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Restitution Kinetics of Ventricular Action Potential Duration In the Human HeartYamazaki, Masatoshi, Honjo, Haruo, Osaka, Toshiyuki, Yokoyama, Eriko, Ito, Atsushi, Kodama, Itsuo 12 1900 (has links)
国立情報学研究所で電子化したコンテンツを使用している。
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EFFECTS OF ACUTE STRETCH ON CARDIAC ELECTRICAL PROPERTIES IN SWINEAgarwal, Anuj 01 January 2013 (has links)
Stretch is known to result in an electrically less stable ventricular substrate, yet the reported effects of stretch on measured electrophysiological parameters have been inconsistent and even contradictory. The goal of this study was to evaluate the effects of acute mechanical stretch on cardiac electrical features thought to be key in generation of arrhythmia, namely restitution of action potential duration (APD), electrical memory, and onset of alternans.
Microelectrodes were used to record intracellular potentials pre, during, and post-stretch from isolated right ventricular tissues from swine. In separate experiments, the effects of two levels of stretch were quantified. Pacing protocols employing explicit diastolic interval (DI) control and cycle length (CL) control were used to obtain measures of restitution of APD, memory, and alternans of APD. Stretching the tissue had varying effects on APD, restitution and memory. Stretch increased APD, restitution slopes and memory by as much as 24, 30 and 53 % in some cases, while it decreased these by up to 18, 37 and 81 % in others. During stretch, alternans of APD were observed in some cases, which occurred at slower rates of activation than before stretch. Histology of tissue samples showed localized changes in orientation of cells relative to the direction of stretch.
Our results show that among individual trials, stretch altered the measured electrophysiological properties, sometimes markedly. However, when pooled together, these changes cancelled each other and the averages showed no statistically significant difference after stretch. A potential mechanism that explains this divergent and inconsistent response to stretch is the presence of local, micron level, variation in orientation of myocytes. Upon stretch, these divergent effects likely increase dispersion of repolarization diffusely and might thus be the reason behind the consistently observed increase in arrhythmic substrate after stretch.
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DYNAMICS OF ACTION POTENTIAL DURATION: EFFECTS ON RESTITUTION AND REPOLARIZATION ALTERNANSWu, Runze 01 January 2006 (has links)
The presented studies investigate dynamics of action potential duration (APD) tobetter understand the underlying mechanism for repolarization alternans.We recorded trans-membrane potentials (TMP) in canine endocardial muscle tissueusing standard glass microelectrode under the control of an explicit diastolic interval (DI)control pacing protocol, i.e. feedback protocol. During sequential sinusoidal DI activation,the trajectory of APD dynamics has multiple values of APD correspondent to the sameDI, i.e. restitution is a bi-modal relationship. Our results indicate that: 1) there is a delay,similar to hysteresis, of change in APD responding to change in DI, 2) and the timecourse of the delay is asymmetric for fast or slow pacing history. The alternans wasobserved during constant DI pacing, i.e. the DI preceding each APD was invariant orchanged within a limited range. This finding suggests that alternans of APD do not needthe oscillation of preceding DI, i.e. DI dependent restitution is not a necessary conditionfor the alternans. This result implies that DI independent component exists in themechanism of the alternans. Nonetheless, the amplitude of alternans was statisticallylarger during constant pacing cycle length (PCL) pacing than that during constant DIpacing, even though both PCL and DI pacing trials used similar average activation rate.These results also demonstrate the ability of the feedback protocol to analyze the memoryeffects and dissect different components in the mechanism of alternans.Two computational models, Luo-Rudy dynamics (LRD) and cardiac ventricle model(CVM) were used to study the hysteresis in restitution. By perturbing membrane current:L-type calcium current, rapid and slow potassium rectifier, and intracellular calciumtransfer rate in sarcoplasmic reticulum (SR) and using sinusoidal DI pacing sequence, weshowed that the asymmetric calcium current across the membrane and its interaction withcalcium buffer in SR during increasing and decreasing DI phase plays an important rolein the hysteresis. CVM was used to study the alternans during constant DI pacing.However CVM failed to replicate the alternans that occurred in the experiments. Thisresult implies that CVM lacks the electrophysiological kinetics related to alternans thatwas shown in our experiment.
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HYSTERESIS IN REPOLARIZATION OF CARDIAC ACTION POTENTIALS: EFFECTS OF SPATIAL HETEROGENEITY AND SLOW REPOLARIZATION CURRENTSJing, Linyuan 01 January 2013 (has links)
Repolarization alternans, i.e. beat-to-beat variation of repolarization of action potential, is proposed as a predictor of life-threatening arrhythmias. Restitution relates repolarization duration with its previous relaxation time, i.e. diatstolic interval (DI), and is considered a dominant mechanism for alternans. Previously, we observed that different repolarization durations at the same DI during decelerating and accelerating pacing, i.e. restitution displays hysteresis, which is a measure of “cardiac memory”.
Objective of the current study was to investigate in the pig 1) the mechanism for a previously observed hysteresis type phenomenon, where alternans, once started at higher heart rate, persists even when heart rate decreases below its initiating rate, 2) regional differences in expression of hysteresis, i.e. memory in restitution in the heart, and 3) changes in restitution and memory during manipulation of an important repolarization current, the slow delayed rectifier, IKs.
