Stretch-induced changes in arrhythmogenesis and excitability in experimentally based heart cell models

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Stretch-induced changes in arrhythmogenesis and excitability in experimentally based heart cell models

Tara L. Riemer, Eric A. Sobie, and Leslie Tung

Department of Biomedical Engineering, Johns Hopkins University, Baltimore, Maryland 21205

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
Appendix
References

Mechanoelectric coupling in the heart is well documented and has been suggested as a cause of arrhythmia. One hypothesizedmechanism for the stretch sensitivity of cardiac muscle is thepresence of stretch-activated channels (SACs). This study usesmodeling to explore the influence of SACs on cardiac resting potential,excitation threshold, and action potential in the context of arrhythmia.We added a putative SAC, modeled as a linear, time-independentconductance with reversal potential of $-$ 20 or $-$ 50 mV, to guineapig and frog ventricular membrane models. Increased stretch conductanceled to resting potential depolarization, a decreased excitationthreshold, altered action potential duration, and, under certainconditions, early afterdepolarizations. We conclude that stretchincreases cellular excitability, making the heart prone to ectopicactivity. Regional effects of stretch on action potential durationcan vary and are influenced by factors such as the SAC reversalpotential, ionic conditions, and baseline currents, all of whichmay lead to an increased dispersion of refractoriness throughoutthe heart and therefore an increased risk of arrhythmia.

mechanoelectric coupling; electrical stimulation; cardiac myocytes; stretch-activated channels; mathematical model

	INTRODUCTION

Top Abstract Introduction Methods Results Discussion Appendix References

THE EXISTENCE of cardiac mechanoelectric coupling (the influence of mechanical events on the electrical state of the heart)is well established (for reviews, see Refs. 13 and 27). Clinically,an increased prevalence of arrhythmia is reported for hearts thathave been mechanically compromised by congestive heart failure(12, 34) or for hearts that have been exposed to pressureoverload through hypertension (46) or aortic valve disease (9).In vitro studies have shown that sudden incidents of cardiac tissuestretch can result in extrasystoles or the formation of arrhythmia(14, 19). It has been hypothesized that stretch-activatedchannels (SACs) contribute to cellular membrane potential changesand therefore are the underlying cellular substrate for mechanoelectriccoupling and stretch-induced arrhythmias (15, 47).

Stretch of cardiac tissue, cells, or cell membranes has been repeatedly observed to alter resting potential (V_rest) and actionpotentials. Stretch-induced changes in V_rest, although variedin magnitude, generally act to depolarize the transmembrane potential(V_m). Rapid, pulsatile increases in muscle length or ventricularvolume produce transient depolarizations of V_rest that can leadto extrasystoles (15, 47). Contrary to this consistent patternof changes in V_rest, stretch-induced action potential changesare highly variable (13, 27). Because a change in action potentialduration (APD) through the consequent heterogeneity of refractoriness(18), dispersion of repolarization (24), formation of earlyafterdepolarizations (EADs) (36), or wavelength shortening (38)may be a critical factor involved in arrhythmia formation, thevariability in action potential shape and duration is importantto characterize. An accelerated repolarization caused by tissueor cellular stretch, indicated by a reduction in APD as measurednear final repolarization [i.e., APD at 90% repolarization (APD₉₀)],has been observed in whole rabbit heart (37), frog ventricle(26), guinea pig papillary muscle (32), frog ventricular myocytes(50), guinea pig ventricular myocytes (54), and in vivo humanstudies (48). Paradoxically, other studies show shortening ofearly repolarization (decreased APD at 20% repolarization) followedby a prolonged plateau and delay in final repolarization (increasedAPD₉₀), resulting in an overall lengthening of the action potentialin canine heart (14), rabbit heart (55), and frog ventricle(25).

Because these experimental studies were conducted on various animal preparations by different investigators, it is difficultto reconcile the apparently conflicting effects of stretch onthe action potential. It is unclear whether a single mechanismcauses all of these stretch effects or whether different mechanismsact in the various preparations and conditions. Modeling of cellularmembrane currents and membrane potentials is one approach to addressthis question because it allows the methodical variation of anynumber of parameters to permit a thorough and efficient examination.

In this investigation, we explore the relationship between stretch and possible cellular substrates for arrhythmia, such asincreased dispersion of repolarization or the formation of EADs.To explore the potential role of SACs in excitability and arrhythmogenesis,we combined a putative SAC model with the Luo-Rudy membrane modelfor guinea pig ventricle (GPV model) (28, 58). We also formulatedand implemented the SAC model into a new biophysical membranemodel for frog ventricle (FV model) because the only quantitativereport of stretch effects on cellular excitability is with fieldexcitation of frog ventricular cells (50). Moreover, implementationof the FV model permitted us to explore the potential role ofthe sarcoplasmic reticulum (SR), which has little function inthe frog compared with the mammal (10, 31). The two modelsillustrate that stretch increases cellular excitability and dispersionof both repolarization and refractoriness $---$ all potentially arrhythmogenicfactors.

A preliminary version of this study was presented in abstract form (40).

	METHODS

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Guinea Pig Ventricular Membrane Model

We implemented the mammalian membrane model of Luo and Rudy (28, 58) for the guinea pig ventricle (GPV model), a formulationbased on whole cell and single-channel experimental data. To accountfor stretch sensitivity, a putative SAC was added to the membranemodel. Both single-channel (6, 21, 41) and whole cell (21,44) current recordings have associated a linear current-voltagerelation with SACs. These currents have been shown to be carriedby cations (6, 21, 41) and to be generally time independent(21, 44). Reported single-channel reversal potentials are $-$ 15 (44), $-$ 27 (6), $-$ 70 and $-$ 2 (21), and $-$ 35 to $-$ 70 (41)mV. Whole cell reversal potentials have been measured to be $-$ 15(44) and $-$ 16 (21) mV.

Thus the stretch channel current (I_s) was assumed to be linear and time independent with variable conductance (g_s) and reversalpotential (E_s) with representative values of $-$ 50 and $-$ 20 mV

<IT>I</IT>s = <IT>g</IT>s(<IT>V</IT>m − <IT>E</IT>s) (1)

For potentials increasingly negative to E_s, the channel contributes an increasing inward current that acts to depolarizeV_m.

