) in seven patients from two families with BPNH. RESULTS: In Family 1, harboring an A > T change in exon 2 (E82V), heterotopic nodules were few, asymmetric, and noncontiguous. Five boys born from affected females had died unexpectedly early in life. In Family 2, harboring an 8 base pair deletion in exon 47 (7627_7634del TGTGCCCC), heterotopic nodules were thick and contiguous. Affected females in both families showed normal to borderline IQ and epilepsy. CONCLUSION: Missense mutations and distal truncations consistent with partial loss of FLN1 function cause familial BPNH with the classical clinical phenotype including epilepsy and mild mental retardation, if any. However, missense mutations have milder anatomic consequences in affected females and are possibly compatible with live birth but short survival of boys.     

Hemimegalencephalic appearance of normal hemisphere in unilateral heterotopia and absent corpus callosum

We report two patients with medically refractory epilepsy who had MRI evidence of unilateral subcortical nodular heterotopia and agenesis of corpus callosum. The abnormal hemisphere was small, whereas the contralateral normal hemisphere appeared large and crossed the midline. Although the normal hemisphere was initially mistaken for hemimegalencephaly, there were no typical radiological features. Moreover, the electroencephalographic abnormalities lateralized to the hemisphere showing heterotopia. Because contralateral hemispheric abnormalities like heterotopia, hemimicrencephaly, and hemimegalencephaly can occur in patients with hemispheric heterotopias, we emphasize the importance of careful scrutiny of the contralateral hemisphere in patients with unilateral heterotopia. Absence of typical radiological features and appropriately lateralized electroencephalographic abnormalities will help differentiate the two. This is crucial when planning epilepsy surgery.     

Neuronal migration, cerebral cortical development, and cerebral cortical anomalies

Cerebral cortical malformations are relatively common anomalies identified by neuroimaging and pathologically in patients with epilepsy and mental retardation. A disruption in neuronal migration during central nervous system development has been postulated as the pathogenesis for many of these disorders. Recently, the cell migration hypothesis has been proven accurate for lissencephaly, subcortical band heterotopia, and periventricular nodular heterotopia. Furthermore, advances in cellular and molecular biology have begun elucidating the fundamental mechanisms underlying these migration disorders. These data have resulted in redefining and recategorizing specific malformations based on their molecular genetic abnormality. In this review we shall discuss the current understanding of neuronal migration in the developing cerebral cortex, the evaluation of these patients, and attempt to describe the pathogenesis for several well-characterized human disorders of cell migration.     

Diffuse cortical dysplasia, or the 'double cortex' syndrome: the clinical and epileptic spectrum in 10 patients

Diffuse neuronal migration disorders associated with epilepsy can now be recognized by modern neuroimaging techniques, particularly high-resolution MRI. We report 10 patients with a recently described MRI picture of continuous or generalized band heterotopia underlying the cortical mantle, giving the appearance of a "double cortex." They have epilepsy, and almost all have mental retardation. The epileptic disorder varies in nature and degree of severity. Patients may present with infantile spasms, a Lennox-Gastaut syndrome, or other forms of secondary generalized or multifocal epilepsy. Response to medical treatment is variable. Callosotomy may lead to considerable reduction of drop attacks, present in 60%. Mental retardation is usually mild or moderate, and only rarely severe. It correlates with the type of epileptic syndrome, and is greater in patients with more disorganized cortex overlying the heterotopia. Recognition of this entity by MRI is important for appropriate diagnosis of the epileptic disorder, planning of therapeutic strategy, and prognosis.