Action potentials were recorded in pig ventricular tissues using microelectrodes. Regional differences were explored in endocardial and epicardial tissues from both ventricles. DIs were explicitly controlled in real time to separate restitution mechanism from non-restitution related effects. Stepwise protocols were used to explore the existence in hysteresis in alternans threshold, where DIs were held constant for each step and progressively decreased and then increased. Quantification of cardiac memory was achieved by sinusoidally changing DI protocols, which were used to investigate memory changes among myocytes from different regions of the heart and during IKs manipulation.
Results show that during stepwise protocol, hysteresis in alternans still existed, which indicates that restitution is not the only mechanism underlying the hysteresis. When comparing hysteresis obtained from sinusoidally oscillatory DIs among different regions, results show memory is expressed differently with endocardium expressing the most and epicardium the least memory. This provides important implications about the location where arrhythmia would initiate. Results also show that measures for hysteresis loops obtained by sinusoidal DI protocols decreased (increased) after enhancement (attenuation) of IKs, suggesting decreased (increased) hysteresis, i.e. memory in restitution. This effect needs to be considered during drug development.
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INVESTIGATION OF CARDIAC ELECTROPHYSIOLOGY IN HUMAN VENTRICULAR TISSUEBrownson, Kathleen 01 January 2014 (has links)
Individuals with cardiomyopathy are at higher risk to die from sudden cardiac arrest than those with non-failing (NF) hearts. This study examined the differences in electrical properties of failing and NF human hearts in terms of cardiac memory through explicit control of diastolic intervals in a sinusoidal fashion, restitution of action potential duration (APD) through standard and dynamic pacing protocols, maximum rate of depolarization and APD alternans. Recordings of transmembrane potentials were made in tissues extracted from patients with heart failure and one donor NF heart. Computational simulations were performed using the O’Hara Rudy model for generating surrogates of control data. Significant differences were seen between left ventricular (LV) tissue and NF LV tissue in tilt, and measures of memory in terms of area and thickness during the sinusoidal 400ms protocol. Minimum delay was also significantly higher in the failing LV during the sinusoidal 150ms protocol. Failing tissues showed a higher restitution slope and prolonged AP which is consistent with previous studies and is hypothesized to contribute to the increased susceptibility to unstable alternans. This study further explored how disease alters the electrical functioning of the heart and why these patients are at a higher risk of ventricular arrhythmia.
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Ratiometric fluorescence imaging and marker-free motion tracking of Langendorff perfused beating rabbit heartsKappadan, Vineesh 14 July 2020 (has links)
No description available.
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The role of the perinexus in Long QT Syndrome Type 3Wu, Xiaobo 13 February 2023 (has links)
Gain of function of cardiac voltage-gated sodium channel (Nav1.5) leads to Long QT Syndrome Type 3 (LQT3). LQT3 phenotype can be exacerbated by expanding the perinexus, which is an intercellular nanodomain with high density of Nav1.5 in the intercalated disc. Following this finding, we found that elevating extracellular sodium and widening the perinexus synergistically exacerbated LQT3 phenotype, Importantly, we also found that perinexal expansion increases the susceptibility to cardiac arrest in aged LQT3, which demonstrated that perinexal expansion is an arrhythmogenic risk especially in aged LQT3 patients. Furthermore, we observed that the perinexus narrows with aging and conceals LQT3 phenotype, which suggests that perinexal narrowing may have a cardio-protective role during aging in LQT3. Surprisingly, following the finding of the synergistic effect of extracellular sodium elevation and perinexal widening on LQT3 phenotype in drug-induced LQT3 guinea pig hearts, we found that this synergistic effect was not observed in genetically-modified LQT3 mouse hearts, which is due to high sodium also increasing transient outward potassium current (Ito). In summary, the whole project investigated the role of the perinexus in LQT3 from different conditions including sodium, aging and species. The findings in this project discovered the importance of perinexal expansion in LQT3 and also the involvement of Ito in sodium regulating LQT3 phenotype in hearts which functionally express Ito channels. Therefore, a LQT3 animal model which has similar electrophysiology close to human may be a great option for translational purpose. / Doctor of Philosophy / Long QT Syndrome Type 3 (LQT3) is an inherited heart disease with the phenotype of long QT interval in ECG. It has been found that LQT3 phenotype gets worse when a very tiny space in the heart, termed as the perinexus, is wide due to cardiac edema. Following this finding, we also found that increasing sodium concentration together with wide perinexus can further exacerbate LQT3 phenotype in guinea pig hearts. Furthermore, we found that widening the perinexus in aged LQT3 hearts causes cardiac death but not in adult, which suggests that perinexal widening worsens LQT3 phenotype and even leads to cardiac death in aged hearts. Besides, we found that the perinexus narrows with aging and there is no difference in LQT3 phenotype between adult and aged hearts, which suggests that the narrow perinexus during aging may protect the hearts from cardiac death in LQT3. Surprisingly, we discovered that increasing sodium and widening the perinexus together fails to exacerbate LQT3 phenotype when compared with widening the perinexus alone in LQT3 mouse hearts, which is due to high sodium increasing transient outward potassium current (Ito). Notably, Ito channels are not functionally expressed in guinea pig hearts. In summary, the whole project investigated the role of the perinexus in LQT3 from different conditions including sodium, aging and species. The findings in this project discovered the importance of perinexal expansion in LQT3 and also the involvement of Ito in sodium regulating LQT3 phenotype in hearts. Therefore, a LQT3 animal model which has similar electrophysiology close to human may be a great option for translational purpose.