Standard model conditions. Ionic conditions for the GPV model were (in mM) 140 [Na]_o, 5.4 [K]_o, and 1.8 [Ca]_o (extracellular Na, K, and Ca concentration,respectively), and temperature was 37°C. At steady-state restingconditions, V_rest was $-$ 86.5 mV, and intracellular concentrationswere (in mM) 18 [Na]_i, 145 [K]_i, and 1.784 × 10⁴ [Ca]_i. Membrane conductances were normalized to membrane capacitanceand expressed in microsiemens per microfarad. Standard capacitivemembrane area (1.534 × 10⁴ cm²), cell volume (38 × 10⁶ µl), and cellular subvolumes were used (28).

Frog Ventricular Membrane Model

To explore the potential role of SR in stretch responses and to compare excitation threshold (ET) results with experimentaldata, we also formulated and implemented a new membrane modelfor the frog ventricle (FV model) as described in the APPENDIX.To account for stretch sensitivity, the membrane model was modifiedby the addition of a linear, time-independent SAC as in Eq. 1.

Field excitation framework. It is essential to use an appropriate model to determine ET when comparing modeling results to experimental studies that applyfield stimuli (50). Therefore, the membrane models were implementedin an 11-patch field excitation framework to determine cellularexcitation under conditions of simulated field stimulation. Thedetails of this framework are presented in the APPENDIX.

Standard model conditions. Ionic conditions for the FV model were (in mM) 110 [Na]_o, 3.0 [K]_o, 1.0 [Ca]_o, and 2.5 [Mg]_i and temperature of 22°C. At steady-stateresting conditions, V_rest was $-$ 85.5 mV, and intracellular concentrationswere (in mM) 10 [Na]_i, 90 [K]_i, and 1.099 × 10⁴ [Ca]_i. Model conductances were expressed in microsiemens fora cell with a capacitance of 0.1 nF and a volume of 2.5 × 10⁶ µl. Membrane conductances were normalized to membrane capacitanceand expressed in microsiemens per microfarad.

Validation of FV model. Experimental data were obtained using whole cell voltage and current clamp of single frog ventricular myocytes, isolated aspreviously described (30). The bath Ringer solution contained(in mM) 110 NaCl, 3 KCl, 1.0 CaCl₂, 10 glucose, and 10 HEPES,pH 7.25. Pipette solution consisted of (in mM) 40 KCl, 70 K-glutamate,10 HEPES, and 10 EGTA, pH 7.18. Experiments were conducted atroom temperature (19-23°C) using a commercial patch-clamp unit(Dagan 3900 Integrating Patch Clamp, Dagan, Minneapolis, MN).Action potentials were generated by a 10-ms current pulse; voltage-clamppulses were applied from a holding potential of $-$ 85.5 mV. Parametersfor the ionic currents of the FV model were adjusted until a closefit of the model to the data was obtained.

Simulations

Simulations were initiated with a zero-stretch conductance using standard model conditions unless otherwise indicated. Todetermine V_rest under stretch conditions, g_s was set to the testvalue and the membrane potential was allowed to settle to itsnew value over a period of 250 ms. To initiate action potentials,monophasic, rectangular electrical waveforms of 5-ms durationwere applied to the field excitation model for cells initiallyat steady-state V_rest. For each value of g_s tested, V_rest wasallowed to settle for a period of 150 ms before application ofthe electrical stimulus. To stretch trigger action potentials,the simulation was initiated with g_s = 0 and the membrane potentialat rest; after 100 ms, g_s was stepped to the test value for aspecified duration and then returned to zero.

Action potentials were simulated for a wide range of values for g_s. Using the FV model, we varied g_s from 0 to 300 µS/µF foran E_s of $-$ 20 and $-$ 50 mV. With the GPV model, g_s was varied from0 to 100 µS/µF for the same E_s, $-$ 20 and $-$ 50 mV.

ET was defined as the minimum half-cell-length potential (HCLP) for which excitation occurred and differs from the transmembranepotential at which regenerative activity occurred, i.e., the "takeoffpotential." The HCLP is the potential difference generated bythe applied field over a distance equal to one-half of the celllength. An action potential was defined to occur when the membranepotential exceeded 0 mV within 100 ms after the onset of the stimulus.

APD₉₀ was used as a measure of the duration of the action potential and was calculated by determining the time elapsed fromthe action potential upstroke to the point of 90% repolarizationfrom the maximum overshoot. The upstroke was defined as the instantof maximum rate of rise in membrane potential.

The membrane response for a given stimulus waveform was computed using a second-order Runge-Kutta-Fehlberg algorithm withvariable step size no greater than 10 µs (Advanced Computer SimulationLanguage, Mitchell and Gauthier, Concord, MA) running on a computerworkstation (Indy/R4400, Silicon Graphics, Mountain View, CA).

	RESULTS

Top Abstract Introduction Methods Results Discussion Appendix References

Validation of FV Model

Two types of experimental recordings from frog ventricular myocytes using the whole cell variation of the patch-clamp methodwere obtained for fitting the parameters of the FV model. Thefirst was the ventricular action potential, obtained with a stimuluspulse under current-clamp conditions. The second was the 400-msisochronal current-voltage relation obtained under voltage clamp.Here, the membrane potential was initially held at rest ( $-$ 85.5mV), clamped to the test potential for 400 ms, and then returnedto rest. Experimental data were acquired at a sampling rate of2 kHz, and the current values were sampled between 398 and 402ms after the onset of the test potential and averaged. The resultingvalue was then plotted against the test pulse voltage.

The model-simulated action potentials and 400-ms isochronal current-voltage relations were determined under clamp protocolsand extracellular and intracellular ionic conditions identicalto those in the experiments and fit iteratively to the experimentalrecordings by adjusting the delayed rectifier potassium current(I_K), inward rectifier potassium current (I_K1), and sodium-potassiumpump current (I_NaK). All of the remaining currents were constrainedaccording to findings in the literature as described in the APPENDIX.The experimental and model-simulated frog ventricular action potentialsare shown in Fig. 1A and compare favorably in height, duration,V_rest, and overall shape. The model-generated 400-ms isochronalcurrent-voltage relation shown in Fig. 1B also faithfully reproducesthe experimental voltage-clamp findings.

