Ca2+ waves during triggered propagated contractions in intact trabeculae

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Ca²⁺ waves during triggered propagated contractions in intact trabeculae

Masahito Miura¹, Penelope A. Boyden², and Henk E. D. J. Ter Keurs¹

¹ Department of Medicine, University of Calgary, Calgary, Alberta, Canada T2N 4N1; and ² Department of Pharmacology, Columbia College of Physicians and Surgeons, New York, New York 10032

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

Triggered propagated contractions (TPCs) starting from damaged regions travel along multicellular cardiac muscle preparations.We have reported that octanol (100 µM) inhibits TPCs. The inhibitoryeffect of octanol on propagation of TPCs could be due to an effectof octanol on Ca²⁺-induced Ca²⁺ release (CICR) mediated by Ca²⁺ diffusion inside the single cell or on the diffusion of Ca²⁺ from cell to cell via gap junctions (GJs). Therefore, we studiedthe regional changes in intracellular Ca²⁺ concentration ([Ca²⁺]_i) during TPCs and the effect of octanol on the permeabilityof gap junctions (P_GJ) in rat cardiac trabeculae. [Ca²⁺]_i was measured using electrophoretically injected fura 2 andan image-intensified charge-coupled device camera. P_GJ was calculatedfrom the diffusion coefficient for fura 2 in trabeculae (D_trab)and in the myoplasm (D_myop). After 1- and 3-h superfusion with100 µM 1-octanol, D_myop showed no significant changes, whereasD_trab was reduced significantly. Therefore, calculated P_GJ wasreduced from 4.15 × 10⁵ to 2.10 × 10⁵ and 0.86 × 10⁵ cm/s, respectively. The propagation velocity of the regionalincreases in [Ca²⁺]_i during TPCs was constant, averaging 1.69 ± 1.48 mm/s (range0.34-5.47 mm/s, n = 10). These observations support the hypothesisthat TPCs are initiated near the damaged ends of trabeculae andare propagated by CICR from the sarcoplasmic reticulum mediatedby diffusion of Ca²⁺ through cells and from cell to cell through GJs.

rat cardiac trabeculae; octanol

	INTRODUCTION

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AFTERCONTRACTIONS ARISE in damaged regions of cardiac muscle and propagate into the neighboring myocardium. Propagating contractions,which can be measured as waves of sarcomere shortening, have beendenoted as triggered propagated contractions (TPCs) and have beenobserved in both rat ventricular (10, 19) and human atrialtrabeculae (9).

Similar to the mechanism proposed for Ca²⁺ waves in a single isolated myocyte (17), the propagation mechanism of a TPC isthought to be consistent with a model of Ca²⁺-induced Ca²⁺ release (CICR) from sarcoplasmic reticulum (SR) mediated by Ca²⁺ diffusion to adjacent SR for the following reasons. First, TPCsdo not require an intact sarcolemma (8). In addition, Gd³⁺, a stretch-activated channel blocker, affects neither initiationnor propagation velocity of a TPC in intact trabeculae, suggestingthat stretch activation of ion fluxes are not involved in TPCpropagation (32). Second, TPCs are abolished by agents thatinterfere with SR Ca²⁺ loading or release, such as ryanodine and caffeine (11), similarto findings with Ca²⁺ waves in single myocytes (17). Third, TPCs propagate alongthe undamaged parts of the trabeculae at constant velocities thatvary from 0.1 to 15 mm/s depending on SR Ca²⁺ loading (10, 19). These propagation velocities are too fastfor simple diffusion of Ca²⁺ alone (see Ref. 2, discussion) and slower than conductionvelocities of electrical signals reported for normal ventricularmuscle (1 m/s). Finally, computer simulation studies using a modelof CICR and Ca²⁺ diffusion predict propagation velocities of TPCs that are inagreement with the observed experimental data (2).

Therefore, if we assume that a CICR model describes the propagation mechanism of TPCs, it is important to know how fast Ca²⁺ diffuses through cells as well as from cell to cell within trabeculae.The equivalent diffusion coefficient (D_eq) in water (D_sol) forCa²⁺ is 750 × 10⁸ cm²/s (30); D_eq in myoplasm (D_myop) for Ca²⁺ is unknown but should be lower than that in pure water becauseof the intracellular milieu, which has an ionic strength of 0.15-0.20M, and the presence of large protein moieties (22). In a multicellularpreparation, Ca²⁺ must diffuse from cell to cell through gap junctions (GJs), whichrespond dynamically to a variety of regulatory factors (24),such that D_eq in trabecula (D_trab) for Ca²⁺ should be affected by the agents that alter the permeabilityof gap junctions (P_GJ). Recently, we demonstrated that octanoland heptanol, which decrease open probability of GJ channels ina nonselective manner (26), reduce the propagation velocity,triggering rate, and force of TPCs (31). These observationsare consistent with the idea that Ca²⁺ diffuses from cell to cell through GJs for the propagation ofa TPC. However, the direct effects of octanol or heptanol on P_GJin intact cardiac muscle have not yet been evaluated.

With regard to Ca²⁺ dynamics within trabeculae during TPCs, regional increases in intracellular Ca²⁺ concentration ([Ca²⁺]_i) are thought to underlie the TPCs and are assumed to be similarto the Ca²⁺ waves in single myocytes (16-18). Furthermore, Ca²⁺ sparks and waves occur at a subcellular level (20) and Ca²⁺ sparks precede or lead to Ca²⁺ waves in myocytes (6). In contrast, little is known aboutthe spatial and temporal changes in [Ca²⁺]_i in multicellular cardiac trabeculae.

Therefore, in this study we have tested 1) whether a regional increase in [Ca²⁺]_i propagates along trabeculae during a TPC in multicellular preparations(>1 mm). Furthermore, we determined 2) the diffusion propertiesfor fura 2 to evaluate how Ca²⁺ ions diffuse through cells as well as from cell to cell withintrabeculae and 3) the effects of octanol on fura 2 diffusion properties.Subsequently, we could then evaluate to what extent Ca²⁺ diffusion through the myoplasm and the GJs is affected by octanolunder our experimental conditions. Preliminary data have recentlybeen published (31).

