Your search keyword '"Frank–Starling"' showing total 5 results

1. Piezo buffers mechanical stress via modulation of intracellular Ca2+ handling in the Drosophila heart.

Author

Zechini, Luigi, Camilleri-Brennan, Julian, Walsh, Jonathan, Beaven, Robin, Moran, Oscar, Hartley, Paul S., Diaz, Mary, and Denholm, Barry

Subjects

STRAINS & stresses (Mechanics), CARDIAC contraction, DROSOPHILA, MYOCARDIUM, MECHANICAL ability

Abstract

Throughout its lifetime the heart is buffeted continuously by dynamic mechanical forces resulting from contraction of the heart muscle itself and fluctuations in haemodynamic load and pressure. These forces are in flux on a beat-by-beat basis, resulting from changes in posture, physical activity or emotional state, and over longer timescales due to altered physiology (e.g. pregnancy) or as a consequence of ageing or disease (e.g. hypertension). It has been known for over a century of the heart's ability to sense differences in haemodynamic load and adjust contractile force accordingly (Frank, Z. biology, 1895, 32, 370-447; Anrep, J. Physiol., 1912, 45 (5), 307-317; Patterson and Starling, J. Physiol., 1914, 48 (5), 357-79; Starling, The law of the heart (Linacre Lecture, given at Cambridge, 1915), 1918). These adaptive behaviours are important for cardiovascular homeostasis, but the mechanism(s) underpinning them are incompletely understood. Here we present evidence that the mechanically-activated ion channel, Piezo, is an important component of the Drosophila heart's ability to adapt to mechanical force. We find Piezo is a sarcoplasmic reticulum (SR)-resident channel and is part of a mechanism that regulates Ca2+ handling in cardiomyocytes in response to mechanical stress. Our data support a simple model in which Drosophila Piezo transduces mechanical force such as stretch into a Ca2+ signal, originating from the SR, that modulates cardiomyocyte contraction. We show that Piezo mutant hearts fail to buffer mechanical stress, have altered Ca2+ handling, become prone to arrhythmias and undergo pathological remodelling. [ABSTRACT FROM AUTHOR]

Published

2022

2. Piezo buffers mechanical stress via modulation of intracellular Ca2+ handling in the Drosophila heart

Author

Luigi Zechini, Julian Camilleri-Brennan, Jonathan Walsh, Robin Beaven, Oscar Moran, Paul S. Hartley, Mary Diaz, and Barry Denholm

Subjects

Piezo, mechanotransduction, Frank-Starling, Drosophila, heart, calcium, Physiology, QP1-981

Abstract

Throughout its lifetime the heart is buffeted continuously by dynamic mechanical forces resulting from contraction of the heart muscle itself and fluctuations in haemodynamic load and pressure. These forces are in flux on a beat-by-beat basis, resulting from changes in posture, physical activity or emotional state, and over longer timescales due to altered physiology (e.g. pregnancy) or as a consequence of ageing or disease (e.g. hypertension). It has been known for over a century of the heart’s ability to sense differences in haemodynamic load and adjust contractile force accordingly (Frank, Z. biology, 1895, 32, 370–447; Anrep, J. Physiol., 1912, 45 (5), 307–317; Patterson and Starling, J. Physiol., 1914, 48 (5), 357–79; Starling, The law of the heart (Linacre Lecture, given at Cambridge, 1915), 1918). These adaptive behaviours are important for cardiovascular homeostasis, but the mechanism(s) underpinning them are incompletely understood. Here we present evidence that the mechanically-activated ion channel, Piezo, is an important component of the Drosophila heart’s ability to adapt to mechanical force. We find Piezo is a sarcoplasmic reticulum (SR)-resident channel and is part of a mechanism that regulates Ca2+ handling in cardiomyocytes in response to mechanical stress. Our data support a simple model in which Drosophila Piezo transduces mechanical force such as stretch into a Ca2+ signal, originating from the SR, that modulates cardiomyocyte contraction. We show that Piezo mutant hearts fail to buffer mechanical stress, have altered Ca2+ handling, become prone to arrhythmias and undergo pathological remodelling.

