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Schizencephaly

Schizencephaly is a rare congenital neuronal migration disorder characterized by full-thickness clefts in the cerebral hemispheres that extend from the pial surface to the of the , lined with heterotopic gray matter. These clefts, filled with , result from abnormal development during early , around the second to fourth months when neuronal migration occurs. The condition affects approximately 1.48 per 100,000 births worldwide, with no significant gender predilection, and is usually sporadic though familial cases linked to genetic mutations have been reported. The etiology of schizencephaly remains incompletely understood but involves a combination of genetic and environmental factors disrupting neuronal migration and differentiation. Potential causes include in utero exposure to teratogens such as warfarin or alcohol, viral infections like cytomegalovirus or Zika virus, and vascular insults such as middle cerebral artery strokes or hypoxia. Genetic associations have been identified with mutations in genes like COL4A1, EMX2, SHH, and SIX3, which play roles in cerebral cortical development, though most cases are not inherited. Schizencephaly is classified into two types: open-lip (Type II), where the cleft walls are separated and communicate directly with the ventricle, often leading to more severe outcomes; and closed-lip (Type I), where the walls are fused with intervening gray matter, typically resulting in milder symptoms. Clinically, schizencephaly manifests with a wide spectrum of neurological impairments depending on the location, extent, and bilaterality of the clefts. Common features include developmental delays, seizures (affecting 50-60% of cases), motor deficits such as or spastic quadriplegia, , and . Unilateral involvement may cause milder and minimal cognitive issues, while bilateral clefts often result in profound developmental impairment and are frequently associated with . is primarily achieved through (MRI), which reveals the characteristic gray matter-lined clefts, with prenatal detection possible via after 20 weeks of . Management focuses on and supportive care, as there is no cure for the underlying malformation. Antiepileptic medications control seizures in most patients, though about one-third with refractory may require surgical intervention such as . Multidisciplinary approaches include physical, occupational, and speech therapies to address motor and cognitive deficits, along with ventriculoperitoneal shunts for associated . Long-term outcomes vary, with early intervention improving , particularly in milder cases.

Signs and symptoms

Neurological manifestations

Schizencephaly frequently manifests with as the predominant neurological symptom, affecting approximately 50% to 80% of patients, with higher rates observed in bilateral cases. These seizures typically onset in infancy or , often presenting as focal seizures originating from the malformed perisylvian regions or as generalized tonic-clonic events, and may progress to refractory in more extensive clefts. The epileptogenic potential arises from the abnormal cortical architecture, including lining the cleft walls, which disrupts normal neuronal migration and connectivity. Motor impairments represent another core neurological feature, stemming directly from the clefts' interference with descending corticospinal tracts and associated pathways. In unilateral schizencephaly, contralateral is common, characterized by weakness and increased tone on the affected side, while bilateral involvement often leads to quadriparesis with more profound and impaired coordination, such as or . These deficits contribute to challenges in fine and , with severity correlating to the cleft's size and location, particularly when frontal or parietal lobes are involved. Developmental delays are invariably linked to the extent of disruption, affecting key milestones like independent walking, which may be postponed beyond age 2 years, and speech acquisition, often resulting in expressive language delays due to perisylvian clefts. Cognitive impairments span a spectrum from mild learning difficulties, such as specific deficits in executive function or , to severe with IQ below 50, predominantly in bilateral open-lip cases where widespread cortical malformation impairs higher-order processing. Sensory deficits, though less emphasized, can emerge when clefts involve specific regions like the , leading to homonymous cuts or hemianopia through disruption of optic radiations, as evidenced in isolated case reports of congenital field loss. These manifestations underscore the variable impact of schizencephaly on neural pathways, with unilateral forms generally sparing global sensory function more than bilateral ones.

