Single‐beat estimation of the left ventricular end‐systolic pressure–volume relationship in patients with heart failure

Brinke, Ellen A. ten; Klautz, Robert J.M.; Verwey, Harriëtte F.; Wall, Ernst E. van der; Dion, Robert; Steendijk, Paul

doi:10.1111/j.1748-1716.2009.02040.x

Cited by 43 publications

(30 citation statements)

References 26 publications

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“…Near end-systole, when the cardiac muscle reaches its maximum state of activation, the relation between the ventricular pressure P m and the ventricular volume V m is known as the end-systolic pressurevolume relation ESPVR. 1,[3][4][5][6][8][9][10][11][12][13][14][15][16][28][29][30][31] In the study of the linear approximation of the ESPVR special attention has been given to the way the slope E max of the ESPVR and the intercept V om of the ESPVR with the volume axis can be applied for the purpose of clinical diagnosis. One of the difficulties in applying the ESPVR in clinical diagnosis is the difficulty to calculate the parameters of the ESPVR in a non-invasive way from several PVR loops, and more recently attempts have been made to determine these parameters from single loop measurements (for a critical review, see Kjorstad, et al).…”

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confidence: 99%

Ejection Fraction and ESPVR

Shoucri

2013

Int. Heart J.

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SummaryA formula derived by using large elastic deformation for the contraction of the myocardium is used to describe the pressure-volume relation (PVR) in the heart left ventricle, it is also used to calculate a mathematical expression for the non-linear end-systolic pressure-volume relation (ESPVR) in the left ventricle. An important feature of the mathematical formalism used is the inclusion of the isovolumic pressure P iso (equal active pressure generated by the myocardium) in the formalism describing the PVR. Relations between the ejection fraction (EF) and parameters describing the non-linear ESPVR are presented. It is shown that the non-linear ESPVR offers a rich collection of parameters that can be used to study the performance of the ventricles, like the areas under the ESPVR (units of energy) or the ordinates of the ESPVR (units of pressure), slopes and intercepts of the curves involved. The mathematical procedure can be easily implemented in a non-invasive way in routine clinical work when ratios of variables are calculated, it necessitates only the non-invasive measurement of the dimensions of the ventricles. Applications to clinical data published in the literature are presented, and they give results that show the consistency of the mathematical formalism used. The implications of the results of this research work on the study of the problem of heart failure with normal or preserved ejection fraction (HFpEF) are discussed. (Int Heart J 2013; 54: 318-327) Key words: Cardiac mechanics, Mathematical physiology of the heart, Pressure volume relation in ventricles, Active pressure of myocardium, Peak isovolumic pressure, End-systolic pressure-volume relation, Heart failure with preserved ejection fraction HFpEF T he study of the pressure-volume relation (PVR) in the left or right ventricle has been the object of intensive attention in the scientific literature. Near end-systole, when the cardiac muscle reaches its maximum state of activation, the relation between the ventricular pressure P m and the ventricular volume V m is known as the end-systolic pressurevolume relation ESPVR. 1,[3][4][5][6][8][9][10][11][12][13][14][15][16][28][29][30][31] In the study of the linear approximation of the ESPVR special attention has been given to the way the slope E max of the ESPVR and the intercept V om of the ESPVR with the volume axis can be applied for the purpose of clinical diagnosis. One of the difficulties in applying the ESPVR in clinical diagnosis is the difficulty to calculate the parameters of the ESPVR in a non-invasive way from several PVR loops, and more recently attempts have been made to determine these parameters from single loop measurements (for a critical review, see Kjorstad, et al). 11)The introduction of the active pressure generated by the myocardium on its inner surface (endocardium) (also called isovolumic pressure P iso by physiologists) in the formalism describing the PVR or the ESPVR in the ventricles has been the main idea of a series of studies published by the author. [17][18][19]...

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Ejection Fraction and ESPVR

Shoucri

2013

Int. Heart J.

