Pulmonary artery compliance: its role in right ventricular-arterial coupling

Objective: The aim was to investigate the ventricular/vascular coupling of the intact right heart under conditions of normal operation and acute pulmonary hypertension. Methods: Right ventricular contractility was obtained by calculating the end systolic pressure-volume relationship (Ees) and the ef...

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Published in	Cardiovascular research Vol. 26; no. 9; pp. 839 - 844
Main Authors	Fourie, Pieter R, Coetzee, André R, Bolliger, Chris T
Format	Journal Article
Language	English
Published	Oxford Oxford University Press 01.09.1992
Subjects	Acute Disease acute pulmonary hypertension Animals Biological and medical sciences Compliance Disease Models, Animal end systolic pressure-diameter relationship Fundamental and applied biological sciences. Psychology Humans Hypertension, Pulmonary - physiopathology Pulmonary Artery - physiology Pulmonary Artery - physiopathology pulmonary artery input impedance Stroke Volume - physiology Swine Ventricular Function, Right - physiology Vertebrates: cardiovascular system Physiology Coupling Compliance(volume pressure) Animal Right ventricle Pulmonary artery
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ISSN	0008-6363 1755-3245
DOI	10.1093/cvr/26.9.839

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Abstract	Objective: The aim was to investigate the ventricular/vascular coupling of the intact right heart under conditions of normal operation and acute pulmonary hypertension. Methods: Right ventricular contractility was obtained by calculating the end systolic pressure-volume relationship (Ees) and the effective pulmonary arterial elastance (Ea), applying the Windkessel parameters of the pulmonary arterial input impedance. Coupling between the ventricle and its load could be determined in terms of Ees and Ea. Acute pulmonary hypertension was induced by injecting glass microspheres into the pulmonary vascular bed until a mean pulmonary arterial pressure of more than 35 mm Hg had been reached. Experimental subjects were Landras/Large white pigs (n=ll), studied under general anaesthesia. Ees was obtained by normalising the right ventricle pressure-diameter equivalent of Ees to stroke volume. The lumped element parameters of the Windkessel analogue were calculated from the pulmonary artery pressure and blood flow. Stroke work was calculated from the pressure-volume loop and oxygen consumption derived from the pressure-volume area. Efficiency was taken to be the ratio between stroke work and oxygen consumption. Results: Ea increased significantly as mean pulmonary artery pressure rose, while Ees remained linear and constant. Stroke work, as well as efficiency, increased, with the maximum of the stroke work curve lying to the right of the efficiency maximum. At the control step (before pulmonary artery hypertension), Ees=1.71 Ea (n=ll). Conclusions: Under control conditions, the right ventricle operates at maximum efficiency and submaximal work output. Compliance of the pulmonary artery is a significant factor in decoupling the right ventricle from its vascular load. As the compliance decreases with acute pulmonary hypertension, the maximum stroke work against load point shifted in such a manner that the right ventricle changed its operational status from a flow to a pressure pump, resulting in a decreased stroke volume. Cardiovascular Research 1992;26:000–000
AbstractList	Objective: The aim was to investigate the ventricular/vascular coupling of the intact right heart under conditions of normal operation and acute pulmonary hypertension. Methods: Right ventricular contractility was obtained by calculating the end systolic pressure-volume relationship (Ees) and the effective pulmonary arterial elastance (Ea), applying the Windkessel parameters of the pulmonary arterial input impedance. Coupling between the ventricle and its load could be determined in terms of Ees and Ea. Acute pulmonary hypertension was induced by injecting glass microspheres into the pulmonary vascular bed until a mean pulmonary arterial pressure of more than 35 mm Hg had been reached. Experimental subjects were Landras/Large white pigs (n=ll), studied under general anaesthesia. Ees was obtained by normalising the right ventricle pressure-diameter equivalent of Ees to stroke volume. The lumped element parameters of the Windkessel analogue were calculated from the pulmonary artery pressure and blood flow. Stroke work was calculated from the pressure-volume loop and oxygen consumption derived from the pressure-volume area. Efficiency was taken to be the ratio between stroke work and oxygen consumption. Results: Ea increased significantly as mean pulmonary