In 10% to 15% of cases, there is no clear cause of CP. There is increasing recognition that genetics plays a part, but no standardized approach to genetic testing in patients with CP exists. In this study we asked the question whether both people with and without known risk factors for CP should have genetic testing.
This study tested the safety and effectiveness of a neuroscience-based, multi-component intervention designed to improve motor skills and sensory processing of the more-affected arm and hand in infants with CP where one side is more impacted than the other (asymmetric CP).
This comprehensive review of the research evidence surrounding supportive stepping for individuals, GMFCS IV and V, provides helpful information for families to make practical decisions about for whom, when, and how long to use a supported stepping device (also known as gait trainers).
This comprehensive review of the research evidence surrounding supportive standing for individuals, GMFCS IV and V, provides helpful information for families to make practical decisions about for whom, when, and how long to use a standing device.
Bimanual therapy, also referred to as intensive bimanual training, engages patients in active play or practice to improve the use and coordination of both hands. Bimanual therapy is different from similar unimanual therapies, like constraint-induced movement therapy (CIMT), because it promotes simultaneous use of both hands.
The GMFCS, MACS and CFCS are all tools used by therapists and researchers to help classify the functional capabilities of individuals with CP. This research article provides evidence of their stability over time.
The GMFCS can be a helpful tool in clinical and research use and has been shown to be stable and accurate over time. It can also help individuals and families better understand cerebral palsy.
Cohort-based whole exome and whole genome sequencing and copy number variant (CNV) studies have identified genetic etiologies for a sizable proportion of patients with cerebral palsy (CP). These findings indicate that genetic mutations collectively comprise an important cause of CP.
"In addition to commonly associated environmental factors, genomic factors may cause cerebral palsy. We performed whole-exome sequencing of 250 parent–offspring trios, and observed enrichment of damaging de novo mutations in cerebral palsy cases."