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Fig. 1. Comparison of experimental and frog ventricle model (FV model) action potentials and current-voltage (I-V) relations. Standard experimental and model conditions were used. A: comparison of experimentally obtained (solid line) and model-simulated (dashed line) frog ventricular action potentials. B: isochronal I-V relation measured at 400 ms for FV model compared with experimental data. Ionic membrane current (I₄₀₀) is plotted on ordinate, and transmembrane potential (V_clamp) for actual experimental data ( $bullet$ ) and model results (solid line) is plotted on abscissa. Cell capacitance was estimated to be 0.12 nF. Model simulations used a cell capacitance of 0.12 nF, and currents were scaled by 1.2 times from the standard model (capacitance of 0.1 nF).

Action Potential Changes

Stretch-mediated changes in APD and action potential shape were explored in both the GPV and FV models by implementing a stretchchannel with an E_s of $-$ 20 and $-$ 50 mV. The stretch channel wasactivated, and V_rest was allowed to stabilize for a period of150 ms. An electrical field stimulus of a fixed intensity equalto 1.1 times that of the control (unstretched) ET was then appliedto trigger an action potential.

Figure 2 shows the results of adding a stretch channel with an E_s of $-$ 50 mV in both guinea pig and frog. For guinea pig ventricle,as g_s was increased from 0 to 50 µS/µF, V_rest gradually depolarizedand APD₉₀ consistently decreased from 193 to 144 ms (Fig. 2A).A similar trend is seen for the frog ventricle. As g_s increasedfrom 0 to 10 µS/µF, V_rest depolarized slightly and APD₉₀ decreasedto an even larger degree, from 716 to 185 ms (Fig. 2B).

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Fig. 2. Comparison of putative action potential changes in guinea pig ventricle (GPV) and FV models with stretch, with reversal potential (E_s) = $-$ 50 mV. Standard model conditions were used for all simulations. A: GPV model including stretch channel conductance (g_s) of 0 (a), 20 (b), 40 (c), and 50 (d) µS/µF. B: FV model including g_s of 0 (a), 2.5 (b), 5 (c), and 10 (d) µS/µF.

Figure 3 illustrates the analogous case of adding a stretch channel with E_s = $-$ 20 mV to the GPV and FV models. Here, the effectof the stretch channel on APD was qualitatively different forthe two models. For the guinea pig ventricle (Fig. 3A), V_restagain depolarized as g_s increased from 0 to 50 µS/µF. However,with increased g_s, APD₉₀ gradually lengthened and final repolarizationwas delayed; at the same time, the APD measured at plateau levelsdecreased. These simultaneous events resulted in a characteristic"crossover" of the action potentials during the repolarizationphase that was not seen for the case of E_s = $-$ 50 mV. The actionpotential plateau lengthening led to the appearance of an EAD(g_s = 49.6 µS/µF; Fig. 3A, trace c). At a slightly higher levelof stretch conductance (g_s = 50 µS/µF; Fig. 3A, trace d), theEAD triggered a premature action potential. For the frog ventricle(Fig. 3B), V_rest depolarized and APD became progressively shorteras g_s increased from 0 to 10 µS/µF. This result is similar tothat seen for E_s = $-$ 50 mV.

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Fig. 3. Comparison of putative action potential changes in GPV and FV models with stretch, with E_s = $-$ 20 mV. Standard model conditions were used for all simulations. A: GPV model including g_s of 0 (a), 30 (b), 49.6 (c), and 50 (d) µS/µF. B: FV model including g_s of 0 (a), 2.5 (b), 5 (c), and 10 (d) µS/µF.

The ionic basis underlying the EAD and slow action potential upstroke is shown in Fig. 4. During the prolonged plateau (termedthe EAD conditional phase; Refs. 22 and 59) preceding theEAD of Fig. 4A, inactivation gates of the L-type calcium current(I_Ca) recover while the activation gate closes, permitting reactivation(Fig. 4B). The SR calcium release current (I_rel) was not triggeredduring EAD formation. Therefore, the stretch-induced prematureaction potential seen in the guinea pig is the result of the recoveryand subsequent reactivation of I_Ca.

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Fig. 4. Kinetic analysis of an early afterdepolarization (EAD) and resulting slow action potential upstroke in GPV model with stretch, with E_s = $-$ 20 mV. Standard model conditions were used. A: membrane potential for GPV model including g_s of 50 µS/µF (same as trace d of Fig. 3A). B: gating variables for L-type calcium current in A. d, Activation gate; f, inactivation gate; f_Ca, calcium-dependent inactivation gate.

Cellular Excitability

To explore the change in excitability of the cell models under stretch, we recorded resting potential (V_rest) and ET withincreasing g_s. In our simulations using the GPV model, g_s wasvaried over a range of 0 to 40 µS/µF using an E_s of $-$ 20 or $-$ 50mV (Fig. 5). As expected from the results shown in Figs. 2 and3, V_rest depolarized from $-$ 86.5 to $-$ 78.0 mV over this range forE_s = $-$ 20 mV and from $-$ 86.5 to $-$ 82.7 mV for E_s = $-$ 50 mV. Concurrentwith this depolarization of V_rest, the cell became more excitable;ET decreased by 23.4% for E_s = $-$ 20 mV and by 10.4% for E_s = $-$ 50mV. Analogous simulations were performed using the FV model. Resultssimilar to those of Fig. 5 were obtained with only minor differencesin the curvature of the plots.

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Fig. 5. GPV model predictions for resting potential and excitation threshold (ET) with E_s = $-$ 20 and $-$ 50 mV. Top: change in resting potential as a function of g_s, expressed in microsiemens per microfarad. Bottom: change in normalized ET as a function of g_s.

A comparison of the effects of g_s on the FV and GPV models is displayed in Table 1. For E_s = $-$ 20 and $-$ 50 mV, the change inV_rest ( $Delta$ V_rest) and the change in ET ( $Delta$ ET) are given for each modelfor an increase in g_s from 0 to 40 µS/µF. As a measure of comparison,the g_s needed to cause a 12% decrease in ET [g_s( $-$ 12% ET)] wasalso determined for both models for E_s = $-$ 20 and $-$ 50 mV.

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Table 1. Comparison of effects of increased stretch conductance on membrane models

By applying stretch conductances with magnitudes larger than those already discussed, we found that both transient and sustainedstretches could directly trigger action potentials in the absenceof any electrical stimulus (Fig. 6). Figure 6A shows a guineapig ventricular action potential triggered by a transient, 30-msactivation of a g_s of 70 µS/µF with E_s = $-$ 20 mV. Figure 6B showsa frog ventricular action potential triggered by a 30-ms, 80 µS/µFstretch, also with E_s = $-$ 20 mV. Similar results were obtainedfor both guinea pig and frog with E_s = $-$ 50 mV. A sustained stretchof a slightly lower conductance results in a pacemaker-like activityfor guinea pig ventricle. Figure 6C shows the response of theguinea pig ventricular membrane potential to the sustained activationof a g_s of 60 µS/µF with E_s = $-$ 20 mV.