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Electrophysiological and structural determinants of electrotonic modulation of repolarization by the activation sequenceWalton, R.D., Benson, A.P., Hardy, Matthew E., White, E., Bernus, O. 10 August 2013 (has links)
Yes / Spatial dispersion of repolarization is known to play an important role in arrhythmogenesis. Electrotonic modulation of repolarization by the activation sequence has been observed in some species and tissue preparations, but to varying extents. Our study sought to determine the mechanisms underlying species- and tissue-dependent electrotonic modulation of repolarization in ventricles. Epi-fluorescence optical imaging of whole rat hearts and pig left ventricular wedges were used to assess epicardial spatial activation and repolarization characteristics. Experiments were supported by computer simulations using realistic geometries. Tight coupling between activation times (AT) and action potential duration (APD) were observed in rat experiments but not in pig. Linear correlation analysis found slopes of −1.03 ± 0.59 and −0.26 ± 0.13 for rat and pig, respectively (p < 0.0001). In rat, maximal dispersion of APD was 11.0 ± 3.1 ms but dispersion of repolarization time (RT) was relatively homogeneous (8.2 ± 2.7, p < 0.0001). However, in pig no such difference was observed between the dispersion of APD and RT (17.8 ± 6.1 vs. 17.7 ± 6.5, respectively). Localized elevations of APD (12.9 ± 8.3%) were identified at ventricular insertion sites of rat hearts both in experiments and simulations. Tissue geometry and action potential (AP) morphology contributed significantly to determining influence of electrotonic modulation. Simulations of a rat AP in a pig geometry decreased the slope of AT and APD relationships by 70.6% whereas slopes were increased by 75.0% when implementing a pig AP in a rat geometry. A modified pig AP, shortened to match the rat APD, showed little coupling between AT and APD with greatly reduced slope compared to the rat AP. Electrotonic modulation of repolarization by the activation sequence is especially pronounced in small hearts with murine-like APs. Tissue architecture and AP morphology play an important role in electrotonic modulation of repolarization.
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Die Effekte der Ca2+-Calmodulin-abhängigen Proteinkinase II (CaMKII) auf die Aktionspotential-morphologie bei mechanischer Last / The effects of Calcium2+/Calmodulin-dependent protein kinase II (CaMKII) on action potential morphology under mechanical loadGupta, Shamindra Nath 29 October 2013 (has links)
No description available.
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Dynamic Action Potential Restitution Contributes to Mechanical Restitution in Right Ventricular Myocytes From Pulmonary Hypertensive RatsHardy, Matthew E., Pervolaraki, E., Bernus, O., White, E. 2018 February 1923 (has links)
Yes / We investigated the steepened dynamic action potential duration (APD) restitution
of rats with pulmonary artery hypertension (PAH) and right ventricular (RV) failure
and tested whether the observed APD restitution properties were responsible for
negative mechanical restitution in these myocytes. PAH and RV failure were provoked
in male Wistar rats by a single injection of monocrotaline (MCT) and compared
with saline-injected animals (CON). Action potentials were recorded from isolated RV
myocytes at stimulation frequencies between 1 and 9Hz. Action potential waveforms
recorded at 1Hz were used as voltage clamp profiles (action potential clamp) at
stimulation frequencies between 1 and 7Hz to evoke rate-dependent currents. Voltage
clamp profiles mimicking typical CON and MCT APD restitution were applied and cell
shortening simultaneously monitored. Compared with CON myocytes, MCT myocytes
were hypertrophied; had less polarized diastolic membrane potentials; had action
potentials that were triggered by decreased positive current density and shortened
by decreased negative current density; APD was longer and APD restitution steeper.
APD90 restitution was unchanged by exposure to the late Na+-channel blocker
(5μM) ranolazine or the intracellular Ca2+ buffer BAPTA. Under AP clamp, stimulation
frequency-dependent inward currents were smaller inMCTmyocytes and were abolished
by BAPTA. In MCT myocytes, increasing stimulation frequency decreased contraction
amplitude when depolarization duration was shortened, to mimic APD restitution, but
not when depolarization duration was maintained. We present new evidence that the
membrane potential of PAH myocytes is less stable than normal myocytes, being
more easily perturbed by external currents. These observations can explain increased
susceptibility to arrhythmias. We also present novel evidence that negative APD
restitution is at least in part responsible for the negative mechanical restitution in PAH
myocytes. Thus, our study links electrical restitution remodeling to a defining mechanical
characteristic of heart failure, the reduced ability to respond to an increase in demand.
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