Associated anomalies

Schizencephaly is frequently accompanied by , which arises due to obstruction of (CSF) flow by the cleft, resulting in ventricular enlargement and increased . In a large , ventricular dilation was observed in 60.5% of patients with schizencephaly, often necessitating ventriculoperitoneal shunt placement to manage symptoms. Midline brain anomalies are common associations, including (SOD), characterized by , abnormalities, and midline defects. SOD coexists with schizencephaly in approximately 69.1% of cases, contributing to visual impairments and endocrine dysfunctions. Absence of the is a common association in schizencephaly cases, often leading to altered ventricular morphology and potential neurodevelopmental impacts. Agenesis or of the is a common association, disrupting interhemispheric connectivity and correlating with more severe cognitive and motor deficits. The walls of the schizencephalic cleft are typically lined with polymicrogyric gray matter, representing a co-occurring neuronal disorder that exacerbates cortical dysfunction. This is a constant feature in many cases, influencing susceptibility and intellectual outcomes. Systemic malformations are rare but can occur in syndromic forms of schizencephaly. For instance, mutations in the COL4A1 gene, linked to familial schizencephaly, are associated with renal abnormalities such as hematuria or cysts alongside brain malformations. Cardiac issues, including , have been documented in exceptional cases tied to Vici syndrome, which features schizencephaly among its multisystem anomalies.

Etiology

Genetic factors

Schizencephaly is predominantly a sporadic condition, but genetic factors contribute to its etiology in a subset of cases through disruptions in early . The "schizencephaly" was first introduced by Yakovlev and Wadsworth in 1946, based on their studies of congenital clefts in the cerebral mantle lined by gray matter, highlighting the malformation's developmental origin. Mutations in the EMX2 gene, located on 10q26.11, have been implicated in schizencephaly . EMX2 encodes a homeodomain essential for telencephalon patterning and regionalization during early embryonic , particularly around gestational weeks 5 to 6 when the prosencephalon structures form. Heterozygous mutations in EMX2, often , disrupt this process, leading to abnormal neuronal migration and cleft formation in the cerebral hemispheres. Initial reports identified such mutations in patients with severe bilateral schizencephaly, though larger cohort studies indicate they are rare and not a major cause in most cases. Mutations in the SIX3 gene, situated on chromosome 2p21, also play a role by impairing development. SIX3 is a that regulates ventral patterning upstream of the sonic hedgehog (SHH) signaling pathway, and heterozygous loss-of-function mutations expand the clinical spectrum of to include schizencephaly features, such as gray matter-lined clefts. These mutations have been detected in isolated schizencephaly cases and fetuses, often or inherited, underscoring SIX3's influence on midline and hemispheric integrity during early gestation. Mutations in the SHH gene, which encodes the critical for and midline development, have been associated with schizencephaly, particularly in cases overlapping with spectrum disorders. Heterozygous mutations in SHH disrupt neuronal migration and cortical organization, contributing to cleft formation. Mutations in the COL4A1 gene, encoding a component of in basement membranes, are linked to schizencephaly through fetal intracranial hemorrhages and vascular disruptions. These mutations weaken cerebral vessels, leading to porencephaly-like clefts that histologically resemble schizencephaly, and have been identified in a substantial proportion of cases. Familial occurrences of schizencephaly are uncommon, with some exhibiting autosomal dominant inheritance. Examples include affected siblings harboring EMX2 mutations, suggesting incomplete penetrance and variable expressivity in hereditary forms. While most instances arise sporadically, these rare familial patterns indicate a heritable component in neuronal migration defects, potentially modified by environmental factors.

Environmental risk factors

Schizencephaly can arise from various prenatal environmental insults that disrupt normal brain development, particularly during the of neuronal and cerebral cleavage, which occurs around gestational weeks 4 to 8. These factors primarily involve disruptions to vascular integrity, infectious agents, or toxic exposures that lead to abnormal cleft formation in the cerebral hemispheres. Unlike genetic etiologies, environmental risks are external and non-heritable, though they may interact with genetic predispositions in susceptible individuals. Maternal infections during early pregnancy, especially with (CMV), have been strongly implicated in schizencephaly due to their interference with neuronal migration and cortical organization. CMV infection can cause vascular inflammation, leading to ischemic damage in the fetal brain that manifests as clefts lined by polymicrogyric gray matter. Similarly, exposure in the first trimester has been associated with schizencephaly-like malformations through direct neurotoxic effects on migrating neurons, as observed in congenital Zika syndrome cases where brain clefts and calcifications appear on imaging. Vascular events, such as in utero ischemic strokes, are another key environmental contributor, often resulting in porencephaly-like clefts that resemble schizencephaly on histological examination. These strokes, typically in the territory, may stem from fetal or embolic events during the late first or early second , leading to encephaloclastic tissue loss and cleft formation. Intracranial hemorrhages, sometimes triggered by infections like CMV, can also evolve into schizencephalic clefts through secondary ischemic . Teratogenic exposures, notably maternal use of during the first trimester, have been directly linked to schizencephaly via induction of hemorrhagic infarcts in the developing . inhibits vitamin K-dependent clotting factors, increasing the risk of fetal vascular disruptions and subsequent clefting, as reported in case studies of congenital warfarin embryopathy with neurological sequelae. Other teratogens, such as , may exacerbate these risks by causing and . Maternal risk factors, including young age under 20 years, consumption, , and absence of first-trimester , significantly elevate the likelihood of schizencephaly. A population-based study identified these as independent associations, with use potentially contributing through teratogenic effects on neuronal and young maternal age correlating with higher exposure to uncontrolled environmental insults. Illicit substances like narcotics further compound vascular instability in the . Metabolic disturbances, such as fetal around the eighth gestational week, and represent potential contributors to abnormal cleavage underlying schizencephaly. can impair cellular migration during early corticogenesis, while traumatic events like maternal abdominal injury or invasive procedures (e.g., ) may induce direct vascular or mechanical disruption to the developing hemispheres. These factors are thought to act during the vulnerable window of weeks 4 to 8, when the prosencephalon divides into telencephalic vesicles.

