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| Model de Windkessel× | Hemodinàmica per CFD× | Variabilitat de la freqüència cardíaca× | Fotopletismografia× | |
|---|---|---|---|---|
| Camp | Biomecànica | Biomecànica | Biomecànica | Biomecànica |
| Família | Process / pipeline | Process / pipeline | Process / pipeline | Process / pipeline |
| Any d'origen≠ | 1969 | 2002 | 1996 | 1937 |
| Autor original≠ | Nikolaos Westerhof | David Steinman | Task Force of European Society of Cardiology | Hertzman |
| Tipus≠ | Physiological lumped-parameter modeling | Multi-physics finite element simulation | Time-series and frequency-domain analysis pipeline | Optical signal acquisition and analysis pipeline |
| Font seminal≠ | Westerhof, N., Bosman, F., De Vries, N. C., & Noordergraaf, A. (1969). Analog studies of the human systemic arterial tree. Journal of Biomechanics, 2(2), 121-143. DOI ↗ | Steinman, D. A., Vinh, B., Ethier, C. R., Ojha, M., Cobbold, R. S., & Johnston, K. W. (2002). A numerical simulation of flow in a two-dimensional end-to-side anastomosis model. Journal of Biomechanical Engineering, 115(1), 112-118. link ↗ | Task Force of the European Society of Cardiology and the North American Society of Pacing and Electrophysiology. (1996). Heart rate variability: standards of measurement, physiological interpretation, and clinical use. Circulation, 93(5), 1043-1065. DOI ↗ | Allen, J. (2007). Photoplethysmography and its application in clinical physiology. Physiology & Behavior, 107(4), 540-548. link ↗ |
| Àlies | Elastic chamber model, Arterial compliance model, Lumped parameter model | Cardiovascular CFD, Blood flow simulation, Hemodynamic simulation | HRV, RR interval analysis, Cardiac variability | PPG, Pulse oximetry, Reflectance photometry |
| Relacionats | 3 | 3 | 3 | 3 |
| Resum≠ | The Windkessel model is a lumped-parameter representation of the arterial system that captures the pulsatile dynamics of blood flow and pressure using simple mechanical analogs (resistors and capacitors). Named after the German word for air chamber, it was formalized by Westerhof and colleagues in the late 1960s and remains fundamental to understanding arterial hemodynamics and blood pressure regulation. | Computational fluid dynamics (CFD) for hemodynamics solves the Navier-Stokes equations to simulate blood flow in realistic vascular geometries. Pioneered by researchers such as David Steinman, CFD hemodynamics reveals complex flow patterns, wall shear stress distributions, and hemodynamic factors implicated in atherosclerosis, aneurysm rupture, and device-induced thrombosis. | Heart rate variability (HRV) analysis quantifies the variation in time intervals between consecutive heartbeats as a window into autonomic nervous system function and cardiovascular health. Formalized by the European Society of Cardiology Task Force in 1996, HRV metrics are now standard in cardiology, physiology, and sports science for assessing stress, recovery, and disease risk. | Photoplethysmography (PPG) measures blood volume changes in tissue using light absorption, providing a non-invasive optical window into cardiovascular dynamics. Originally developed by Hertzman in 1937, PPG is now ubiquitous in pulse oximetry, smartwatches, and research applications for monitoring heart rate, blood oxygenation, and vascular function. |
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