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Critical Care
Published in: Critical Care 3/2003

Open Access 01-06-2004 | Research

Preload-independent mechanisms contribute to increased stroke volume following large volume saline infusion in normal volunteers: a prospective interventional study

Authors: Anand Kumar, Ramon Anel, Eugene Bunnell, Sergio Zanotti, Kalim Habet, Cameron Haery, Stephanie Marshall, Mary Cheang, Alex Neumann, Amjad Ali, Clifford Kavinsky, Joseph E Parrillo

Published in: Critical Care | Issue 3/2003

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Abstract

Introduction

Resuscitation with saline is a standard initial response to hypotension or shock of almost any cause. Saline resuscitation is thought to generate an increase in cardiac output through a preload-dependent (increased end-diastolic volume) augmentation of stroke volume. We sought to confirm this to be the mechanism by which high-volume saline administration (comparable to that used in resuscitation of shock) results in improved cardiac output in normal healthy volunteers.

Methods

Using a standardized protocol, 24 healthy male (group 1) and 12 healthy mixed sex (group 2) volunteers were infused with 3 l normal (0.9%) saline over 3 hours in a prospective interventional study. Individuals were studied at baseline and following volume infusion using volumetric echocardiography (group 1) or a combination of pulmonary artery catheterization and radionuclide cineangiography (group 2).

Results

Saline infusion resulted in minor effects on heart rate and arterial pressures. Stroke volume index increased significantly (by approximately 15–25%; P < 0.0001). Biventricular end-diastolic volumes were only inconsistently increased, whereas end-systolic volumes decreased almost uniformly. Decreased end-systolic volume contributed as much as 40–90% to the stroke volume index response. Indices of ventricular contractility including ejection fraction, ventricular stroke work and peak systolic pressure/end-systolic volume index ratio all increased significantly (minimum P < 0.01).

Conclusion

The increase in stroke volume associated with high-volume saline infusion into normal individuals is not only mediated by an increase in end-diastolic volume, as standard teaching suggests, but also involves a consistent and substantial decrease in end-systolic volumes and increases in basic indices of cardiac contractility. This phenomenon may be consistent with either an increase in biventricular contractility or a decrease in afterload.
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Metadata
Title
Preload-independent mechanisms contribute to increased stroke volume following large volume saline infusion in normal volunteers: a prospective interventional study
Authors
Anand Kumar
Ramon Anel
Eugene Bunnell
Sergio Zanotti
Kalim Habet
Cameron Haery
Stephanie Marshall
Mary Cheang
Alex Neumann
Amjad Ali
Clifford Kavinsky
Joseph E Parrillo
Publication date
01-06-2004
Publisher
BioMed Central
Published in
Critical Care / Issue 3/2003
Electronic ISSN: 1364-8535
DOI
https://doi.org/10.1186/cc2844

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