Modeling Cyclic Variation of Intracranial Pressure

Abstract

To test the theoretical feasibility that low frequency baseline changes of the intracranial pressure (ICP) recording during mechanical ventilation are due to cyclic extravascular compressional modulation primarily of the cerebral venous bed, an established isovolumetric model of cerebrospinal fluid dynamics proposed by Ursino was modified. These modifications were made to address the hypothesis that: (1) cyclic extravascular compressional modulation of the cerebral venous bed occurs during positive pressure inhalation, and (2) the degree of modulation is diminished with increasing vascular dilation induced by increasing the level of the partial pressure of carbon dioxide (PC02) within the arterial blood. Modification of the isovolumetric model was accomplished by introducing a cyclic modulation of the resistance of the cerebral venous bed synchronized with ventilation. Simulated model recordings demonstrated that the correlation index between arterial blood pressure and ICP progressively increased monotonically as the level of PC02 increased from 30 mmHg to 80 mmHg. These results support the premise that during positive pressure ventilation, cyclic extravascular compressional modulation of primarily the cerebral venous bed produces a cyclic variation of ICP and the degree of modulation is dependent on the state of vascular dilation. The potential clinical application of these results is that patients with severe head injury who demonstrate a strong correlation between the ICP and arterial blood pressure recordings are likely to have a high transmural venous pressure indicative of maximal dilation, loss of autoregulation of cerebral blood flow, and the subsequent development of cerebral edema.

Document Details

Document Type

Technical Report

Publication Date

Oct 25, 2001

Accession Number

ADA410875

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