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Fig. 6. Stretch-triggered action potentials with E_s = $-$ 20 mV. A: GPV model including a 30-ms activation of a g_s of 70 µS/µF. B: FV model including a 30-ms activation of a g_s of 80 µS/µF. C: GPV model including a sustained activation of a g_s of 60 µS/µF. Bars indicate duration of g_s activation.

Dispersion of APD

The difference between the changes in APD with stretch obtained with the GPV and FV membrane models at E_s = $-$ 20 mV (Fig. 3)prompted further investigation. For example, ionic conditionsfor the FV model were varied to determine whether lengtheningof APD₉₀ with stretch (behavior never observed under normal ionicconditions for the FV model but seen for the GPV model in Fig.3A) could be observed. Indeed, if the magnitude of I_Ca were increased,either by simply scaling the current or by increasing [Ca]_o from1 to 4 mM, stretch with E_s = $-$ 20 mV now caused a lengthening ofthe action potential (Fig. 7A). A similar crossover and increaseof APD could also be obtained by a combination of a smaller increasein [Ca]_o (2 mM) and a decrease in I_K1 by a factor of 2 (Fig. 6B).However, with either the increase of [Ca]_o to 2 mM or the decreaseof I_K1 alone, APD shortening (and not lengthening) was observed.Despite significant lengthening of the action potential plateau,no EAD was observed for the FV model under any conditions.

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Fig. 7. Comparison of putative action potential changes in FV model with stretch for nonstandard model conditions and E_s = $-$ 20 mV. A: extracellular Ca concentration ([Ca]_o) = 4 mM and g_s of 0 (a), 10 (b), 15 (c), and 20 (d) µS/µF. B: [Ca]_o = 2 mM, inward rectifier potassium current (I_K1) decreased by a factor of 2, and g_s of 0 (a), 2.5 (b), 5 (c), and 10 (d) µS/µF.

Regional differences in action potential duration in cardiac tissue create a situation of "dispersion of repolarization."Dispersion of repolarization may be caused by any number of mechanisms,including a gradient in tissue stretch or variance in local extracellularionic conditions, as suggested by our results. To quantify thepotential dispersion of repolarization that might be found instretched tissue, APD was plotted over a range of g_s for the FVmodel (E_s = $-$ 20 mV, Fig. 8). APD₉₀ is seen to decrease to lessthan one-half of its original value with a g_s of 10 µS/µF undernormal ionic conditions. However, increasing [Ca]_o to 4 mM ora combination of increasing [Ca]_o to 2 mM and decreasing I_K1 leadsto an increase in APD₉₀ as g_s increases. Figure 8 illustrateshow these APD₉₀ changes interact and how given either a gradientin g_s (variation along the abscissa on a single curve) or a regionalvariation in ionic conditions (variation among curves at a singlepoint on the abscissa), significant dispersion of repolarizationcan exist in tissue.

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Fig. 8. Action potential duration (APD) variability. APD at 90% repolarization (APD₉₀) is plotted for 3 different cellular conditions for a variety of stretch conductances. $bullet$ , Standard conditions; $black-triangle$ , [Ca]_o = 4 mM;

, [Ca]_o= 2 mM, I_K1 decreased by a factor of 2.

	DISCUSSION

Top Abstract Introduction Methods Results Discussion Appendix References

In this study we implemented two biophysical membrane models, the Luo-Rudy GPV model and a newly formulated FV model, to explorethe arrhythmogenic effects of adding a linear, time-independent,stretch-sensitive current. This current consistently caused adepolarization of V_rest and a reduction in ET, thus increasingexcitability to the point where a mechanical stimulus alone couldelicit an extrasystole. APD changes, as measured by APD₉₀, weremore variable. The guinea pig action potential shortened withstretch for E_s = $-$ 50 mV. However, the action potential lengthenedwith stretch for E_s = $-$ 20 mV, leading to a crossover of the actionpotentials and formation of EADs. In contrast, the frog actionpotential consistently shortened with increased stretch for bothE_s = $-$ 20 mV and E_s = $-$ 50 mV, and neither action potential crossovernor lengthening was seen. Under altered ionic conditions, thefrog action potential could lengthen with increased stretch, althoughEADs were never seen. The highly variable APD response observedin this study suggests that stretch is a possible substrate forarrhythmia in terms of an increased dispersion of repolarizationthroughout a region of stretched tissue. In addition, the formationof EADs indicates a mechanism for stretch-induced extrasystolesor initiation of reentry.

Effect of Stretch Conductance on ET and V_rest

Depolarization of V_rest occurs with an increase in the conductance of the stretch channel, a finding that was independentof the membrane model or stretch channel E_s. At times, the depolarizationof the membrane potential by the stretch current was sufficientto trigger an action potential independent of any electrical stimulus(Fig. 6), a behavior that corresponds to that seen experimentallyin isolated rabbit heart and frog ventricle (15, 25). Theubiquitous V_rest depolarization is paralleled by a decrease inET. Over a range of g_s, a close relationship exists between theextent of depolarization and the percent decrease of ET. The ratioof percent change in ET per millivolt change in V_rest was nearlyconstant and varied only from 2.49 to 2.75 for the range of conductancechanges reported (Fig. 5, Table 1).

Such decreases in ET and depolarizations in V_rest that occur with applied stretch are consistent with previous findings incell-based experiments. A recent study of whole cell currentsin guinea pig ventricular myocytes has shown the activation ofinward stretch-sensitive currents for stretch of 10-20% from restinglength (44)_. Another cell-based study, in which direct mechanicalstretch was applied to guinea pig ventricular myocytes, reporteda slight depolarization (<4 mV) of V_rest with stretch (54).