artery pressure rose, while Ees remained linear and constant. Stroke work, as well as efficiency, increased, with the maximum of the stroke work curve lying to the right of the efficiency maximum. At the control step (before pulmonary artery hypertension), Ees=1.71 Ea (n=ll). Conclusions: Under control conditions, the right ventricle operates at maximum efficiency and submaximal work output. Compliance of the pulmonary artery is a significant factor in decoupling the right ventricle from its vascular load. As the compliance decreases with acute pulmonary hypertension, the maximum stroke work against load point shifted in such a manner that the right ventricle changed its operational status from a flow to a pressure pump, resulting in a decreased stroke volume. Cardiovascular Research 1992;26:000–000 The aim was to investigate the ventricular/vascular coupling of the intact right heart under conditions of normal operation and acute pulmonary hypertension.OBJECTIVEThe aim was to investigate the ventricular/vascular coupling of the intact right heart under conditions of normal operation and acute pulmonary hypertension.Right ventricular contractility was obtained by calculating the end systolic pressure-volume relationship (Ees) and the effective pulmonary arterial elastance (Ea), applying the Windkessel parameters of the pulmonary arterial input impedance. Coupling between the ventricle and its load could be determined in terms of Ees and Ea. Acute pulmonary hypertension was induced by injecting glass microspheres into the pulmonary vascular bed until a mean pulmonary arterial pressure of more than 35 mm Hg had been reached. Experimental subjects were Landras/Large white pigs (n = 11), studied under general anaesthesia. Ees was obtained by normalising the right ventricle pressure-diameter equivalent of Ees to stroke volume. The lumped element parameters of the Windkessel analogue were calculated from the pulmonary artery pressure and blood flow. Stroke work was calculated from the pressure-volume loop and oxygen consumption derived from the pressure-volume area. Efficiency was taken to be the ratio between stroke work and oxygen consumption.METHODSRight ventricular contractility was obtained by calculating the end systolic pressure-volume relationship (Ees) and the effective pulmonary arterial elastance (Ea), applying the Windkessel parameters of the pulmonary arterial input impedance. Coupling between the ventricle and its load could be determined in terms of Ees and Ea. Acute pulmonary hypertension was induced by injecting glass microspheres into the pulmonary vascular bed until a mean pulmonary arterial pressure of more than 35 mm Hg had been reached. Experimental subjects were Landras/Large white pigs (n = 11), studied under general anaesthesia. Ees was obtained by normalising the right ventricle pressure-diameter equivalent of Ees to stroke volume. The lumped element parameters of the Windkessel analogue were calculated from the pulmonary artery pressure and blood flow. Stroke work was calculated from the pressure-volume loop and oxygen consumption derived from the pressure-volume area. Efficiency was taken to be the ratio between stroke work and oxygen consumption.Ea increased significantly as mean pulmonary artery pressure rose, while Ees remained linear and constant. Stroke work, as well as efficiency, increased, with the maximum of the stroke work curve lying to the right of the efficiency maximum. At the control step (before pulmonary artery hypertension), Ees = 1.71 Ea (n = 11).RESULTSEa increased significantly as mean pulmonary artery pressure rose, while Ees remained linear and constant. Stroke work, as well as efficiency, increased, with the maximum of the stroke work curve lying to the right of the efficiency maximum. At the control step (before pulmonary artery hypertension), Ees = 1.71 Ea (n = 11).Under control conditions, the right ventricle operates at maximum efficiency and submaximal work output. Compliance of the pulmonary artery is a significant factor in decoupling the right ventricle from its vascular load. As the compliance decreases with acute pulmonary hypertension, the maximum stroke work against load point shifted in such a manner that the right ventricle changed its operational status from a flow to a pressure pump, resulting in a decreased stroke volume.CONCLUSIONSUnder control conditions, the right ventricle operates at maximum efficiency and submaximal work output. Compliance of the pulmonary artery is a significant factor in decoupling the right ventricle from its vascular load. As the compliance decreases with acute pulmonary hypertension, the maximum stroke work against load point shifted in such a manner that the right ventricle changed its operational