Classification

Closed-lip schizencephaly

Closed-lip schizencephaly, classified as type I schizencephaly, represents the milder form of this congenital disorder, featuring a full-thickness cleft that extends from the pial surface of the to the ependymal lining of the lateral ventricle, with the cleft walls in direct apposition and fused together, preventing any (CSF)-filled gap. The pathological hallmark is the lining of the cleft by a thin layer of heterotopic gray matter, frequently displaying due to disrupted neuronal during early brain development, while the apposed walls maintain contact without separation. This configuration isolates the subarachnoid space from the , distinguishing it from more disruptive variants. This subtype most commonly manifests as unilateral lesions, predominantly affecting the perisylvian regions, posterior , or , with involvement of the also frequent; isolated temporal or cases are rare. Bilateral occurrences are less typical for closed-lip compared to other forms. Clinically, closed-lip schizencephaly correlates with a milder , often presenting with , motor delay, or subtle developmental challenges, and is associated with better-preserved intellectual and function, particularly in unilateral cases where up to 78% achieve mild to moderate neurodevelopmental outcomes. The risk of is lower than in open-lip schizencephaly, with seizures occurring in approximately 50-60% of cases overall for schizencephaly but tending toward the lower end and better control in closed-lip variants due to less extensive disruption. Many individuals remain or are diagnosed incidentally in adulthood. On diagnostic imaging, particularly MRI, closed-lip schizencephaly appears as a characteristic nipple-like protrusion or dimple at the ventricular surface, with a tract of gray matter extending outward and no evident CSF communication between the ventricle and cortical surface; this subtle feature can be challenging to detect on . In contrast to open-lip schizencephaly, where walls are separated, the fused appearance confirms the closed-lip diagnosis.

Open-lip schizencephaly

Open-lip schizencephaly, classified as type II schizencephaly, is defined by a full-thickness cleft in the where the opposing walls are separated, forming a clear gap filled with (CSF) that communicates directly between the cortical surface and the lateral ventricle. This malformation features dysplastic gray matter lining both sides of the cleft, characterized by and often heterotopic neurons, with associated ventricular enlargement due to disrupted brain architecture. The cleft typically involves the perisylvian regions, such as the frontal or parietal lobes, and contrasts with the closed-lip form by allowing free CSF flow through the gap. Bilateral involvement is frequent in open-lip schizencephaly, occurring in approximately 40% of all reported cases and more commonly presenting as open-lip in bilateral configurations, affecting both hemispheres either symmetrically or asymmetrically. Unilateral cases also occur but are less severe in comparison. The condition carries a high risk of severe neurological consequences, including which is often refractory (particularly in bilateral cases), profound , and spastic quadriparesis. Progression may involve secondary arising from altered CSF dynamics within the open cleft, potentially leading to increased .