	METHODS

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Dissection and Mounting of Rat Ventricular Trabeculae

Lewis Brown Norway rats (250-300 g) were anesthetized with diethyl ether. The hearts were excised, and the coronary arterieswere immediately perfused via the aorta with Krebs-Henseleit (KH)solution modified by adding 15 mM KCl. After the arrest of theheart, long, thin trabeculae (n = 27, length = 2.6 ± 1.2 mm, width= 260 ± 150 µm, thickness = 110 ± 29 µm) were dissected from 27rat right ventricles and were mounted horizontally between a forcetransducer and a micromanipulator in a perfusion bath locatedon the stage of an inverted microscope (Nikon). Preparations weresuperfused with bicarbonate-buffered KH solution containing (inmM) 120 NaCl, 5 KCl, 1.2 MgCl₂, 1.2 Na₂SO₄, 2.0 NaH₂PO₄, 19 NaHCO₃,10 glucose, and CaCl₂ as specified in Fura 2 loading. All solutionswere in equilibrium with 95% O₂-5% CO₂ such that pH was 7.4.

Experimental Equipment

Figure 1A shows the experimental setup. Light from a 150-W xenon arc lamp (model 6255, Oriel, Stratford, CT) was filteredusing band-pass filters (Melles Griot, Irvine, CA) centered at340, 360, or 380 nm. Band-pass filters had band widths of 10 nmand were switched manually. Filtered light was projected ontothe trabeculae via a ×10 UV-Fluor objective lens (Nikon) of themicroscope using a dichroic mirror (400 DPLC, Omega Opticals).The epifluorescence from trabeculae was collected by the objectivelens, passed through a 510-nm band-pass filter (Melles Griot),and then projected onto a photomultiplier tube (PMT; PMT-R2693with a C1053-01 socket, Hamamatsu). The PMT signal was filteredat 100 Hz (3 dB), fed into an analog-to-digital converter (2801AData-Translation, Marlborough, MA), and stored in a personal computer(Gateway 2000, North Sioux City, SD). Alternatively, the fluorescentimage of the trabecula was recorded by a charge-coupled devicecamera coupled to a two-stage image intensifier (IIC; model C330,General Scanning, Watertown, MA) through a 510- to 560-nm band-passfilter (Nikon). Images from the camera were recorded directlywith a videocassette recorder (VCR; EV-S7000 NTSC, Sony, Tokyo,Japan) for later analysis. The VCR allowed reliable display ofsingle-time code video frames. Concurrently, the force of themuscle was measured using a modified silicon semiconductor straingauge (model AE-801, Sensonor, Horten, Norway). Sarcomere length(SL) was measured using laser diffraction by illuminating themuscle with a He-Ne laser (Spectra-Physics, Eugene, OR) describedin detail elsewhere (27). Briefly, the intensity distributionof the first-order diffraction pattern was scanned by a photodiodearray (Reticon 256 EC, Sunnyvale, CA) and SL was calculated fromthe median of the intensity distribution. Trabeculae were stimulatedat 0.5 Hz through two parallel platinum electrodes in the bathusing 5-ms pulses 50% above threshold.

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Fig. 1. A: simplified diagram shows experimental setup used for measurement of fluorescence signals, force (F), and sarcomere length (SL). Xe, xenon arc lamp; PMT, photomultiplier tube; IIC, charge-coupled device (CCD) camera coupled to 2-stage image intensifier; PC, personal computer, VCR, video cassette recorder. B: original SL and stress tracings of last stimulated twitch of a train of 15 twitches at 2 Hz and a subsequent triggered propagated contraction (TPC). SL was measured at 2 sites (A and B) 270 µm apart. During TPC, sarcomere shortening transient (arrowheads) occurred earlier at site A than site B. Experiment was performed at 20.8°C and 1.5 mM extracellular Ca²⁺ concentration ([Ca²⁺]_o). C: in vitro calibration curve. Applied [Ca²⁺] was plotted against ratio of fluorescence at 340 and 380 nm (340/380) calculated from signal of PMT after subtraction of autofluorescence. K_d, effective dissociation constant; R_min, ratio at zero [Ca²⁺]; R_max, ratio at a saturating [Ca²⁺].

Fura 2 Loading and Analysis of [Ca^2+]_i

Fura 2 loading. The free acid form of fura 2 was microinjected electrophoretically into trabeculae, as described previously (1). In brief,the tip of the microelectrode was filled with 2 mM fura 2 pentapotassiumsalt (Molecular Probes, Eugene, OR) and the remainder of the electrodewas back filled with 4 mM KCl. With this microelectrode solution,the tip resistances ranged from 180 to 250 M $Omega$ when measured usingthe standard KH solution. Intracellular membrane potentials weremeasured using an intracellular amplifier (Intra 767, World PrecisionInstruments, Sarasota, FL) and were between $-$ 40 and $-$ 80 mV understandard conditions [SL = 2.1 µm, extracellular Ca²⁺ concn ([Ca²⁺]_o) = 0.7 mM, 26°C]. After stability was achieved, 5-10 nA ofnegative current was passed for 10-20 min. During the injectionperiod, the fura 2 diffused from the impalement site into theadjacent cells via GJs as previously described (1). On completionof injection and removal of the microelectrode, the trabeculawas stimulated at 1 Hz for 30-60 min until uniform loading withfura 2 was obtained. Under such conditions, changes in the fluorescenceratio of fura 2 determined using the IIC or PMT were superimposable,as shown in Fig. 2A, even when the trabecula was moved over severalhundred micrometers, showing that fura 2 loading was uniform.

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Fig. 2. A: superimposed ratio transients (360/380 or 340/380) measured at 3 positions along trabecula (at 0-, 210-, and 650-µm displacement) calculated either from signal of PMT (top) or from signals at central 20 × 20 pixels of IIC (bottom) during same electrically stimulated twitch (0.5-Hz stimulation rate, [Ca²⁺]_o 0.7 mM, and 26°C). B: relationships of ratios determined by IIC vs. PMT at the 3 different positions on trabeculae (0 µm, top; 210 µm, middle; 650 µm, bottom) calculated from A. Note that at each position along trabecula, ratios determined by the 2 methods were correlated linearly. r, Correlation coefficient.

