6533b7d4fe1ef96bd126283c
RESEARCH PRODUCT
A nonlinear biomechanical model for evaluation of cerebrospinal fluid shunt systems.
Oliver KempskiMohamed A. Hafezsubject
medicine.medical_specialtyIntracranial PressureModels NeurologicalCranial SinusesCerebrospinal fluidCerebrospinal Fluid PressuremedicineTransducers PressureHumansIntracranial pressurebusiness.industryGeneral MedicineEquipment Designmedicine.diseaseCerebral VeinsCerebrospinal Fluid ShuntsSurgeryHydrocephalusCerebrospinal fluid shuntBiomechanical PhenomenaCompliance (physiology)Pediatrics Perinatology and Child HealthFlushingBiomechanical modelEquipment FailureNeurology (clinical)medicine.symptomJugular VeinsbusinessShunt (electrical)Biomedical engineeringHydrocephalusdescription
In view of complications arising from physical properties of cerebrospinal fluid shunts, a biomechanical model of hydrocephalus was set up to study in vivo parameters that may influence their function. These include: intracranial pressure, compliance and pulses, intrathoracic, intra-abdominal, and subcutaneous pressures, and the effects of siphonage and repeated valve flushing. Each of these factors was studied separately upon shunt implantation in the model. Results of testing of a sample low-pressure valve with antisiphon device conformed with consumer information in regard to valve opening pressure and pressure flow measurements. No customer information, however, was supplied concerning the deleterious effects of direct subcutaneous pressure, variable degrees of siphonage, and repeated valve flushing that were demonstrated by the model. Such results indicate that shunts should be similarly tested prior to marketing and implantation in patients.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 1994-07-01 | Child's nervous system : ChNS : official journal of the International Society for Pediatric Neurosurgery |