We, too, have observed small depolarizations of V_rest and found ~12% change in ET for a 10% stretch in single frog ventricularmyocytes during direct mechanical stretch (Ref. 50; Table 1).These findings, combined with those from the FV model, can beused to estimate the fraction of SACs that are activated by a10% stretch of a ventricular cell. The values for g_s expectedto effect a 12% change in ET are shown in Table 1 and range from11.5 to 46.1 µS/µF. These values for g_s are only a rough estimate,considering the many assumptions that have been made. Nevertheless,the conductance values are quite low when compared with single-channeldata. Assuming a single-channel conductance on the order of 100pS (6, 41), channel density of 0.3/µm² (6, 41), and specific membrane capacitance of 1 µF/cm², a g_s of 46.1 µS/µF corresponds to an open probability for thechannels on the order of (46.1 µS/µF)/(100 pS × 0.3/µm²) $approx$ 0.015. Therefore, the stretch conductance activated by a 10%stretch is ~1.5% of that expected for fully open channels, indicatingthat only a small fraction of stretch channels need be openedto increase cellular excitability significantly.

Effect of Stretch Conductance on APD

An intriguing result of our simulations is the variety of changes in the morphology of the action potential that can occurwith increased stretch. For E_s = $-$ 50 mV, the action potentialconsistently shortens with increasing stretch for both membranemodels (Fig. 2). However, for E_s = $-$ 20 mV, the FV model showsAPD shortening whereas the GPV model shows APD lengthening asg_s increases (Fig. 3). This action potential lengthening in theGPV model is accompanied by a crossover during repolarizationand can ultimately lead to formation of an EAD (Fig. 3A, traced). Thus our modeling results indicate that differences in E_s(as reported for different subtypes of SACs; Refs. 21 and 41)can modulate stretch-induced changes in APD.

To determine whether other factors can modulate the APD response to stretch, additional simulations were performed in whichthe relative levels of the ionic currents or ionic concentrationswere varied. The possibility that calcium may be a modulator ofstretch has been described by Gannier and co-workers (16). Theirresults show that a stretch-induced increase in intracellularcalcium depends on extracellular calcium rather than on intracellularstores and seems to be caused by calcium influx through L-typecalcium channels (16), which have been found to be mechanicallysensitive (29). We found that in the FV model, the magnitudeof I_Ca plays a crucial role in the behavior of the action potentialwith stretch. Our simulation of Fig. 3C was executed with a [Ca]_oof 1 mM, and action potential shortening was observed. However,if [Ca]_o were raised to 4 mM, or if the magnitude of I_Ca wereincreased (analogous to upregulation of the channel), action potentiallengthening could be induced (Fig. 7A). Augmentation of this currentcontributes to the creation of a small, negative region of thecurrent-voltage relation during the plateau phase that is notpresent in the FV model under normal calcium conditions (Fig.1B). Therefore, a quasi-stable potential is created at approximately $-$ 10 mV, leading to the observed lengthening in the action potential.

Taken together, these action potential simulations show that the stretch response of APD may be highly sensitive to a fewionic currents or ionic conditions, leading either to shorteningor lengthening of APD from its normal value. Also, activationof a stretch channel does not imply that the point of crossoverof action potentials with increasing stretch is necessarily equalto E_s, contrary to the assertions of some previous studies (43).The crossover point may be either positive (Fig. 7) or negative(Fig. 3A) (55) to E_s. Also, a crossover need not always occur(Fig. 3B).

Clinical Implications for Arrhythmogenesis

Both the depolarization in V_rest and the decrease in ET seen in this study may be sufficient to produce an action potentialwithout external electrical stimulation, as was seen in modelsimulations at high stretch conductances (Fig. 6). Stretch-induceddepolarizations have been observed to induce extrasystoles experimentally(3, 19, 25). Pulsatile volume increases in rabbit wholeheart preparations induce corresponding V_rest depolarizationssuch that increasing the magnitude of these volume pulses leadsto progressively increased depolarizations and eventually to triggeredextrasystoles (15). Transient stretch of frog ventricular tissuewill also consistently trigger tissue activation that can be detectedboth mechanically and electrically (11).

The altered durations of the plateau and repolarization phases of the action potential also have proarrhythmic tendencies.An extended plateau can create a conditional phase (22) whenthe cell is vulnerable to EADs. Once formed, an EAD may triggera premature upstroke, resulting in an extrasystole. EADs wereseen in simulations of the GPV model (Fig. 3A, trace c) and werecapable of triggering a regenerative upstroke (Fig. 3A, traced).

In contrast, shortening of the action potential does not have any inherently arrhythmogenic effects at the cellular level.However, at the tissue or whole heart level, APD shortening willlead to a reduction in wavelength, known to predispose cardiactissue to arrhythmia. In addition, regional APD shortening willincrease the dispersion of refractoriness and repolarization,also commonly believed to be substrates for arrhythmia formation(18, 24). Such a dispersion of refractoriness would be augmentedfurther if regional lengthening were also to occur in other partsof the heart. Spatially heterogeneous refractoriness and repolarizationhave been reported in the isolated pig heart when subjected toincreased loading by aortic clamping (8), and a significantincrease of regional dispersion of repolarization was shown toresult from sustained stretch in isolated rabbit hearts (56).This modeling study reinforces these experimental findings andsuggests that local variations in stretch levels and ionic conditionsmay act synergistically, leading to simultaneous action potentialshortening and lengthening in different cardiac regions, therebyincreasing the dispersion of APD throughout the heart.

The concept that ionic conditions play a role in the modulation of APD under stretch conditions implies that pathologicalconditions may augment or alter the baseline electrophysiologicaleffects of stretch. During ischemia and reperfusion, membranecurrents are modified as a result of altered ionic compositionof intracellular and extracellular fluids and the buildup of metabolicbyproducts (4). Ischemia leads to an accumulation of extracellularpotassium, caused at least partially by an ATP-sensitive potassiumchannel activated by a decrease in cellular ATP levels (2).There is also considerable evidence for abnormal calcium cyclingin heart failure, resulting in altered calcium transients (5).Both ischemia and heart failure, although generally viewed asmechanical disorders, are associated with an increased risk ofsudden death by arrhythmia (36, 57). The pathological ionicconditions associated with these diseases may compound the stretch-inducedeffects on APD, thereby contributing to an increased dispersionof refractoriness throughout the heart.

