Peripheral vascular decoupling in porcine endotoxic shock

Peripheral vascular decoupling in porcine endotoxic shock

Cardiac output measurement from arterial pressure waveforms presumes a defined relationship between the arterial pulse pressure (PP), vascular compliance (C), and resistance (R). Cardiac output estimates degrade if these assumptions are incorrect. We hypothesized that sepsis would differentially alt...

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Bibliographic Details
Published in:Journal of applied physiology (1985) Vol. 111; no. 3; pp. 853 - 860
Main Authors: HATIB, Feras, JANSEN, Jos R. C, PINSKY, Michael R
Format: Journal Article
Language:English
Published: Bethesda, MD American Physiological Society 01-09-2011
Subjects:
Acute Disease
Algorithms
Animals
Aorta - physiopathology
Biological and medical sciences
Blood
Blood Flow Velocity
Blood Pressure
Cardiac Output
Catheterization
Compliance
Coronary vessels
Disease Models, Animal
Female
Femoral Artery - physiopathology
Fourier Analysis
Fundamental and applied biological sciences. Psychology
Heart
Hemodynamics
Hogs
Lipopolysaccharides
Models, Cardiovascular
Monitoring, Physiologic
Predictive Value of Tests
Radial Artery - physiopathology
Regional Blood Flow
Resuscitation
Sepsis
Shock, Septic - chemically induced
Shock, Septic - physiopathology
Shock, Septic - therapy
Swine
Time Factors
Vascular Resistance
Shock
Animal model
pulse contour
Endotoxin
Pig
Infection
Sepsis syndrome
Toxin
Vertebrata
Mammalia
Artiodactyla
Hemodynamics
Ungulata
Monitoring
sepsis
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Summary:Cardiac output measurement from arterial pressure waveforms presumes a defined relationship between the arterial pulse pressure (PP), vascular compliance (C), and resistance (R). Cardiac output estimates degrade if these assumptions are incorrect. We hypothesized that sepsis would differentially alter central and peripheral vasomotor tone, decoupling the usual pressure wave propagation from central to peripheral sites. We assessed arterial input impedance (Z), C, and R from central and peripheral arterial pressures, and aortic blood flow in an anesthetized porcine model (n = 19) of fluid resuscitated endotoxic shock induced by endotoxin infusion (7 μg·kg⁻¹·h⁻¹ increased to 14 and 20 μg·kg⁻¹·h⁻¹ every 10 min and stopped when mean arterial pressure <40 mmHg or Sv(O₂) < 45%). Aortic, femoral, and radial artery pressures and aortic and radial artery flows were measured. Z was calculated by FFT of flow and pressure data. R and C were derived using a two-element Windkessel model. Arterial PP increased from aortic to femoral and radial sites. During stable endotoxemia with fluid resuscitation, aortic and radial blood flows returned to or exceeded baseline while mean arterial pressure remained similarly decreased at all three sites. However, aortic PP exceeded both femoral and radial arterial PP. Although Z, R, and C derived from aortic and radial pressure and aortic flow were similar during baseline, Z increases and C decreases when derived from aortic pressure whereas Z decreases and C increases when derived from radial pressure, while R decreased similarly with both pressure signals. This central-to-peripheral vascular tone decoupling, as quantified by the difference in calculated Z and C from aortic and radial artery pressure, may explain the decreasing precision of peripheral arterial pressure profile algorithms in assessing cardiac output in septic shock patients and suggests that different algorithms taking this vascular decoupling into account may be necessary to improve their precision in this patient population.
ISSN:8750-7587
1522-1601
DOI:10.1152/japplphysiol.00066.2011