Diagnosis

Imaging techniques

Magnetic resonance imaging (MRI) serves as the gold standard for diagnosing schizencephaly due to its superior contrast and ability to delineate anatomical details. Standard T1- and T2-weighted sequences reveal the characteristic full-thickness cleft extending from the pial surface to the ependymal lining of the lateral ventricle, lined by dysplastic gray matter often exhibiting . These sequences also effectively demonstrate the extent of the cleft—whether closed-lip (appearing as a nipple-like outpouching) or open-lip (CSF-filled gap)—and associated anomalies such as or absent . MRI's high resolution is crucial for distinguishing schizencephaly from mimics like , as the former features gray matter lining while the latter shows gliotic . Prenatal , typically performed in the second , is the initial for suspecting schizencephaly, often detecting open-lip clefts as anechoic, fluid-filled spaces communicating between the lateral ventricle and subarachnoid space, particularly near the Sylvian fissure. It may also identify indirect signs like or midline anomalies, but its sensitivity is limited for closed-lip variants or small clefts due to lower resolution and acoustic shadowing. Fetal MRI is recommended for confirmation in suspected cases, offering better visualization of the gray matter lining and associated malformations, thus improving diagnostic accuracy over ultrasound alone. Postnatally, computed tomography () provides a rapid screening tool, particularly useful for identifying calcifications, , or gross ventricular dilation associated with schizencephaly. However, is inferior to MRI for assessing gray matter detail and cleft lining, often appearing less distinct in differentiating gray-white matter interfaces. Postnatal via the can further support initial evaluation, showing echogenic gray matter edges along hypoechoic clefts in coronal views, though it shares similar limitations to prenatal and typically requires MRI for definitive characterization. Advanced imaging techniques, such as diffusion tensor imaging (DTI) with , assess disruptions in tracts adjacent to the cleft, such as the pyramidal tract, revealing asymmetries that correlate with motor function deficits. Key diagnostic criteria across modalities include a full-thickness cleft from to , lined by polymicrogyric gray matter, confirming the malformation's congenital neuronal migration origin.

Differential diagnosis

Schizencephaly must be differentiated from other cerebral malformations and acquired lesions that present with clefts or cystic spaces on , as accurate distinction relies on identifying the presence of gray matter lining the cleft and the timing of the insult during brain development. Misdiagnosis can occur due to overlapping imaging appearances, particularly in unilateral cases, where clinical features like seizures or may be similar. Porencephaly is a primary , featuring a full-thickness cleft extending from the cortical surface to the ventricle, but unlike schizencephaly, it is lined by gliotic rather than heterotopic gray matter, reflecting a destructive (encephaloclastic) process such as vascular insult after neuronal migration is complete. This distinction is evident on MRI, where shows irregular margins with surrounding and lacks the polymicrogyric gray matter seen in schizencephaly. Some classifications consider schizencephaly a form of "true " due to its developmental origin, but the gray matter lining remains the key differentiator. Migration disorders, such as or focal cortical , can mimic schizencephaly when presenting with cortical irregularities or shallow clefts, but they typically lack a full-thickness cleft reaching the ventricle and instead show focal areas of abnormal gyration without gray matter-lined communication to the subarachnoid space. often coexists as the lining of schizencephalic clefts but, in isolation, appears as multifocal pachygyric cortex without ventricular extension. may present as a linear periventricular nodule bulging into the ventricle, simulating a cleft, but it does not form a continuous gray matter-lined tract to the . Holoprosencephaly involves midline fusion defects with incomplete hemispheric separation, often accompanied by absent corpus callosum or septum pellucidum, but lacks the lateral gray matter-lined clefts characteristic of schizencephaly; instead, it shows fused thalami or holotelencephaly without ventricular-pial communication. Imaging differentiation emphasizes the midline nature of holoprosencephaly versus the often unilateral or asymmetric lateral clefts in schizencephaly. Intrauterine infections, such as (CMV), can produce periventricular calcifications, , and destructive lesions mimicking schizencephalic clefts, but these are distinguished by the absence of gray matter lining and the presence of migrational disruptions like or hyperintensities on MRI, often with systemic signs of . CMV-related vasculopathy may lead to porencephaly-like encephalomalacia rather than true developmental clefts. Tumors or arachnoid cysts may simulate clefts through or cystic expansion, but arachnoid cysts are extra-axial, CSF-filled collections without gray matter lining or ventricular connection, while tumors exhibit enhancing solid components or restricted absent in schizencephaly. is confirmed by the lack of developmental gray matter features and the presence of compressive rather than intrinsic cleft morphology on .
ConditionKey Imaging Distinction from SchizencephalyTypical Etiology
Lined by gliotic ; irregular margins with Post-migrational vascular destruction
Polymicrogyria/FCDNo full-thickness cleft to ventricle; focal cortical irregularityNeuronal migration defect, no cleft
Midline fusion failure; fused structures, no lateral cleftEarly prosencephalic cleavage defect
CMV InfectionPeriventricular calcifications; signal changesInfectious vasculopathy/encephalomalacia
/TumorExtra-axial, no gray matter lining; enhancement or compressionNon-developmental, mass/cystic effect