To induce TPCs, bath temperature was lowered to 20-22°C and trains of electrical stimuli (n = 15) were applied at [Ca²⁺]_o of 0.3 mM and SL of 2.10 µm. [Ca²⁺]_o was then increased in steps of 0.2 mM until TPCs appeared (10,19). The measurement of [Ca²⁺]_i was started only when TPCs were reproducible (Fig. 1B).

Analysis of signal from PMT. [Ca²⁺] was determined using the following equation (13) (after subtraction of the autofluorescence of the muscle)

[Ca2+] = <IT>K</IT>d ⋅ &bgr; ⋅ (R − Rmin)/(Rmax − R) (1)

where K_d is the effective dissociation constant, R is the ratio of the fluorescence at 340-nm excitation to that at 380-nmexcitation (340/380), R_min is R at zero [Ca²⁺], R_max is R at a saturating [Ca²⁺], and $beta$ is the ratio of fluorescence value for Ca²⁺-free dye to fluorescence value for Ca²⁺-bound dye at 380-nm excitation. Values for K_d, R_min, R_max, and $beta$ were determined using in vitro calibrations (Fig. 1C) as previouslydescribed (1). Previously, we reported that there is a goodcorrelation between in vitro and in vivo calibrations when freeMg²⁺ is 1 mM in the solutions, mimicking the intracellular milieu(1). Solutions for calibration were prepared using a calciumcalibration buffer kit (Molecular Probes) and contained differentknown free [Ca²⁺], 1 mM free Mg²⁺, 10 mM ethylene glycol-bis( $beta$ -aminoethyl ether)-N,N,N',N'-tetraaceticacid, 100 mM KCl, 10 mM 3-(N-morpholino)propanesulfonic acid,and 1 µM fura 2 (pH 7.2). Calibration was performed by placing100 µl of solutions of different known free [Ca²⁺] into chambers on the microscope stage. Each solution was illuminatedwith 340-, 360-, and 380-nm excitation light, and fluorescencewas collected onto the PMT and then stored in the computer forlater analysis. The background fluorescence was determined byillumination of a solution with zero free Ca²⁺ in the absence of fura 2. Values for K_d, R_min, R_max, and $beta$ werecalculated from the curve describing the relationship betweenthe ratio and pCa. For these experiments the R_min and R_max were0.152 and 4.60, respectively, and K_d and $beta$ were 361 nM and 9.18,respectively. This is in agreement with previous data from thislaboratory (1).

Analysis of image from IIC. The fluorescence data of each video frame were digitized with a 8-bit analog-to-digital converter and stored in a frame buffermemory of 512 × 480 pixels (Coreco). Therefore, in our opticalsystem, 1 pixel of memory corresponded to 2.87 × 2.87 µm of theimage. For analysis of the image, a sampling region of interest(ROI) was set horizontally along the long axis of the fluorescenceimage of trabeculae. The horizontal length of the ROI was always512 pixels (1,470 µm), and its vertical width was 20 pixels (57.4µm). To obtain intensity profiles of the fluorescence (F_s) alongthe long axes of trabeculae, we calculated an average intensityvalue from each vertical line of pixels within the ROI. To eliminatehigh-frequency noise from the intensity profile, we used the low-passfinite impulse response filter of MATLAB (Math Works, Natick,MA), which was a Hamming-windowed, linear-phase filter, and setthe cutoff frequency of the filter at 5 pixels (14.4 µm). Aftersubtraction of the autofluorescence of the muscle, we calculatedthe ratio of the fluorescence at 360-nm to that at 380-nm excitation(360/380) at each point on the average intensity profiles obtainedfrom the images at 360- and 380-nm excitation light.

The area of investigation in the muscle is large (>1 mm) using a ×10 objective lens, and the aperture of the xenon lamp wassmaller than that of the objective lens, such that focusing theexcitation light onto the muscle yielded a nonuniform distributionof light on the muscle within the field of view. Therefore, wecorrected for the effects of this nonuniform illumination as follows.Changes in fluorescence of trabeculae during electrically stimulatedtwitches (26°C, 0.5 Hz, [Ca²⁺]_o = 0.7 mM) were determined using both the IIC and PMT at severalsites along the long axis of the trabeculae, and the values obtainedat these sites were compared (Fig. 2A). For this comparison, wefirst defined an ROI along the long axis of the muscle image recordedby the IIC. We then compared the intensity ratio (360/380) obtainedfrom images at the central 20 × 20 pixels (57.4 × 57.4 µm) tothe ratio (340/380) obtained using the PMT at three differentsites. The ratio changes at the central regions of the IIC weresuperimposable (Fig. 2A) and linearly correlated with the PMTratio changes despite the movement of the trabeculae (Fig. 2B).Therefore, [Ca²⁺]_i transients were uniform throughout the central millimeter ofthe muscle during twitches. Moreover, the calculated ratios (360/380)at each sampling point along the 512 × 20 pixel array, with themuscle in a stationary position, correlated linearly with theratio (340/380 or 360/380) calculated from PMT recordings (r =0.96-0.99) during the twitch; however, the slope of the relationshipvaried at sites along the pixel array. Thus for each trabeculaewe calculated [Ca²⁺]_i at each sampling point after the induction of TPCs using theregression line derived from the relationship between the PMTand IIC ratios determined at the same sampling point. Furthermore,to avoid noise caused by low-excitation light intensity on thefar edges of the profile of fluorescence, we calculated [Ca²⁺]_i only at the regions of the centrally located 250 pixels (719µm) from the fluorescence intensity along the trabeculae.

For the measurement of the velocity of Ca²⁺ waves, we used data from at least three sequential images in which regional [Ca²⁺]_i was changing. Therefore, the time resolution of the imagesis a limitation of our measured velocities. Furthermore, we usedonly data from the centrally located 250 pixels (719 µm) of theintensity profiles in the determination of velocity. Thus theupper limit of the measurable velocity of Ca²⁺ waves using our experimental setup was ~7 mm/s. Results wereobtained from reproducible Ca²⁺ waves that were induced in eight rat right ventricular trabeculae(length = 2.1 ± 0.38 mm, width = 170 ± 19 µm, thickness = 96 ±18 µm) at [Ca²⁺]_o of 0.73 ± 0.30 mM and temperature of 21.5 ± 0.9°C.