Published

2022

3. Historical perspective on heart function: the Frank-Starling Law.

Author

Sequeira, Vasco and Velden, Jolanda

Abstract

More than a century of research on the Frank-Starling Law has significantly advanced our knowledge about the working heart. The Frank-Starling Law mandates that the heart is able to match cardiac ejection to the dynamic changes occurring in ventricular filling and thereby regulates ventricular contraction and ejection. Significant efforts have been attempted to identify a common fundamental basis for the Frank-Starling heart and, although a unifying idea has still to come forth, there is mounting evidence of a direct relationship between length changes in individual constituents (cardiomyocytes) and their sensitivity to Ca ions. As the Frank-Starling Law is a vital event for the healthy heart, it is of utmost importance to understand its mechanical basis in order to optimize and organize therapeutic strategies to rescue the failing human heart. The present review is a historic perspective on cardiac muscle function. We 'revive' a century of scientific research on the heart's fundamental protein constituents (contractile proteins), to their assemblies in the muscle (the sarcomeres), culminating in a thorough overview of the several synergistically events that compose the Frank-Starling mechanism. It is the authors' personal beliefs that much can be gained by understanding the Frank-Starling relationship at the cellular and whole organ level, so that we can finally, in this century, tackle the pathophysiologic mechanisms underlying heart failure. [ABSTRACT FROM AUTHOR]

Published

2015

4. Differential contribution of cardiac sarcomeric proteins in the myofibrillar force response to stretch.

Author

Ait mou, Younss, Guennec, Jean-Yves, Mosca, Emilio, de Tombe, Pieter P., and Cazorla, Olivier

Subjects

*CYTOPLASMIC filaments, *MYOCARDIUM, *HEART cells, *ENDOCARDIUM, *MYOFIBROBLASTS, *PHYSIOLOGY

Abstract

The present study examined the contribution of myofilament contractile proteins to regional function in guinea pig myocardium. We investigated the effect of stretch on myofilament contractile proteins, Ca2+ sensitivity, and cross-bridge cycling kinetics ( K tr) of force in single skinned cardiomyocytes isolated from the sub-endocardial (ENDO) or sub-epicardial (EPI) layer. As observed in other species, ENDO cells were stiffer, and Ca2+ sensitivity of force at long sarcomere length was higher compared with EPI cells. Maximal K tr was unchanged by stretch, but was higher in EPI cells possibly due to a higher α-MHC content. Submaximal Ca2+-activated K tr increased only in ENDO cells with stretch. Stretch of skinned ENDO muscle strips induced increased phosphorylation in both myosin-binding protein C and myosin light chain 2. We concluded that transmural MHC isoform expression and differential regulatory protein phosphorylation by stretch contributes to regional differences in stretch modulation of activation in guinea pig left ventricle. [ABSTRACT FROM AUTHOR]

Published

2008

5. Hypovolemia explains the reduced stroke volume at altitude

Author

Christoph Siebenmann, Carsten Lundby, Mike Hug, Stefanie Keiser, Johannes J. van Lieshout, Peter Vestergaard Rasmussen, Andrea Müller, Amsterdam Cardiovascular Sciences, General Internal Medicine, University of Zurich, and Siebenmann, Christoph

Subjects

Tachycardia, medicine.medical_specialty, Cardiac output, Physiology, Acclimatization, 610 Medicine & health, Blood volume, heart, Frank–Starling, 2737 Physiology (medical), Altitude, blood, Physiology (medical), Internal medicine, Hypovolemia, medicine, Original Research, Frank–Starling law of the heart, hypoxia, business.industry, 1314 Physiology, Stroke volume, Hypoxia (medical), 10076 Center for Integrative Human Physiology, Cardiology, 570 Life sciences, biology, medicine.symptom, business

Abstract

During acute altitude exposure tachycardia increases cardiac output (Q) thus preserving systemic O2 delivery. Within days of acclimatization, however, Q normalizes following an unexplained reduction in stroke volume (SV). To investigate whether the altitude-mediated reduction in plasma volume (PV) and hence central blood volume (CBV) is the underlying mechanism we increased/decreased CBV by means of passive whole body head-down (HDT) and head-up (HUT) tilting in seven lowlanders at sea level (SL) and after 25/26 days of residence at 3454 m. Prior to the experiment on day 26, PV was normalized by infusions of a PV expander. Cardiovascular responses to whole body tilting were monitored by pulse contour analysis. After 25/26 days at 3454 m PV and blood volume decreased by 9 ± 4% and 6 ± 2%, respectively (P < 0.001 for both). SV was reduced compared to SL for each HUT angle (P < 0.0005). However, the expected increase in SV from HUT to HDT persisted and ended in the same plateau as at SL, albeit this was shifted 18 ± 20° toward HDT (P = 0.019). PV expansion restored SV to SL during HUT and to an ∼8% higher level during HDT (P = 0.003). The parallel increase in SV from HUT to HDT at altitude and SL to a similar plateau demonstrates an unchanged dependence of SV on CBV, indicating that the reduced SV during HUT was related to an attenuated CBV for a given tilt angle. Restoration of SV by PV expansion rules out a significant contribution of other mechanisms, supporting that resting SV at altitude becomes reduced due to a hypovolemia.

Published

2013