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“…ESPVR was established by the actual end-systolic and the predicted isovolumic pressure-volume point. The latter was estimated by fitting a 5 th -order degree polynomial function to LV pressure curve data from end-diastole to maximum rate of pressure rise and from maximum rate of pressure fall to 90% pressure decay, as described by ten Brinke et al (38). As for EDPVR we applied the single-beat method first proposed by Zile et al (41) which consists of deriving a corrected LV pressure excluding the active component of pressure decay due to relaxation as predicted by monoexponential fitting of time constant of isovolumic relaxation .…”

Section: Methodsmentioning

confidence: 99%

Spectral transfer function analysis of respiratory hemodynamic fluctuations predicts end-diastolic stiffness in preserved ejection fraction heart failure

Abdellatif

Leite

Alaa

et al. 2016

American Journal of Physiology-Heart and Circulatory Physiology

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Falcão-Pires I, Leite-Moreira AF, Lourenço AP. Spectral transfer function analysis of respiratory hemodynamic fluctuations predicts end-diastolic stiffness in preserved ejection fraction heart failure. Am J Physiol Heart Circ Physiol 310: H4 -H13, 2016. First published October 16, 2015 doi:10.1152/ajpheart.00399.2015.-Preserved ejection fraction heart failure (HFpEF) diagnosis remains controversial, and invasive left ventricular (LV) hemodynamic evaluation and/or exercise testing is advocated by many. The stiffer HFpEF myocardium may show impaired stroke volume (SV) variation induced by fluctuating LV filling pressure during ventilation. Our aim was to investigate spectral transfer function (STF) gain from end-diastolic pressure (EDP) to indexed SV (SV i) in experimental HFpEF. Eighteen-weekold Wistar-Kyoto (WKY) and ZSF1 lean (ZSF1 Ln) and obese rats (ZSF1 Ob) randomly underwent LV open-chest (OC, n ϭ 8 each group) or closed-chest hemodynamic evaluation (CC, n ϭ 6 each group) under halogenate anesthesia and positive-pressure ventilation at constant inspiratory pressure. Beat-to-beat fluctuations in hemodynamic parameters during ventilation were assessed by STF. Enddiastolic stiffness (␤ i) and end-systolic elastance (Eesi) for indexed volumes were obtained by inferior vena cava occlusion in OC (multibeat) or single-beat method estimates in CC. ZSF1 Ob showed higher EDP spectrum (P Ͻ 0.001), higher STF gain between enddiastolic volume and EDP, and impaired STF gain between EDP and SV i compared with both hypertensive ZSF1 Ln and normotensive WKY controls (P Ͻ 0.001). Likewise ␤ i was only higher in ZSF1 Ob while Eesi was raised in both ZSF1 groups. On multivariate analysis ␤ i and not Eesi correlated with impaired STF gain from EDP to SVi (P Ͻ 0.001), and receiver-operating characteristics analysis showed an area under curve of 0.89 for higher ␤i prediction (P Ͻ 0.001).Results support further clinical testing of STF analysis from right heart catheterization-derived EDP surrogates to noninvasively determined SV as screening/diagnostic tool to assess myocardial stiffness in HFpEF.heart failure with preserved ejection fraction; spectral analysis; spectral transfer function; myocardial stiffness HEART FAILURE (HF) with preserved ejection fraction (HFpEF) accounts for a rising proportion of over 50% of HF cases (25) and remains one of the unmet cardiovascular research challenges. Although it may constitute a heterogeneous disorder with complex determinants (32), most experts believe abnormalities in myocardial relaxation and compliance that develop under the influence of aging and comorbidities are the main underlying pathophysiological mechanisms (12). Diagnosis remains challenging and controversial. Biomarkers and noninvasive echocardiographic indexes would be desirable (26) but many question their accuracy and sensitivity based on invasively derived left ventricular (LV) hemodynamic evaluation and exercise testing in asymptomatic patients (27). In a small proof-of-concept study carried out in HFpEF patients and a...