Analysis of D_eq for Fura 2

For this subset of experiments, we calculated three types of D_eq for fura 2 along the trabecula, in myocytes, and in solution(D_trab, D_myop and D_sol). All the settings of the IIC and the microscopewere kept constant during the recordings of trabeculae set atSL of 2.10 µm with [Ca²⁺]_o of 0.7 mM.

Measurement of D_trab for fura 2. Fura 2 pentapotassium salt was microinjected electrophoretically into trabeculae (Table 1) using 10 nA of negative currentfor 10 min. To determine the effects of octanol on D_trab, fura2 was injected after a 1- or 3-h superfusion of trabeculae withKH solution containing 100 µM 1-octanol (Table 1). Trabeculaewere constantly stimulated at 0.5 Hz except for the fura 2 injectionperiods. Epifluorescence of the trabeculae obtained using theIIC (see Analysis of image from IIC) was recorded with the VCRat the completion of fura 2 injection and thereafter every 10min for 60 min.

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Table 1. Diffusion coefficients for fura 2 in rat cardiac trabeculae

To determine D_trab for fura 2 in the absence and presence of octanol, we set an ROI of 512 × 21 ± 8 pixels horizontally alongthe long axis of the fluorescence image of trabeculae and calculatedF_s using the procedure described in Analysis of image from IIC.To improve the ratio of signal to noise, we calculated an averagevalue of each horizontally corresponding pixel of F_s from 25 sequentialframes (0.83 s) and obtained an averaged intensity profile ofthe fluorescence (F_av) every 10 min (Fig. 3A). F_av was symmetricalwith respect to the site of impalement and spread at comparablevelocity in both directions in the absence and presence of octanol.To eliminate the effect of uneven intensity of illumination, thefluorescence from the solution containing 1 µM fura 2 pentapotassiumsalt excited by 360-nm light was recorded after the measurementof D_sol. To do this, we set an ROI of 512 × 20 pixels along theimage of the fluorescing solution and calculated an average intensityprofile of fluorescence (F_sol) from each vertical line of pixelswithin the ROI. We then determined a normalized intensity profileof the fluorescence (F_norm) by dividing F_av by the spatially correspondingvalues of the F_sol (Fig. 3B).

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Fig. 3. A: average intensity profiles of fluorescence (F_av) along long axis of trabecula after a 1-h superfusion with 100 µM 1-octanol (0, 10, and 50 min after injection of fura 2). After injection of fura 2, F_av exhibited a maximal value at injection site; fura 2 diffused evenly in both directions, whereas maximal value of F_av decreased. B: left half of normalized intensity profiles of fluorescence (F_norm) obtained by dividing F_av of A by spatially corresponding values of intensity profiles of fluorescence image from solution containing 1 µM fura 2 (F_sol; not shown). Solid lines reflect regions of the 3 profiles in which intensity varied between 73 and 27% of maximal intensity. C: fit of intensity of profile (27-73% of maximal intensity) shown in B to diffusion equation (Ref. 7). Abscissa shows square of distance (X²) from region in which fura 2 had been injected; ordinate shows natural log of F_norm. These relationships were fitted by linear regression (r = 0.99-1); slope coefficients equal $-$ 1/(4 · D_trab · t). D_trab · t was calculated from fit data. D: relationship between time after fura 2 injection vs. D_trab · t. D_trab was calculated from slope of relationship.

F_norm exhibited a maximum at the region in which fura 2 had been injected. To obtain D_trab at each time point, F_norm valueswhere intensity equaled 73 and 27% of the maximal intensity (solidlines in Fig. 3B) were fit to the following general diffusionequation for a plane sheet (7)

F<SUB>norm</SUB> = <IT>K</IT>/2(&pgr;<IT>D</IT><SUB>eq</SUB><IT>t</IT>)<SUP>1/2</SUP> exp (−<IT>x</IT><SUP>2</SUP>/4<IT>D</IT><SUB>eq</SUB><IT>t</IT>)

(2)

where K is a constant related to the amount of the fura 2 deposited in the cell, t is time, and x is the distance from thecenter of the intensity profile. Because D_eq is the equivalentdiffusion coefficient in the sheet, D_eq equals D_trab for our measurement,spanning 500-1,000 µm along the trabecula, and D_eq is D_myop forour measurement of changes of the fluorescence profile over distances<100 µm. For all data, we avoided using peak and far-edge valuesof fluorescence, because the peak region signals often saturatedthe IIC and the far-edge signals showed noise caused by low-excitationlight. From the fitted data, D_trab · t was calculated (Fig. 3C).This procedure was repeated for the profiles obtained every 10min. D_trab · t depended in a linear manner on the time of measurement(Fig. 3D). Therefore, the effects of octanol we observed werenot caused by a progressive decrease of D_trab during the samplingperiod. Accordingly, calculated D_trab will reflect the diffusioncoefficients 1.5 h (or 3.5 h) after the first exposure of themuscle to octanol. D_trab was calculated from the time course ofD_trab · t (Fig. 3D). There was no significant difference in theshapes of trabeculae, temperature, or the remaining force amongthe groups (Table 1).

Measurement of D_myop for fura 2. Fura 2 was microinjected 11 times into three trabeculae (Table 1) using 7 nA of negative current for 10-20 s. To study theeffects of octanol on D_myop, fura 2 was microinjected 6 timesinto trabeculae after 1 h of superfusion of the muscle with 100µM 1-octanol and 11 times into the same trabeculae (Table 1)after a 3-h superfusion with the same solution. The epifluorescencefrom the trabeculae was recorded, using the procedure describedin Analysis of image from IIC, for 30 s immediately after thecompletion of each fura 2 injection.

To determine D_myop from these image profiles, a narrow ROI of 512 × 3 pixels (1,472 × 8.63 µm) was set through the spot ofinjected fura 2 along the long axis of the trabeculae and F_s valueswere determined. F_av was then calculated (Fig. 4A) from eightsequential frames (0.27 s) obtained every 5 s as described inMeasurement of D_trab for fura 2. We calculated F_norm (Fig. 4B)and fitted data to Eq. 2 using the procedure described for ourmeasurement of D_trab (Fig. 4C). D_myop was calculated directlyfrom the time course of D_myop · t (Fig. 4D). There were no significantdifferences in the shapes of trabeculae, temperature, or the forcedevelopment between the groups (Table 1).

