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Cardiovascular Response to Posture Changes: Multiscale Modeling and in vivo Validation During Head-Up Tilt

Matteo Fois, Simona Maule, Marta Giudici, Matteo Valente, Luca Ridolfi, Stefania Scarsoglio

2022Frontiers in Physiology30 citationsDOIOpen Access PDF

Abstract

In spite of cardiovascular system (CVS) response to posture changes have been widely studied, a number of mechanisms and their interplay in regulating central blood pressure and organs perfusion upon orthostatic stress are not yet clear. We propose a novel multiscale 1D-0D mathematical model of the human CVS to investigate the effects of passive (i.e., through head-up tilt without muscular intervention) posture changes. The model includes the main short-term regulation mechanisms and is carefully validated against literature data and in vivo measures here carried out. The model is used to study the transient and steady-state response of the CVS to tilting, the effects of the tilting rate, and the differences between tilt-up and tilt-down. Passive upright tilt led to an increase of mean arterial pressure and heart rate, and a decrease of stroke volume and cardiac output, in agreement with literature data and present in vivo experiments. Pressure and flow rate waveform analysis along the arterial tree together with mechano-energetic and oxygen consumption parameters highlighted that the whole system approaches a less stressed condition at passive upright posture than supine, with a slight unbalance of the energy supply-demand ratio. The transient dynamics is not symmetric in tilt-up and tilt-down testing, and is non-linearly affected by the tilting rate, with stronger under- and overshoots of the hemodynamic parameters as the duration of tilt is reduced. By enriching the CVS response to posture changes, the present modeling approach shows promise in a number of applications, ranging from autonomic system disorders to spaceflight deconditioning.

Topics & Concepts

Supine positionTilt (camera)Heart rateOrthostatic vital signsBlood pressureHemodynamicsMedicineStroke volumeCardiac outputMean arterial pressureHaemodynamic responseCardiologyMechanicsBiomedical engineeringAnesthesiaInternal medicinePhysicsStructural engineeringEngineeringSpaceflight effects on biologyHeart Rate Variability and Autonomic ControlCardiovascular Health and Disease Prevention