2015
DOI: 10.1152/ajpheart.00436.2015
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What global diastolic function is, what it is not, and how to measure it

Abstract: Leonardo da Vinci's observation (circa 1511) that "the atria or filling chambers contract together while the pumping chambers or ventricles are relaxing and vice versa," the dynamics of four-chamber heart function, and of diastolic function (DF) in particular, are not generally appreciated. We view DF from a global perspective, while characterizing it in terms of causality and clinical relevance. Our models derive from the insight that global DF is ultimately a result of forces generated by elastic recoil, mod… Show more

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Cited by 28 publications
(32 citation statements)
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References 135 publications
(164 reference statements)
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“…Conventional indices such as E/A, DT and e′ are the result, rather the cause, of this interplay and cannot independently quantify relaxation or stiffness. 66 Thus, for the purpose of LV diastolic function assessment, no single variable has proven to be sufficiently accurate, and therefore, algorithm-based decision trees composed of several parameters are recommended. The most recent American Society of Echocardiography guidelines for the use of echocardiography in the assessment of LV diastolic function have identified the following 4 variables to be the most useful for this purposemitral E/A ratio, average E/e′, LA volume index, and peak tricuspid regurgitation velocity.…”
Section: Diastolic Dysfunction and Lvfpmentioning
confidence: 99%
“…Conventional indices such as E/A, DT and e′ are the result, rather the cause, of this interplay and cannot independently quantify relaxation or stiffness. 66 Thus, for the purpose of LV diastolic function assessment, no single variable has proven to be sufficiently accurate, and therefore, algorithm-based decision trees composed of several parameters are recommended. The most recent American Society of Echocardiography guidelines for the use of echocardiography in the assessment of LV diastolic function have identified the following 4 variables to be the most useful for this purposemitral E/A ratio, average E/e′, LA volume index, and peak tricuspid regurgitation velocity.…”
Section: Diastolic Dysfunction and Lvfpmentioning
confidence: 99%
“…The mechanisms involved in left ventricular (LV) diastolic filling and their relative importance remain an area of active investigation12345678. Understanding the physiology of normal LV filling can advance characterization of the pathophysiology of diastolic dysfunction and consequently help in identifying optimal diagnostic metrics as well as targets for treatment.…”
mentioning
confidence: 99%
“…Understanding the physiology of normal LV filling can advance characterization of the pathophysiology of diastolic dysfunction and consequently help in identifying optimal diagnostic metrics as well as targets for treatment. The main mechanisms known to act during LV diastolic filling are active relaxation4, restoring forces generated by elastic energy stored within the myocardium1910 and atrial contraction.…”
mentioning
confidence: 99%
“…IVR is generally regarded as a pure relaxation dependent process, however, shape changes of the ventricle during IVR have been observed, implying that elastic recoil forces simultaneously distract the myocardium as the cross-bridge uncoupling occurs (26). Similarly, during and throughout the early rapid filling phase, viewed as a process determined by suction from the elastic recoil, the cross-bridge uncoupling continues, acting as a resistive force (a break) to the ventricular distention produced by the elastic recoil forces (26). When relaxation occurs faster than ventricular filling, the negative atrioventricular pressure gradient created produces the diastolic ventricular suction (26).…”
Section: Diastolic Functionmentioning
confidence: 99%
“…Similarly, during and throughout the early rapid filling phase, viewed as a process determined by suction from the elastic recoil, the cross-bridge uncoupling continues, acting as a resistive force (a break) to the ventricular distention produced by the elastic recoil forces (26). When relaxation occurs faster than ventricular filling, the negative atrioventricular pressure gradient created produces the diastolic ventricular suction (26). The ventricular suction is made possible by optimal and fast active relaxation of the myocardium, a process that requires energy.…”
Section: Diastolic Functionmentioning
confidence: 99%