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Fig. 4. A: F_av along long axis of trabecula at 5, 15, and 30 s after injection of fura 2 in absence of octanol. Intensity profile of F_av spread at almost comparable velocities in both directions. B: left half of F_norm obtained by dividing F_av (A) by spatially corresponding values of F_sol from solution containing 1 µM fura 2. Solid lines reflect regions of the 3 profiles where intensity varied between 73 and 27% of maximal intensity. C: fit of intensity values of profile (27-73% of maximal intensity) shown in B to diffusion equation (7). Abscissa shows square of distance (<50 µm) from region in which fura 2 had been injected; ordinate shows natural log of F_norm. These relationships were fitted by linear regression (r = 0.95-0.99); slope coefficients equal $-$ 1/(4 · D_myop · t). D_myop · t was calculated from fitted data. D: plots of time after fura 2 injection against D_myop · t. D_myop was calculated from slope of relationships. E: 3 examples of F_av relations that showed clear asymmetries after a 3-h superfusion with octanol. Fura 2 diffused slowly outside a limited region within muscle; edges of these regions are indicated by gray bars. Distance between edges of serial F_av at 5, 15, and 30 s after injection was 100-150 µm, i.e., similar to length of a single myocyte. We assumed that GJs were located at regions indicated by gray bars (see DISCUSSION). In these cases we calculated D_myop using diffusion in direction indicated by arrows.

Often the profiles of F_av showed clear asymmetries after a 3-h exposure to octanol (Fig. 4E). That is, it appeared that fura2 diffused away from the impalement site with different velocitiesin opposite directions. We further observed that, after octanolexposure, fura 2 diffused very slowly across regions that were~100 µm apart bordering the injected cell. The border regionsare indicated by the gray bars in Fig. 4E. In these cases we calculatedD_myop using the diffusion toward the direction indicated by arrowsinside the gray bars.

Measurement of D_sol for fura 2. A droplet of fura 2 solution (300-µm diameter) was placed in a stationary flow bath and image profiles of the droplet excitedby 360-nm light were recorded for 30 s at room temperature (20°C).To determine D_sol for fura 2, an ROI of 512 × 20 pixels was sethorizontally through the fura 2 droplet. The F_av was calculatedfrom F_s obtained from eight sequential frames (0.27 s) every 5s. With F_av, D_sol was then determined at every 5 s for 30 s usingthe procedure described above. The contribution of convectivefluid motion caused by illumination of the fluid was ignored.

Calculation of P_GJ. P_GJ was calculated using the following equations (7, 12)

<IT>L</IT>/<IT>D</IT>trab = <IT>L</IT>myoc/<IT>D</IT>myop + <IT>L</IT>GJ/<IT>D</IT>GJ (3)

<IT>P</IT>GJ = <IT>D</IT>GJ/<IT>L</IT>GJ (4)

where L_myoc is the length of one myocyte, L_GJ is the dimension of GJs, and L is the total length of L_myoc and L_GJ. For thecalculation of P_GJ, we used 100 µm for L_myoc.

Statistics

All averaged values are expressed as means ± SD. Single-factor analysis of variance was used to detect significant difference(P < 0.05).

	RESULTS

Top Abstract Introduction Methods Results Discussion References

Diffusion of Fura 2

Diffusion of fura 2 in free solution was ~10 times faster than that in the myoplasm (Table 1). In addition, diffusion throughthe cytosol of single cells was twice as fast as diffusion throughthe whole trabecula. Octanol did not reduce the diffusion of fura2 through the cytosol but reduced the diffusion through the trabeculatwofold and threefold after 1 and 3 h of superfusion, respectively(Table 1). A brief injection of fura 2 caused an oval spot offluorescence with the long axis parallel to the muscle axis; thelength of the spot was <100 µm. It was striking that, after a3-h superfusion with octanol, F_av after a similar brief injectionof fura 2 often showed a clear asymmetrical pattern along muscle(Fig. 4E). We assume that in these cases the microelectrode hadbeen positioned in the muscle near the end of the cell and thatdiffusion toward the cell center was faster than that toward adjacentcells. Accordingly, for the three cases shown in Fig. 4E, we calculatedthe diffusion coefficient using the diffusion of fura 2 in bothdirections. The calculated diffusion coefficient toward the directionindicated by arrows was 43.9 ± 30.3 × 10⁸ cm²/s, whereas the diffusion coefficient in the opposite directionacross the regions including the gray bars was 6.99 ± 2.56 × 10⁸ cm²/s. The latter value is similar to the value of the D_trab obtainedafter a 3-h superfusion with octanol (Table 1). It should benoted that in Fig. 4E the distance between the gray bars was 100-150µm, i.e., similar to the length of a single myocyte.

We are not aware of data to compare our D_GJ measures directly with those of previous studies. Therefore, we calculated theP_GJ from D_trab and D_myop using Eqs. 3 and 4 (see METHODS). Itfollows from Eqs. 3 and 4 that

<IT>P</IT>GJ = <IT>D</IT>trab ⋅ <IT>D</IT>myop/(<IT>L</IT> ⋅ <IT>D</IT>myop − <IT>L</IT>myoc ⋅ <IT>D</IT>trab) (5)

where P_GJ does not require an assumption about the linear dimension of the GJs (L_GJ) and thus can directly be compared withresults from studies on cell pairs. When we calculated P_GJ forfura 2 based on our average values of D_trab and D_myop, we foundthat P_GJ was reduced from 4.15 × 10⁵ cm/s in control to 2.10 × 10⁵ cm/s and 0.86 × 10⁵ cm/s after 1 and 3 h of superfusion with 100 µM 1-octanol, respectively(Table 1). Our control calculated P_GJ for fura 2 pentapotassiumsalt (mol wt 832) is in close agreement with data presented byDr. Irisawa's group (15) depicting the relationship betweenthe P_GJ of a solute and its molecular weight. They showed thatthere is an inverse linear relation between log(P_GJ) and molecularweight (see Fig. 8 in Ref. 15), where P_GJ values range from7 × 10⁵ cm/s (mol wt 559, lissamine rhodamine B-200) to 770 × 10⁵ cm/s (mol wt 39, K⁺).