In addition to heterogeneity of the magnitude of stretch or of ionic conditions, a heterogeneity of stretch channel typesthroughout the heart may also increase the dispersion of repolarization.Cells may contain multiple stretch channel subtypes, each havinga characteristic E_s and distribution pattern (21, 41). Inchick heart cells, for example, two populations of SAC have beenidentified, having E_s of $-$ 70 and $-$ 2 mV (21). The effective E_sof the total stretch-induced current will lie between these twoE_s and will be determined by the relative conductances contributedby each channel type. If the channels are nonuniformly distributedthroughout the heart, so that different channel types dominateregionally, the effective E_s of the stretch-induced current willalso vary from region to region. We have shown that in guineapig cells, stretch can cause either action potential shorteningor lengthening depending on the exact value of E_s (Figs. 2A and3A).

Early Afterdepolarizations

EADs were seen in simulations using the GPV model but not in those using the FV model (Figs. 3, 6). Because SR has a muchgreater functional role in the mammal compared with the frog (10,31), we expected that the more complex calcium dynamics of theguinea pig might explain why the GPV model shows a tendency towardsEAD formation. However, we found that I_rel was zero during theEAD, indicating that some other current must be involved in EADformation.

In a modeling study by Zeng and Rudy in a guinea pig ventricular cell model (59), the critical factors for drug-inducedEAD formation were determined to be a prolonged action potentialplateau and reactivation of L-type calcium channels. These twofactors are related, because the extended plateau phase providestime for I_Ca to recover from inactivation, a necessary precursorto its reactivation. In our experiments using the GPV model, theaction potential plateau was lengthened by addition of a stretchcurrent with E_s = $-$ 20 mV (Fig. 3A). A conditioning phase developedat approximately $-$ 30 mV, the same as observed by Zeng and Rudy(59). This potential is sufficiently negative to permit significant(~40%) recovery of inactivation and the subsequent reactivationof I_Ca (Fig. 4). In the FV model, a prolonged plateau appearedduring stretch only under varied extracellular ionic conditions(Fig. 7). However, this plateau level was 0 to $-$ 10 mV, much morepositive than that seen for GPV action potentials. At this membranepotential, little recovery from inactivation is possible, andreactivation of the L-type calcium channels does not occur. Becausethe characteristics of the activation and inactivation gates arenearly identical in the GPV and FV models, the level of the plateaupotential may therefore be critical to whether reactivation ofI_Ca and formation of EADs result from stretch.

There has been some debate as to whether experimental findings of stretch-induced EADs in frog (25) and mammalian (33)tissue are real or artifactual. Our results suggest that EAD formation,at least in guinea pig, is indeed a real effect of stretch.

Comparison to Previous SAC Modeling Studies

Our model for I_s is similar to the SAC implemented in previous modeling by Sachs (42) and Zabel et al. (55) for guineapig ventricle using the Oxsoft HEART program. In those simulations,the stretch conductance was explicitly assumed to be a functionof sarcomere length, in the form g_s = $gamma$ $rho$ $beta$ (L), where $gamma$ is single-channelconductance, $rho$ is channel density, $beta$ (L) is a nonlinear length-dependentfactor that defines channel open probability, and L is sarcomerelength. According to their model, $beta$ (L) asymptotically approacheszero at short lengths and is 1% activated at a sarcomere lengthof 1.9 µm, the slack length for guinea pig ventricular myocytes(17). We have made no assumptions regarding the relationshipbetween channel open probability and sarcomere length in our formulation,because this relationship is not currently known.

The previous modeling studies using this SAC formulation illustrated that some stretch-induced action potential and V_restchanges reported by experimental studies could be successfullymodeled by implementing a linear, time-independent SAC with anegative E_s (42, 55). The current study shows that stretchof cardiac tissue produces more than just a change in the durationof the action potential. The APD change has a significant impacton arrhythmogenicity and excitability of cardiac tissue. Changesin APD, especially when regionally distributed, can become arrhythmogenicthrough mechanisms such as EADs, wavelength shortening, and increaseddispersion of repolarization. Stretch also depolarizes V_rest andincreases the excitability of individual cardiac cells.

Limitations of Study

The SAC has been assumed to be linear and time-independent, on the basis of findings from numerous experimental studies. Othermodeling studies have made the same assumptions with respect toSAC properties (42, 55). However, although experimental studieshave confirmed the existence of linear, time-independent SACsin guinea pig (44), direct experimental data have not yet beenobtained to show their existence in the frog ventricle. In addition,there may be a slow time-dependent inactivation of SACs, on theorder of seconds (21) or minutes (44, 50), that has notbeen accounted for in this study.

Other ionic effects of stretch have been described for cardiac muscle. First, several of the fundamental time-dependent channelstypically found in cardiac cells, including the L-type calcium,delayed rectifier potassium, and ATP-sensitive potassium channels(29, 51, 53), have been shown to be modified by stretch.Second, currents have been identified in frog and guinea pig ventriclethat are mechanosensitive but not necessarily stretch sensitive,including the swelling-sensitive chloride current (39, 52).This current is not activated under isotonic conditions, and thereforeis not expected to alter the results of the current study. Third,it is known that the binding of calcium to troponin C is stretchsensitive (7). The effects of stretch on these other mechanismshave not been considered in the current study.

In conclusion, these results confirm experimental observations that stretch of cardiac tissue can be arrhythmogenic. Stretchleads to V_rest depolarization and increased cellular excitability.The diversity of APD changes induced by stretch may lead to anincreased dispersion of repolarization, a potentially arrhythmogenicsituation in cardiac tissue. EADs and premature action potentialscan be elicited by a stretch current and may initiate extrasystolesin the whole heart.

	APPENDIX. FV Model

Top Abstract Introduction Methods Results Discussion Appendix References

The FV model simulates the electrophysiological properties of frog ventricular cardiac membrane. The simulation equationsfor this model are based largely on the model formulated by Rasmussonet al. (35) for the frog atrium (FA model). The FV model assumesa "standard" cell with a capacitance of 10⁴ µF, the convention used in the FA model. Conductances are expressedin microsiemens, membrane potential in millivolts, and membranecurrents in nanoamperes. The diffusion-limited cleft space inthe FA model was eliminated. Changes from the FA membrane equationswere implemented as necessary to match simulations to whole cellvoltage-clamp and action potential data obtained from single frogventricular myocytes. A putative stretch-activated current wasalso included in the model.

