Dystonia, characterized by involuntary over-contractions or co-contractions of muscle groups, is the third most common movement disorder and afflicts an estimated 300-400 million individuals worldwide. Despite the convergence of this group of disorders on a phenotype of abnormal muscle activity, the ...
Dystonia, characterized by involuntary over-contractions or co-contractions of muscle groups, is the third most common movement disorder and afflicts an estimated 300-400 million individuals worldwide. Despite the convergence of this group of disorders on a phenotype of abnormal muscle activity, the underlying pathophysiology of dystonia has proven to be wide-ranging, diverse, and difficult to elucidate. This reality is reflected in the clinic, where dystonia often poses great diagnostic and therapeutic challenges. However, major inroads have been made in defining the causes, with mounting efforts rising to meet the demand of developing therapies to treat this group of devastating disorders. Specifically, the identification of disease-causing mutations in inherited, often childhood-onset, forms of dystonia has opened the door to generate experimental models to understand the genetic and neural network culprits that cause dystonia. This insight has elucidated commonalities in the molecular and neural pathways underlying genetically distinct forms of dystonia. Despite these advances, there are still many outstanding questions in the field. Why do genetic forms of dystonia often present early in life? What protects against symptom development in non-manifesting carriers of dystonia-causing genetic mutations? Does neurodevelopmental maturation contribute to symptom acquisition, and does this role of maturation reflect a critical therapeutic window? And most importantly, how can we exploit our current understanding of the mechanisms that underlie dystonia to design effective therapies and successful new treatments?
This special issue aims to offer comprehensive coverage of the most recent perspectives in the genetic, molecular, and network mechanisms underlying developmental dystonia. The collection of papers will present diverse model systems, with a focus on understanding dystonia as a disease of network development and maintenance. Together, this issue will summarize the systematic undertakings that are underway to unravel the difficult problem of dystonia and bring the current state of discovery in therapeutic interventions to the fore.
For authors, please also review the journal's information regarding Author Guidelines and Article Processing Charges, or direct any questions to the Editorial Office: dystonia.office@frontierspartnerships.org.
Keywords:
Dystonia, pathophysiology, genetic mutation, neurodevelopmental maturation