status from a flow to a pressure pump, resulting in a decreased stroke volume. The aim was to investigate the ventricular/vascular coupling of the intact right heart under conditions of normal operation and acute pulmonary hypertension. Right ventricular contractility was obtained by calculating the end systolic pressure-volume relationship (Ees) and the effective pulmonary arterial elastance (Ea), applying the Windkessel parameters of the pulmonary arterial input impedance. Coupling between the ventricle and its load could be determined in terms of Ees and Ea. Acute pulmonary hypertension was induced by injecting glass microspheres into the pulmonary vascular bed until a mean pulmonary arterial pressure of more than 35 mm Hg had been reached. Experimental subjects were Landras/Large white pigs (n = 11), studied under general anaesthesia. Ees was obtained by normalising the right ventricle pressure-diameter equivalent of Ees to stroke volume. The lumped element parameters of the Windkessel analogue were calculated from the pulmonary artery pressure and blood flow. Stroke work was calculated from the pressure-volume loop and oxygen consumption derived from the pressure-volume area. Efficiency was taken to be the ratio between stroke work and oxygen consumption. Ea increased significantly as mean pulmonary artery pressure rose, while Ees remained linear and constant. Stroke work, as well as efficiency, increased, with the maximum of the stroke work curve lying to the right of the efficiency maximum. At the control step (before pulmonary artery hypertension), Ees = 1.71 Ea (n = 11). Under control conditions, the right ventricle operates at maximum efficiency and submaximal work output. Compliance of the pulmonary artery is a significant factor in decoupling the right ventricle from its vascular load. As the compliance decreases with acute pulmonary hypertension, the maximum stroke work against load point shifted in such a manner that the right ventricle changed its operational status from a flow to a pressure pump, resulting in a decreased stroke volume.
Author	Fourie, Pieter R Coetzee, André R Bolliger, Chris T
Author_xml	– sequence: 1 givenname: Pieter R surname: Fourie fullname: Fourie, Pieter R organization: University of Stellenbosch, PO Box 19063, Tygerberg 7505, Republic of South Africa – Department of Medical Physiology and Biochemistry, University of Stellenbosch, PO Box 19063, Tygerberg 7505, Republic of South Africa: P R Fourie – sequence: 2 givenname: André R surname: Coetzee fullname: Coetzee, André R organization: University of Stellenbosch, PO Box 19063, Tygerberg 7505, Republic of South Africa – Department of Medical Physiology and Biochemistry, University of Stellenbosch, PO Box 19063, Tygerberg 7505, Republic of South Africa: P R Fourie – sequence: 3 givenname: Chris T surname: Bolliger fullname: Bolliger, Chris T organization: University of Stellenbosch, PO Box 19063, Tygerberg 7505, Republic of South Africa – Department of Medical Physiology and Biochemistry, University of Stellenbosch, PO Box 19063, Tygerberg 7505, Republic of South Africa: P R Fourie
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Notes	ark:/67375/HXZ-407N6K05-Z ArticleID:26-9-839 Correspondence to Dr Fourie. We are grateful to Emmarentia Badenhorst for technical support and to the Medical Research Council of South Africa and the Harry Crossley Trust for financial support. istex:D292D04D770628C793DB57A06500EFB10C7BB454 ObjectType-Article-2 SourceType-Scholarly Journals-1 ObjectType-Feature-1 content type line 23
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Snippet	Objective: The aim was to investigate the ventricular/vascular coupling of the intact right heart under conditions of normal operation and acute pulmonary... The aim was to investigate the ventricular/vascular coupling of the intact right heart under conditions of normal operation and acute pulmonary hypertension.... The aim was to investigate the ventricular/vascular coupling of the intact right heart under conditions of normal operation and acute pulmonary...
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SubjectTerms	Acute Disease acute pulmonary hypertension Animals Biological and medical sciences Compliance Disease Models, Animal end systolic pressure-diameter relationship Fundamental and applied biological sciences. Psychology Humans Hypertension, Pulmonary - physiopathology Pulmonary Artery - physiology Pulmonary Artery - physiopathology pulmonary artery input impedance Stroke Volume - physiology Swine Ventricular Function, Right - physiology Vertebrates: cardiovascular system
Title	Pulmonary artery compliance: its role in right ventricular-arterial coupling
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