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“…В начале систолы направленная вперед от сокращения желудоч-ков энергия импульса способствует увеличению давления и прямому потоку в проксимальном отделе аорты. Если в проксимальном отделе аорты волновое сопротивление является высо-ким из-за жесткой стенки, небольшого диаме-тра аорты или того и другого, то степень повы-шения давления относительно больше в начале выброса [17,29,33,43]. Время прибытия отра-женной волны к восходящей аорте зависит от расположения отраженных участков и скорости пульсовой волны (СПВ) в сосудах, в частности в аорте, которая способна проводить волны как вперед, так и назад [27,43].…”

Section: сердечно-сосудистое сопряжение: его компоненты и возможностиunclassified

“…Если в проксимальном отделе аорты волновое сопротивление является высо-ким из-за жесткой стенки, небольшого диаме-тра аорты или того и другого, то степень повы-шения давления относительно больше в начале выброса [17,29,33,43]. Время прибытия отра-женной волны к восходящей аорте зависит от расположения отраженных участков и скорости пульсовой волны (СПВ) в сосудах, в частности в аорте, которая способна проводить волны как вперед, так и назад [27,43]. СПВ в аорте име-ет прямую связь с жесткостью стенки аорты (квадратный корень из модуля упругости) и об-ратно пропорциональна квадратному корню из диаметра аорты [17,29,30,33].…”

Section: сердечно-сосудистое сопряжение: его компоненты и возможностиunclassified

Cardiovascular pairing: modern methods of estimation, prognostic significance and possible clinical use in acute decompensation of chronic heart failure

Nikolayeva¹,

Jirov²,

Uskach³

et al. 2015

Medical news of the North Caucasus

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Хроническая сердечная недостаточность занимает одно из ведущих мест в структуре сердеч-но-сосудистых событий. Более половины таких больных, согласно результатам исследования ЭПОХА-ХСН, имеют сохранную систолическую функцию левого желудочка. Несмотря на накоплен-ный с годами внушительный опыт диагностики и лечения таких больных, смертность от хрониче-ской сердечной недостаточности продолжает оставаться одной из ведущих проблем российского здравоохранения, на сегодняшний день экономически наиболее затратных. На основании этого представляется актуальным обсудить, опираясь на данные современных методов обследования, изменение сердечно-сосудистого сопряжения, эффективной артериальной жесткости и конечной систолической жесткости левого желудочка как потенциальных терапевтических мишеней для по-лучения более точного представления о последствиях вмешательств на сердечную функцию. Ключевые слова: сердечно-сосудистое сопряжение, хроническая сердечная недостаточность, систолическая функция левого желудочка, эффективная артериальная жесткость, конечная систо-лическая жесткость левого желудочкаChronic heart failure takes one of the leading places in the structure of cardiovascular events. More than half of these patients, according to a study ЭПОХА-ХСН, has preserved systolic left ventricular function. Despite the accumulated over the years, an impressive experience of diagnosis and treatment of these patients, the mortality rate due to chronic heart failure continues to be one of the leading health problems of the Russian Federation. It is important to discuss, based on the data of modern methods of inspection, modification of the cardiovascular coupling, effective arterial stiffness and end-systolic left ventricular stiffness as potential therapeutic targets for a more accurate picture of the impact of interventions on cardiac function.

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Single‐beat estimation of the left ventricular end‐systolic pressure–volume relationship in patients with heart failure

Abstract: Our findings, obtained in hearts spanning a wide range of sizes and conditions, support the use of the SB method. This method ultimately facilitates less invasive ESPVR estimation, particularly when coupled with emerging noninvasive techniques to measure LV pressures and volumes.

Cited by 43 publications

References 26 publications

Ejection Fraction and ESPVR

Ejection Fraction and ESPVR

Spectral transfer function analysis of respiratory hemodynamic fluctuations predicts end-diastolic stiffness in preserved ejection fraction heart failure

Cardiovascular pairing: modern methods of estimation, prognostic significance and possible clinical use in acute decompensation of chronic heart failure

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