Abstract
Standing up elicits a host of cardiovascular changes which all affect the cerebral circulation. Lowered mean arterial blood pressure (ABP) at brain level, change in the cerebral venous outflow path, lowered end‐tidal PCO 2 (PETCO 2), and intracranial pressure (ICP) modify cerebral blood flow (CBF). The question we undertook to answer is whether gravity‐induced blood pressure (BP) changes are compensated in CBF with the same dynamics as are spontaneous or induced ABP changes in a stable position. Twenty‐two healthy subjects (18/4 m/f, 40 ± 8 years) were subjected to 30° and 70° head‐up tilt (HUT) and sinusoidal tilts (SinTilt, 0°↨60° around 30° at 2.5–10 tilts/min). Additionally, at those three tilt levels, they performed paced breathing at 6–15 breaths/min to induce larger than spontaneous cardiovascular oscillations. We measured continuous finger BP and cerebral blood flow velocity (CBFv) in the middle cerebral artery by transcranial Doppler to compute transfer functions (TFs) from ABP‐ to CBFv oscillations. SinTilt induces the largest ABP oscillations at brain level with CBFv gains strikingly lower than for paced breathing or spontaneous variations. This would imply better autoregulation for dynamic gravitational changes. We demonstrate in a mathematical model that this difference is explained by ICP changes due to movement of cerebrospinal fluid (CSF) into and out of the spinal dural sack. Dynamic cerebrovascular autoregulation seems insensitive to how BP oscillations originate if the effect of ICP is factored in. CSF‐movement in‐and‐out of the spinal dural space contributes importantly to orthostatic tolerance by its effect on cerebral perfusion pressure.
Highlights
Standing up in the morning might be the most audacious deed of the day
Blood pressure at heart level increases only when going to +70°; at +30°, it is already significantly decreased at brain level. mCBFv decreases going from 0° to +30° and further to +70°, at the same time PETCO2 is decreasing
To make a good comparison for the three ways to define the transfer from ABPbrain to cerebral blood flow velocity (CBFv), we have reduced the individual curves underlying Figure 3: For each subject, we only present the results for gain and phase at 0.1 Hz as derived from the spontaneous variability in supine, +30° and +70° head-up tilt (HUT), respectively (Claassen et al 2016) and the data points at the three frequencies paced breathing (PB) and four frequencies sinusoidal tilts (SinTilt) as measured at +30° HUT
Summary
Standing up in the morning might be the most audacious deed of the day. It forces the circulation to adapt to the demands of gravity, most importantly to provide sufficient pressure for brain perfusion. The increased systemic vascular resistance (SVR) figures most prominently (Rowell 1993). Physiological Reports published by Wiley Periodicals, Inc. on behalf of The Physiological Society and the American Physiological Society.
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