Model Equations

Sodium current. The kinetic equations used to describe the fast sodium current (I_Na) are based on the data of Seyama and Yamaoka (45) forbullfrog ventricular cells. The rate constants were scaled by5.2 to account for an apparent Q₁₀ of 2.5 in these cells (1)and the 18°C temperature difference between experimental (4°C)and model (22°C) conditions. This value of Q₁₀ was calculatedby comparing the activation time constant data at 4°C (45) withthe activation time constant reported for 25°C (1). However,this value of Q₁₀ did not account for the difference in the inactivationtime constant between these two sets of data (1, 45). Toadjust for this discrepancy, the inactivation time constant wasincreased by a factor of 1.7. The maximum conductance was setto a value of 0.66 µS.

Calcium current. I_Ca was the FA calcium current for frog atrial cells scaled by a factor of 2.125 as reported in a current density comparisonbetween frog atrial and ventricular cells (20).

Delayed rectifier potassium current. I_K was the FA current scaled by a factor of 0.25 to match the 400-ms isochronal current-voltage relation at positive transmembranepotentials obtained experimentally in frog ventricular cells,as shown in Fig. 1B.

Inward rectifier potassium current. The mathematical formulation for I_K1 in the FA model had too few free parameters to match our experimental data for frog ventricularcells. Instead, a modified version of the Luo-Rudy I_K1 current(28) was used, with parameters altered to match the 400-ms isochronalcurrent-voltage relation for transmembrane potentials negativeto $-$ 20 mV (Fig. 1B). The current was defined by the followingequations

<IT>I</IT>K1 = <IT>g</IT>K1 (<IT>V</IT>m − <IT>E</IT>K) (A1)

<IT>g</IT>K1 = 0.101486<FR><NU><IT>a</IT>K1<IT>c</IT>K1<RAD><RCD>[K]o</RCD></RAD></NU><DE><IT>a</IT>K1 + <IT>b</IT>K1</DE></FR> (A2)

<IT>a</IT>K1 = <FR><NU>2.04</NU><DE>1 + exp [0.07155(<IT>V</IT>m − <IT>E</IT>K − 54.215)]</DE></FR> (A3)

<IT>c</IT>K1 = 1 − <FR><NU>0.9</NU><DE>1 + exp [0.11925 (<IT>V</IT>m − <IT>E</IT>K − 99.215)]</DE></FR> (A4)

<IT>b</IT>K1 = <FR><NU><FENCE><AR><R><C>0.49124 exp [0.05783(<IT>V</IT>m − <IT>E</IT>K − 13.524)]</C></R><R><C> + exp [0.06175(<IT>V</IT>m − <IT>E</IT>K − 584.31)] </C></R></AR></FENCE></NU><DE>1 + exp [−0.5143(<IT>V</IT>m − <IT>E</IT>K + 14.753)]</DE></FR> (A5)

where E_K is the potassium reversal potential.

Background currents. The calcium background current and the sodium background current were identical to those in the FA model.

Stretch-activated current. The putative I_s used in the FV model was assumed to have a time-independent, linear current-voltage relation, with E_s in therange of $-$ 50 to $-$ 20 mV and a g_s that increased with stretch (Eq.1).

Pump and exchanger currents. The sodium-calcium exchanger current (I_NaCa) and the sarcolemmal calcium pump current were identical to those in the FA model.The sodium-potassium pump current (I_NaK) was scaled by a factorof 0.5 from that of the FA model.

Corrections to the FA Model. On the basis of discussions with R. Rasmusson, corrections were made to three published equations of the FA model (35).These equations, including corrections, are also part of the FVmodel.

Delayed rectifier current

<IT>r</IT>′ = <FR><NU>95</NU><DE>1 + exp <FENCE><FR><NU><IT>V</IT><SUB>m</SUB> − <IT>E</IT><SUB>K</SUB> − 98</NU><DE>25</DE></FR></FENCE></DE></FR> − 95

(A6)

where r' is a variable in the formulation of the maximum conductance of the delayed rectifier current (I_K).

Sodium-potassium pump

<IT>I</IT><SUB>NaK</SUB> = 0.0725 ⋅ <FENCE><FR><NU>[Na]<SUB>i</SUB></NU><DE>[Na]<SUB>i</SUB> + 5.46</DE></FR></FENCE><SUP>3</SUP> <FENCE><FR><NU>[K]<SUB>o</SUB></NU><DE>[K]<SUB>o</SUB> + 0.621</DE></FR></FENCE><SUP>2</SUP> <FENCE><FR><NU><IT>V</IT><SUB>m</SUB> + 150</NU><DE><IT>V</IT><SUB>m</SUB> + 200</DE></FR></FENCE>

(A7)

Sodium-calcium exchanger (incorrect parentheses)

<IT>I</IT><SUB>NaCa</SUB> = 1.5 × 10<SUP>−6</SUP> ⋅ <FR><NU><FENCE><AR><R><C>[Na]<SUP>3</SUP><SUB>i</SUB>[Ca]<SUB>o</SUB> exp (0.0195<IT>V</IT><SUB>m</SUB>)</C></R><R><C> − [Na]<SUP>3</SUP><SUB>o</SUB>[Ca]<SUB>i</SUB> exp (−0.0195<IT>V</IT><SUB>m</SUB>)</C></R></AR></FENCE></NU><DE>1 + 0.0001([Na]<SUP>3</SUP><SUB>o</SUB>[Ca]<SUB>i</SUB> + [Na]<SUP>3</SUP><SUB>i</SUB>[Ca]<SUB>o</SUB>)</DE></FR>

(A8)

Field Excitation

To determine cellular excitation threshold under experimental conditions of field stimulation, the model was modified furtherin a manner similar to that developed previously (49). Unlikethe previous field model in which cells were stimulated by longitudinallyoriented fields, here we consider the case of transverse stimulationbecause this configuration allows a clear separation of membranechannel versus geometric effects, as will become apparent. Assuminga prolate spheroid shape for the cell, the extracellular surfacepotential (V_e) resulting from the applied field (E_oy)can be determined analytically and is a linear function of distance(y) (23)

<IT>V</IT><SUB>e</SUB>(<IT>y</IT>) = <IT>A</IT>(&egr;)<IT>E</IT><SUB>o<IT>y</IT></SUB><IT>y</IT> (−<IT>b</IT> ≤ <IT>y</IT> ≤ <IT>b</IT>)

(A9)

with the form factor (A) being a function of eccentricity ( $epsilon$ ), defined as <RAD><RCD>(1 −(<IT>b</IT>2/<IT>a</IT>2)</RCD></RAD>

,where a and b are the semimajor and semiminor axes, respectively.For simplicity in our model, we have assumed the limiting caseof a cylindrical geometry with radius (b) for the cell, in whichcase a $right-arrow$ $infinity$ , $epsilon$ $right-arrow$ 1, A $right-arrow$ 2, and V_e assumes the well-known cosinedependence if y is expressed in terms of polar angle (i.e., y= b cos $theta$ ).