Management

Symptomatic treatment

for schizencephaly focuses on alleviating associated neurological symptoms through conservative, non-invasive approaches, tailored to the individual's presentation such as seizures, motor impairments, and developmental delays. Multidisciplinary care involving neurologists, therapists, and educators is essential to optimize and functional outcomes. Seizures, a common manifestation occurring in 50-60% of cases, are primarily managed with antiepileptic drugs (AEDs) as first-line therapy. and are frequently used as first-line therapies for focal or generalized seizures. For refractory cases, additional agents like or may be added, often requiring polytherapy and regular monitoring to adjust regimens. Physical, occupational, and speech therapies form the cornerstone of addressing motor delays, spasticity, and communication challenges, ideally initiated in early infancy to promote and skill development. Physical therapy targets gross motor function and to improve and reduce spasticity-related discomfort, while occupational therapy enhances fine motor skills and daily living activities. Speech therapy supports and difficulties, particularly in bilateral cases with cognitive involvement. These interventions, delivered through structured rehabilitation programs, have been shown to mitigate long-term functional deficits. Mild , which can accompany schizencephaly due to disrupted dynamics, is initially managed with close clinical and to assess progression. Temporary pharmacological interventions, such as or , may be employed to reduce in select non-severe cases, serving as a bridge before considering escalation. Nutritional and developmental support involves a comprehensive team approach to address feeding difficulties, growth concerns, and cognitive delays. Specialized nutritional plans ensure adequate intake to support overall development, often integrated with multidisciplinary care that includes services to foster learning and social integration. For contributing to motor limitations, oral serves as a primary to modulate via GABA-B receptor agonism, with injections targeted to specific muscle groups for focal relief when systemic therapy is insufficient. These measures, combined with , help prevent contractures and enhance mobility, though refractory may necessitate surgical evaluation.

Surgical options

Surgical interventions for schizencephaly are typically reserved for cases where complications such as obstructive or intractable lead to progressive neurological deterioration unresponsive to medical management. These procedures aim to alleviate (CSF) buildup or control seizures originating from malformed cortical tissue, but they carry risks including , , and potential exacerbation of existing motor deficits like . Ventriculoperitoneal (VP) shunt placement is indicated for obstructive associated with open-lip schizencephaly, where the cleft disrupts normal CSF pathways, leading to ventricular enlargement and brain compression. The procedure involves inserting a into the lateral ventricle or the fluid-filled cleft to divert excess CSF to the , thereby reducing and preventing further neurological compromise. Outcomes generally include symptom relief, such as decreased and improved motor function, with case reports demonstrating sustained stability and no seizures for several years post-shunt. In severe unilateral schizencephaly with medically refractory , hemispherectomy or hemispherotomy may be performed to remove or functionally disconnect the affected , targeting epileptogenic zones within the malformed and adjacent tissues. These surgeries are considered when persist despite optimal antiepileptic therapy, often in patients with , as the procedure can worsen motor function on the contralateral side but may halt propagation. Postoperative freedom rates range from 60% to 80% in the early years, though long-term efficacy may decline slightly, accompanied by potential cognitive challenges due to hemispheric loss despite compensatory in the remaining brain. Endoscopic is occasionally employed in select cases of cleft-related CSF obstructions, such as expanding ventricular diverticula overlying the , to create alternative pathways for CSF flow and mitigate . This minimally invasive approach involves perforating membranes via to connect isolated cavities to the or basal cisterns, but its success is variable, with some reports indicating limited efficacy and progression requiring subsequent shunting.