The conductance of GJs (g_GJ) at a voltage difference across the GJs of 0 mV can now be calculated using P_GJ and the followingequation (12)

<IT>g</IT>GJ = <IT>F</IT>2 <IT>P</IT>GJ <IT>A</IT> (Cout − Cin)/<IT>RT</IT> (6)

where F is the Faraday constant, C_out is the concentration of fura 2 within the cell in which fura 2 had been injected (M₀),C_in is the concentration of fura 2 within the neighboring cell(M₁) of M₀, A is the area of intercalated disk between M₀ andM₁, R is the molar gas constant, and T is absolute temperature.The calculated g_GJ is ~3.3 nS. When we calculate the conductanceof a single GJ channel on the assumption that open probabilityof the GJ channel is 0.43% and that GJ channel density is 2.3× 10⁴ µm² in rat ventricular muscle (15), the conductance of a singleGJ channel for fura 2 is ~0.15 pS. Using the relationship betweenP_GJ and molecular weight of the solute, this value would predicta unitary conductance for K⁺ of ~28 pS in trabeculae, which is in the same order of magnitudeas the reported unitary conductance of GJ channels for K⁺ (~50 pS) (24).

Ca²⁺ Waves During TPCs

Figure 1B shows a typical TPC in the form of a traveling sarcomere shortening wave accompanied by an aftercontraction (10,19). Although several studies have implied that such TPCs arerelated to traveling Ca²⁺ waves in trabeculae (10, 19), there has been no direct proofof this. In fact, in a previous publication (31) we only hypothesizedthat octanol affected TPC propagation via its effect on P_GJ (seeDiffusion of Fura 2), thereby reducing the likelihood of propagatingCa²⁺ waves. Therefore, in the next series of experiments, we determinedthe spatial and temporal changes in [Ca²⁺]_i in intact trabeculae during a TPC.

Figure 5 shows a typical example of the global [Ca²⁺]_i and the force development during the last electrically stimulated twitchof a train and a subsequent TPC in one trabecula at 22.1°C and[Ca²⁺]_o of 0.7 mM. Figure 5A shows the change in [Ca²⁺]_i calculated from a PMT signal. When the muscle was stimulatedat 2 Hz, the Ca²⁺ transient shortened progressively so that the total durationafter 15 stimuli was ~0.37 s. Figure 5B shows the force recordsmade while fluorescence was recorded, first using excitation withUV light at 340 nm followed by excitation at 380 nm. The arrowsindicate an increase in [Ca²⁺]_i (Fig. 5A) and the occurrence of an aftercontraction (Fig. 5B)observed during a TPC. The global measurement obtained with thePMT shows that the amplitude of the Ca²⁺ transient during the TPC is small (10%) compared with that ofthe preceding stimulated twitch and lasts twice as long as theCa²⁺ transient of the twitch. The force transient of the TPC is alsosmall in amplitude (14%) and lasts longer (40%) than that of thepreceding stimulated twitch. The force transient of the TPC lastsslightly longer than the concomitant Ca²⁺ transient. In this study, all imaging data were accepted foranalysis when the stresses recorded at both excitation wavelengthswere identical as shown in Fig. 5.

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Fig. 5. Global intracellular Ca²⁺ concentration ([Ca²⁺]_i) calculated from fluorescence signals recorded by PMT (A) together with force records (normalized for cross-sectional area of muscle) recorded at 340- and 380-nm excitation wavelength (B) during last electrically stimulated twitch and a subsequent TPC. Arrows indicate an increase in [Ca²⁺]_i and an aftercontraction during which a TPC was observed. s, Moment of electrical stimulation.

To determine the spatial and temporal changes in [Ca²⁺]_i during the TPC, we analyzed the images recorded by the IIC directlyafter a PMT recording. Figure 6 shows the last stimulated Ca²⁺ transient and a cytosolic Ca²⁺ wave during the TPC in the same trabeculae as presented in Fig.5. In this three-dimensional representation the abscissa is time,the ordinate is [Ca²⁺]_i, and the z-axis is the position of each pixel along the longaxis of the trabecula. After the end of a series of stimulatedCa²⁺ transients, a smaller Ca²⁺ transient was observed to move as a wave from position A (indicatedby * in Fig. 6) toward position B. The Ca²⁺ waves appeared to travel at constant velocity along the trabeculaesimilar to properties of TPCs we have previously described (Refs.10, 19; Fig. 1B).

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Fig. 6. Regional [Ca²⁺]_i calculated from images by IIC during last electrically stimulated twitch and a TPC a few minutes after recording of PMT shown in Fig. 5. Abscissa, time; ordinate, [Ca²⁺]_i; z-axis is position along long axis of trabecula. After end of clearly uniform stimulated Ca²⁺ transient, a smaller Ca²⁺ transient appeared to move from A (*) toward B (for explanation see text).

To calculate of the velocity of the Ca²⁺ wave in Fig. 6, we selected the peak of the Ca²⁺ transient during the Ca²⁺ wave at each pixel along the trabeculae and plotted the timeof the peak point against the position of the peak (Fig. 7A).Regression analysis showed a linear relationship. The slope ofthe fitted line was taken as the velocity of the Ca²⁺ wave occurring during the TPC. This analysis shows that the Ca²⁺ wave propagates along the trabecula at a constant velocity, andthe calculated velocity of the Ca²⁺ wave was 2.27 mm/s (Fig. 7A). The analysis of 10 reproducibleCa²⁺ waves in 8 trabeculae shows that the velocity of the travelingCa²⁺ waves was 1.69 ± 1.48 mm/s (range 0.34-5.47 mm/s, n = 10) at[Ca²⁺]_o of 0.73 ± 0.30 mM and a temperature of 21.5 ± 0.9°C. Figure7B shows that the [Ca²⁺]_i at the peak of the Ca²⁺ wave and the diastolic [Ca²⁺]_i between the last stimulated Ca²⁺ transient and the Ca²⁺ wave at each pixel position along the trabeculae were almostconstant.

