Non-Invasive Intracranial Pressure Estimation During Combined Exposure to CO2 and Head-Down Tilt
BACKGROUND: Exposure to carbon dioxide (CO2) and cephalad fluid shift are considered factors that affect intracranial pressure (ICP) during spaceflight. Increases in ICP were reported during cephalad fluid shift induced by head-down tilt (HDT), while little is known
regarding the effect of additional CO2 during HDT on ICP. Therefore, we tested the hypothesis that this combination increases ICP more than HDT alone.
METHODS: There were 15 healthy male volunteers who underwent 4 types of 10-min interventions consisting of Placebo/Supine (air and supine), CO2/Supine (3% CO2 and supine, CO2 alone), Placebo/HDT (air and −10° HDT, HDT alone), and CO2/HDT (3% CO2 and −10° HDT, combination). Using arterial blood pressure (ABP) and cerebral blood flow velocity waveforms, ICP was estimated noninvasively before and during the four interventions. Two calculation methods were employed. One is based on the signal transformation from ABP to ICP with the intracranial component as a “black box” system (nICP_BB), and the other is based on the equation ICP = ABP − cerebral perfusion pressure, reflecting critical closing pressure (nICP_CrCP).
RESULTS: Both nICP_BB and nICP_CrCP significantly increased during Placebo/HDT and CO2/HDT, although there was no statistically significant difference between the nICP indexes of these two interventions.
DISCUSSION: Increases in ICP were observed during both Placebo/HDT and CO2/HDT. Contrary to our hypothesis, the combination of 3% CO2 and −10° HDT did not increase ICP remarkably compared to −10° HDT alone. Therefore, the addition of 3% CO2 is considered to have little effect on increasing ICP during cephalad fluid shift.
Kurazumi T, Ogawa Y, Yanagida R, Morisaki H, Iwasaki K. Non-invasive intracranial pressure estimation during combined exposure to CO2 and head-down tilt. Aerosp Med Hum Perform. 2018; 89(4):365–370.
METHODS: There were 15 healthy male volunteers who underwent 4 types of 10-min interventions consisting of Placebo/Supine (air and supine), CO2/Supine (3% CO2 and supine, CO2 alone), Placebo/HDT (air and −10° HDT, HDT alone), and CO2/HDT (3% CO2 and −10° HDT, combination). Using arterial blood pressure (ABP) and cerebral blood flow velocity waveforms, ICP was estimated noninvasively before and during the four interventions. Two calculation methods were employed. One is based on the signal transformation from ABP to ICP with the intracranial component as a “black box” system (nICP_BB), and the other is based on the equation ICP = ABP − cerebral perfusion pressure, reflecting critical closing pressure (nICP_CrCP).
RESULTS: Both nICP_BB and nICP_CrCP significantly increased during Placebo/HDT and CO2/HDT, although there was no statistically significant difference between the nICP indexes of these two interventions.
DISCUSSION: Increases in ICP were observed during both Placebo/HDT and CO2/HDT. Contrary to our hypothesis, the combination of 3% CO2 and −10° HDT did not increase ICP remarkably compared to −10° HDT alone. Therefore, the addition of 3% CO2 is considered to have little effect on increasing ICP during cephalad fluid shift.
Kurazumi T, Ogawa Y, Yanagida R, Morisaki H, Iwasaki K. Non-invasive intracranial pressure estimation during combined exposure to CO2 and head-down tilt. Aerosp Med Hum Perform. 2018; 89(4):365–370.
Keywords: cephalad fluid shift; hypercapnia; intracranial pressure; non-invasive method; transcranial Doppler ultrasonography
Document Type: Research Article
Publication date: 01 April 2018
- This journal (formerly Aviation, Space, and Environmental Medicine), representing the members of the Aerospace Medical Association, is published monthly for those interested in aerospace medicine and human performance. It is devoted to serving and supporting all who explore, travel, work, or live in hazardous environments ranging from beneath the sea to the outermost reaches of space. The original scientific articles in this journal provide the latest available information on investigations into such areas as changes in ambient pressure, motion sickness, increased or decreased gravitational forces, thermal stresses, vision, fatigue, circadian rhythms, psychological stress, artificial environments, predictors of success, health maintenance, human factors engineering, clinical care, and others. This journal also publishes notes on scientific news and technical items of interest to the general reader, and provides teaching material and reviews for health care professionals.
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