The membrane was divided circumferentially into 11 segments over which V_e (varying from $-$ 2E_oyb to +2E_oyb)was partitioned into 11 equal ranges. The potential drop overone-half of the cell (E_oyb), termed the half-cell-lengthpotential (HCLP), was used to define ET. The biophysical propertiesof each membrane patch were represented by the model equationsdescribed by the FV model or the GPV model, and the relative sizesof the membrane patches were calculated as previously described(49). To reduce the simulation times, intracellular and extracellularresistances were omitted, which resulted in a slight but systematicoverestimation of ET.

In the interpretation of our simulation results, it is necessary to take into account changes in the cell geometry with stretch.If a constant cell volume is assumed, an increment of $Delta$ L/L incell length will decrease cell diameter by <RAD><RCD>&Dgr;<IT>L</IT>/<IT>L</IT></RCD></RAD> ,thereby decreasing the sensitivity of the cell to the extracellularfield and raising the stimulus threshold. A 10% longitudinal stretchwill result in a 4.65% decrease in cell diameter, resulting inan effective increase in ET by a factor of 100/(100 $-$ 4.65) =1.05 from geometric effects alone. In previous experiments fromour laboratory, the ET for cross-shock field stimuli in singlefrog ventricular myocytes was found to decrease on the order of $-$ 0.8% per 1% stretch (n = 10; Ref. 50). Accounting for the expectedgeometric changes, the ET for a 10% increase in cell length canbe calculated to be (100 $-$ 8)/1.05 = 87.7% of the prestretch value,i.e., a decrease of ~12%. This 12% decrease in ET resulting froma 10% cell stretch is used as a characteristic measure of thestretch effect.

	ACKNOWLEDGEMENTS

This work was supported by National Institutes of Health Grant R01 HL-50610. T. Riemer was a recipient of a Whitaker FoundationGraduate Fellowship in Biomedical Engineering.

	FOOTNOTES

Address for reprint requests: L. Tung, Dept. of Biomedical Engineering, Johns Hopkins Univ., 720 Rutland Ave., Baltimore, MD 21205.

Received 20 November 1997; accepted in final form 20 April 1998.

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Mechanisms of conduction slowing during myocardial stretch by ventricular volume loading in the rabbit
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[Abstract] [Full Text] [PDF]

S. N. Healy and A. D. McCulloch
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[Abstract] [Full Text] [PDF]

K. K. Parker, J. A. Lavelle, L. K. Taylor, Z. Wang, and D. E. Hansen
Stretch-induced ventricular arrhythmias during acute ischemia and reperfusion
J Appl Physiol, July 1, 2004; 97(1): 377 - 383.
[Abstract] [Full Text] [PDF]

C.-E. Chiang, H.-N. Luk, and T.-M. Wang
Swelling-activated chloride current is activated in guinea pig cardiomyocytes from endotoxic shock
Cardiovasc Res, April 1, 2004; 62(1): 96 - 104.
[Abstract] [Full Text] [PDF]

A Kamkin, I Kiseleva, and G Isenberg
Stretch-activated currents in ventricular myocytes: amplitude and arrhythmogenic effects increase with hypertrophy
Cardiovasc Res, December 1, 2000; 48(3): 409 - 420.
[Abstract] [Full Text] [PDF]

T. L. Riemer and L. Tung
Focal extracellular potential: a means to monitor electrical activity in single cardiac myocytes
Am J Physiol Heart Circ Physiol, April 1, 2000; 278(4): H1383 - H1394.
[Abstract] [Full Text] [PDF]

J. R. Hume, D. Duan, M. L. Collier, J. Yamazaki, and B. Horowitz
Anion Transport in Heart
Physiol Rev, January 1, 2000; 80(1): 31 - 81.
[Abstract] [Full Text] [PDF]

R. W. Fasciano II and L. Tung
Factors governing mechanical stimulation in frog hearts
Am J Physiol Heart Circ Physiol, December 1, 1999; 277(6): H2311 - H2320.
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				R. W. Mills, S. M. Narayan, and A. D. McCulloch Mechanisms of conduction slowing during myocardial stretch by ventricular volume loading in the rabbit Am J Physiol Heart Circ Physiol, September 1, 2008; 295(3): H1270 - H1278. [Abstract] [Full Text] [PDF]

				S. N. Healy and A. D. McCulloch An ionic model of stretch-activated and stretch-modulated currents in rabbit ventricular myocytes Europace, January 1, 2005; 7(s2): S128 - S134. [Abstract] [Full Text] [PDF]

				K. K. Parker, J. A. Lavelle, L. K. Taylor, Z. Wang, and D. E. Hansen Stretch-induced ventricular arrhythmias during acute ischemia and reperfusion J Appl Physiol, July 1, 2004; 97(1): 377 - 383. [Abstract] [Full Text] [PDF]

				C.-E. Chiang, H.-N. Luk, and T.-M. Wang Swelling-activated chloride current is activated in guinea pig cardiomyocytes from endotoxic shock Cardiovasc Res, April 1, 2004; 62(1): 96 - 104. [Abstract] [Full Text] [PDF]

				A Kamkin, I Kiseleva, and G Isenberg Stretch-activated currents in ventricular myocytes: amplitude and arrhythmogenic effects increase with hypertrophy Cardiovasc Res, December 1, 2000; 48(3): 409 - 420. [Abstract] [Full Text] [PDF]

				T. L. Riemer and L. Tung Focal extracellular potential: a means to monitor electrical activity in single cardiac myocytes Am J Physiol Heart Circ Physiol, April 1, 2000; 278(4): H1383 - H1394. [Abstract] [Full Text] [PDF]

				J. R. Hume, D. Duan, M. L. Collier, J. Yamazaki, and B. Horowitz Anion Transport in Heart Physiol Rev, January 1, 2000; 80(1): 31 - 81. [Abstract] [Full Text] [PDF]

				R. W. Fasciano II and L. Tung Factors governing mechanical stimulation in frog hearts Am J Physiol Heart Circ Physiol, December 1, 1999; 277(6): H2311 - H2320. [Abstract] [Full Text] [PDF]