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Fig. 7. A: relationship between moment at which [Ca²⁺]_i during Ca²⁺ wave (Fig. 6) was maximal against position of maximal point along trabecula. Relationship was fitted by linear regression (r = 0.971); slope of fitted line was taken as velocity of Ca²⁺ wave. B: peak [Ca²⁺]_i during Ca²⁺ wave (solid line) and diastolic [Ca²⁺]_i between last stimulated Ca²⁺ transient and Ca²⁺ wave (dotted line) as a function of position along trabecula. C: average [Ca²⁺]_i in a 600-µm-long region of interest (ROI) along trabecula (calculated from Fig. 6). Solid line shows average of stimulated Ca²⁺ transients during twitch and average of Ca²⁺ transient during Ca²⁺ wave (TPC) after correction for time required for Ca²⁺ wave to move from pixel to pixel as calculated from Fig. 6. Dotted line shows same trace of global change in [Ca²⁺]_i as presented in Fig. 5, recorded with PMT from a region of ~1.00 µm that overlapped with ROI of IIC.

The average time course of Ca²⁺ transients during the Ca²⁺ wave was obtained by using our observation that Ca²⁺ waves traveled at constant velocity. Therefore, we could shiftthe time axis of the Ca²⁺ transient of every pixel according to the time required for theCa²⁺ wave to move from pixel to pixel. After this correction, theCa²⁺ transients of all corresponding pixels (n = 250) were averaged.The solid line in Fig. 7C shows the average of the stimulatedCa²⁺ transients in all pixels during the twitch as well as the averageof regional Ca²⁺ transients during the Ca²⁺ wave after the shift of the time axis calculated from the imagingdata of Fig. 6. The peak of the averaged regional Ca²⁺ wave reached 40% of that of the stimulated Ca²⁺ transient, whereas its duration was slightly longer than thatof the stimulated Ca²⁺ transient itself. The time course of decline of the "regional"Ca²⁺ wave was identical to that of the electrically induced transient,although the time constant of decline of Ca²⁺ was shorter in the stimulated Ca²⁺ transient (144 ms) than in the regional Ca²⁺ wave (235 ms) because of the difference in their peak Ca²⁺ levels (4). The rise of the regional Ca²⁺ wave lasted ~0.15 s longer than that of the electrically inducedtransient, accounting for the difference in duration of the twotransients. The dotted line in Fig. 7C shows the same record ofthe global Ca²⁺ transient, measured with the PMT, as presented in Fig. 5A. Thetwofold longer duration of the global Ca²⁺ transient (dotted line) during the TPC is presumably caused bythe displacement of the Ca²⁺ wave during the TPC along the segment of muscle, which was observedby the PMT.

It follows from Figs. 5 and 6 that when the Ca²⁺ wave started during the late relaxation of the twitch [as we have shown previously(19)], the site of origin of the wave must have been located~700 µm from position A toward the tricuspid valve, as was indeedthe distance between position A and the insertion of this trabeculain the AV ring.

In summary, a sequential, spatial, and temporal change in [Ca²⁺]_i (a traveling Ca²⁺ wave) underlies a TPC in thin right ventricular trabeculae. Thesewaves start at one of the damaged ends of the trabeculae.

	DISCUSSION

Top Abstract Introduction Methods Results Discussion References

To our knowledge, this is the first study to provide a quantitative assessment of propagating Ca²⁺ waves in multicellular cardiac preparations. As we discuss here,both the presence and properties of Ca²⁺ waves during TPCs are consistent with a previously proposed modelof propagation, i.e., CICR from the SR mediated by diffusion ofCa²⁺ along the cell. Our previous observation that TPCs are delayedby octanol is consistent with the conclusion from this study thatthe permeability of GJs is drastically reduced by octanol, suchthat the propagation process for TPCs is delayed because of slowerdiffusion of Ca²⁺ from cell to cell.

Diffusion of Fura 2 Within Trabeculae

D_sol for fura 2 is in good agreement with the diffusion coefficient for fura 2 in aqueous solution (390 ± 0.6 × 10⁸ cm²/s) measured previously (28) and is one-half of the D_sol forCa²⁺ (750 × 10⁸ cm²/s; Ref. 30). D_myop for fura 2 calculated within 30 s afterthe injection into trabeculae under drug-free conditions is ingood agreement with the diffusion of fura 2 measured in isolatedsingle myocytes (31.9 ± 18.5 × 10⁸ cm²/s, 21°C; Ref. 5), barnacle muscle fibers (39 × 10⁸ cm²/s, 20°C; Ref. 28), and frog skeletal muscle (36 × 10⁸ cm²/s, 16°C; Ref. 3).

Diffusion of fura 2 (D_trab) calculated for 1 h after the injection of the probe into trabeculae illustrates that an additionaldiffusion barrier was present along trabeculae, because D_trabwas nearly one-half of D_myop. We assume that this barrier is formedby the GJs. Several lines of evidence support this assumption.First, the diffusion coefficient of the GJs (D_GJ) can be calculatedfrom D_myop and D_trab, treating the trabeculae as a planar diffusionsheet. The permeability of GJs follows from D_GJ and is similarto P_GJ determined for molecules of a similar size (15). Second,our calculated g_GJ, based on reasonable assumptions regardingGJ density and open probability, was similar to g_GJ measured inlipid bilayers (24). Third, when we observed fura 2 diffusiondirectly after injection of fura 2 into a cell, cell diffusionwas clearly rapid and unaffected by octanol (see RESULTS).

The asymmetry of short-term diffusion of fura 2 shown in Fig. 4E is also consistent with our interpretation of an effect ofoctanol on GJs for the following reason. In these cases fura 2diffused faster in one direction than another (see RESULTS). Wepropose a simple explanation for this observation, i.e., impalementwith a microelectrode occurs at a random position within the impaledcell. Obviously, the microelectrode is more likely to impale thecell near one of the two ends than in the center. Hence, we assumethat fura 2 diffusion was slow on the side of the fluorescenceprofile when it had been injected near the edge of a cell. Asymmetricaldiffusion was visible in muscles that had not been treated withoctanol (data not shown) but became pronounced after exposureto octanol (Fig. 4E). Calculation of the diffusion coefficientfor the three cases shown in Fig. 4E suggests that diffusion acrossthe regions including the gray bars reflects a barrier with diffusionproperties similar to those of the barrier that exists duringdiffusion along the whole trabecula. In addition, the distancebetween the gray bars was similar to the length of a single myocyte.Thus we assume that GJs were located at the regions indicatedby the gray bars and that the inhibitory effect of octanol ondiffusion of fura 2 is caused by the effect of octanol on GJs.It is reasonable to assume that the reduction of P_GJ by octanolis caused by the reduction of the open probability of GJ channels,as has been described by others (26).