Prognosis

Factors affecting outcome

The prognosis of schizencephaly is significantly influenced by the type and of the cleft. Closed-lip schizencephaly, particularly unilateral, is associated with the best outcomes, with approximately 78% of closed-lip patients experiencing mild to moderate neurocognitive and motor impairments, whereas bilateral open-lip schizencephaly yields the poorest results, with the majority of cases resulting in severe , including profound and quadriparesis. In a large , bilateral clefts conferred an odds ratio of 6.31 for neurocognitive dysfunction compared to unilateral cases. Cleft size and location also play critical roles in determining the severity of deficits. Smaller, non-periventricular clefts correlate with milder cognitive and motor outcomes, while larger clefts are linked to earlier onset of and more profound impairments. Perisylvian involvement, particularly in bilateral cases, is associated with greater speech and language delays, whereas clefts more commonly lead to or quadriparesis in 83% of affected patients. Early intervention, including timely physical, occupational, and speech therapies as well as seizure management, can substantially improve motor skills, , and overall . Neurological deficits often manifest before age 1 year, underscoring the importance of prompt multidisciplinary support to mitigate long-term disability. Comorbidities further worsen the trajectory. , present in up to 60.5% of cases as , exacerbates motor and cognitive deficits, while , which co-occurs in a significant proportion of reported cases (up to 69.1% in one review of published literature), adds risks of , endocrine dysfunction, and increased seizure refractory rates. , seen in 41.5% of individuals, carries an odds ratio of 21.75 for severe neurocognitive impairment. Socioeconomic factors, particularly access to multidisciplinary , profoundly impact outcomes by influencing the timeliness and quality of interventions. Limited resources and delayed in lower socioeconomic settings can hinder , leading to poorer motor and cognitive trajectories compared to those with comprehensive support systems.

Long-term expectations

Individuals with schizencephaly typically enjoy a near-normal lifespan when managed appropriately, though severe bilateral cases carry an elevated risk of mortality due to complications such as , infections, or uncontrolled seizures. In milder unilateral forms, survival is generally unaffected, with most individuals reaching adulthood without life-shortening issues. Functional outcomes vary significantly by the extent and laterality of the clefts; many individuals with unilateral schizencephaly achieve , often with manageable and near-normal intelligence, whereas bilateral cases frequently result in profound and motor impairments necessitating lifelong support. is influenced by factors such as cleft size and associated anomalies, with smaller unilateral closed-lip variants yielding the best results. Epilepsy persists in the majority of cases into adulthood, with about 70% of affected individuals requiring ongoing antiepileptic drug (AED) therapy, and a notable risk of in refractory bilateral forms. control can be challenging in open-lip schizencephaly, where intractable is more common, though surgical interventions may improve outcomes in select patients. Quality of life can be enhanced through multidisciplinary therapies, including physical, occupational, and speech interventions, which mitigate motor and cognitive deficits; however, severe bilateral schizencephaly is associated with high rates of institutionalization due to dependency needs. In adulthood, challenges often include heightened psychiatric issues such as anxiety, , and , alongside employment limitations stemming from cognitive and physical impairments, particularly in bilateral cases.

Schizencephaly is a rare congenital malformation with an estimated incidence of approximately 1.5 per 100,000 live births, as reported in population-based studies spanning 2011 to 2023. Prevalence estimates among individuals range from 0.54 to 1.54 per 100,000, reflecting variations in detection rates that have risen with advancements in (MRI) technology, which has become the gold standard for identifying the condition's characteristic gray matter-lined clefts. The malformation presents in two main morphological types: closed-lip (Type I), where the cleft walls are fused with no communication, accounting for 20-30% of cases; and open-lip (Type II), featuring separated walls with fluid-filled clefts, comprising 70-80% of cases. It occurs unilaterally in about 65% of diagnosed instances and bilaterally in 35%, with unilateral forms often associated with milder clinical manifestations. Prevalence rates show geographic consistency, with birth prevalence of approximately 1.54 per 100,000 in the United States and 1.44 per 100,000 in the , based on national registries; no significant ethnic variations have been identified across these populations. The condition's true occurrence is likely underestimated in low-resource settings due to limited access to advanced neuroimaging like MRI, leading to underdiagnosis or misattribution to other cerebral pathologies.

Demographic patterns

Schizencephaly exhibits no predominance, with studies reporting an equal distribution between males and females. Approximately 47% of cases are diagnosed prenatally via , typically after 20 weeks of gestation, while the remainder are identified in the neonatal period or infancy, often prompted by the onset of seizures. The mean age at diagnosis for symptomatic infants is around 6 months, reflecting early neurological manifestations in most affected individuals. Over 95% of schizencephaly cases are sporadic, with familial occurrences being exceedingly rare and limited to reports of recurrences that indicate possible incomplete genetic . Reported incidence appears higher in populations with socioeconomic disadvantages, particularly areas characterized by poor access, which correlates with increased environmental risk factors such as young maternal age (under 20 years) and exposure during . Late diagnoses in adulthood are uncommon and typically involve mild unilateral cases, often discovered incidentally through imaging for unrelated issues or presenting with new-onset seizures.