Association between phenotypes and genotype of developmental and epileptic encephalopathy in next-generation sequencing methods in infants: A scoping review.

Introduction: Developmental and epileptic encephalopathy (DEE) is epilepsy related to developmental impairment that may be caused by both the underlying etiology (developmental encephalopathy) and superimposed epileptic activity (epileptic encephalopathy). The origin of DEE and the causes of its variations remain unknown. Owing the lack of clarity regarding the role of genetic variables in DEE, we conducted a scoping review to qualitatively identify the genes most important in the development of DEE to provide an up-to-date review.

Material and methods: We searched all published studies related to the genetic factors of DEE. The identified publications were screened and selected by the authors on basis of on inclusion and exclusion criteria and assessed for methodological quality. Eighteen articles were included. The extracted data included age of onset, sex, gene mutations and inheritance (e.g. nucleotide change, protein change, and family testing), clinical manifestation, electroencephalogram, imaging, medication, and outcomes.

Result: A total of 18 studies were included in this scoping review. The most frequently reported gene variants were STXBP1 in Ohtahara Syndrome, SLC1A2 in Early Myoclonic Encephalopathy (EME), CDKL5 in West Syndrome, SCN1A in Dravet Syndrome, and KCNT1 in Epilepsy of Infancy with Migrating Focal Seizures (EIMFS). Each gene was associated with distinct electroclinical features, including differences in age of onset, seizure type, EEG patterns, and developmental outcomes. While genotype and phenotype associations were heterogeneous, certain variants showed consistent patterns indicative of more severe disease courses.

Conclusions: This review identified key gene variants commonly associated with early-onset DEE in infants, particularly STXBP1, SLC1A2, CDKL5, SCN1A, and KCNT1, each linked to unique clinical presentations and outcomes. These findings support the clinical utility of next-generation sequencing (NGS) for early diagnosis and tailored treatment planning in DEE. Understanding genotype-phenotype correlations may enhance prognostication and highlight potential avenues for targeted therapy in future research.