The formation of an oval spot of fluorescence after injection of fura 2 with the long axis parallel to the muscle axis meansthat diffusion of fura 2 is faster longitudinal than transverseto myocardial fiber orientation, suggesting anisotropy of theGJ distribution. This nonuniform distribution of fura 2 is consistentwith the report that velocity of electrical conduction is greaterlongitudinal than transverse to myocardial fiber orientation (23).This report also shows that heptanol slows the conduction velocitytransverse to fiber orientation to a greater degree than longitudinal.However, in this study we did not compare the effect of octanolon P_GJ in the longitudinal direction with that in the transversedirection quantitatively, because we did not measure the effectof octanol on P_GJ calculated from the transverse diffusion offura 2.

In summary, by using diffusion characteristics of fura 2, we conclude that octanol, in a concentration known to affect TPCpropagation velocity (31), reduces P_GJ, thus supporting theconcept that calcium ions need to diffuse from cell to cell throughGJs for propagation of a TPC through normal myocardium.

Ca²⁺ Waves

It is simple to show that the maximal rate of displacement of a Ca²⁺ front by diffusion (starting with the same Ca²⁺ concn gradient as for fura 2 in this experiment) is ~20 µm/s(Fig. 4), assuming that Ca²⁺ diffusion is twice as fast as fura 2 diffusion. This means thatsimple diffusion of Ca²⁺ cannot be responsible for the velocity of TPCs, which is 5-500times higher (10, 19). For this reason, we have previouslyproposed CICR as a propagation mechanism underlying TPCs (2).Although it is reasonable to assume that TPCs are caused by travelingCa²⁺ waves (10, 19), there has been no direct proof of this. Infact, in a previous publication (31) we only hypothesized thatoctanol affected TPC propagation via its P_GJ effect (see Diffusionof Fura 2 Within Trabeculae), which would then reduce the likelihoodof propagating Ca²⁺ waves.

Comparison between global and regional measurement. The global Ca²⁺ transient (Figs. 5 and 7) during the TPC showed a smaller maximal amplitude and longer duration than the regionalCa²⁺ transients (Figs. 6 and 7). This difference can be explainedin a straightforward manner because the PMT averages the fluorescenceintensity from an area of the muscle that is ~1 mm long. The Ca²⁺ wave travels at 2.27 mm/s and lasts ~0.40 s. Therefore, the PMTis expected to "see" a Ca²⁺ wave that lasts ~0.84 s (1/2.27 s + the duration of the waveitself), as is indeed the case. For the same reason, the maximalamplitude of the global Ca²⁺ wave seen by the PMT is expected to be almost one-half of thatof the regional Ca²⁺ wave, as is the case.

Comparison with Ca²⁺ waves in single myocytes. The Ca²⁺ waves during TPCs in trabeculae propagate faster (0.34-5.47 mm/s) than the reported Ca²⁺ waves in isolated single myocytes (~0.1 mm/s; Refs. 16-18). Inour previous studies, the velocity of the TPCs varied dependingon the [Ca²⁺]_o, the number and frequency of the electrical stimuli (10,19), and the presence or absence of Ca²⁺ channel agonists and antagonists (11). These observations areconsistent with the assumption that Ca²⁺ loading of the cell is the main determinant of the velocity ofthe TPCs. Thus we assume that the Ca²⁺ waves during TPCs propagate along trabeculae faster than theCa²⁺ waves in single myocytes, because both the myoplasm and the SRare probably more loaded with Ca²⁺ in trabeculae than in myocytes because of the preceding repetitivestimulation and thereby CICR is probably facilitated.

The duration of the Ca²⁺ transient (~0.40 s) during Ca²⁺ waves in trabeculae was similar to that in single myocytes (0.35-0.45s), whereas the region of elevated [Ca²⁺]_i (~900 µm) during Ca²⁺ waves in trabeculae was larger than that reported in single myocytes(30-50 µm; Refs. 16, 18). This observation is consistent withthe prediction that the faster a Ca²⁺ wave propagates along a trabecula, the larger the region of theelevated [Ca²⁺]_i (2).

Comparison with TPCs. Similar to the TPCs (10, 19), the propagation velocity of the Ca²⁺ waves was constant along the trabeculae (Fig. 7A) and variedunder the conditions in this study from 0.34 to 5.47 mm/s (mean1.69 ± 1.48 mm/s). We were unable to measure Ca²⁺ waves with a velocity >7 mm/s in our experimental setup (seeMETHODS). The duration of the Ca²⁺ transients seen in this study during Ca²⁺ waves was ~0.40 s (Fig. 7C), which is similar to the durationof the SL shortening waves observed during TPCs (10, 19).Furthermore, our results are consistent with the observation thatTPCs are initiated at or near the (damaged) ends of the trabeculae(19). These similarities in behavior suggest that Ca²⁺ waves underlie TPCs in trabeculae.

Comparison with CICR computer model of Ca²⁺ wave propagation. Propagation of the Ca²⁺ waves was clearly faster than the expected maximal rate of displacement of a diffusion front of Ca²⁺ (20 µm/s, see above). The presence of Ca²⁺ waves during TPCs is consistent with the hypothesis that TPCspropagate along the trabeculae by CICR mediated by Ca²⁺ diffusion to adjacent SR. This hypothesis is supported by theobservation that the time course of the Ca²⁺ wave is similar to that of the electrically evoked transient,suggesting that the Ca²⁺ wave and twitch transient share underlying mechanisms. In particular,our observation is consistent with the report that the declineof Ca²⁺ during both the Ca²⁺ transients is mainly caused by uptake by SR and that the rateof uptake depends on the [Ca²⁺]_i (4).

The duration of the regional Ca²⁺ transients observed during TPCs was longer and the amplitude was smaller than the result ofthe computer-simulated model of CICR (2). The computer model,however, was developed on the basis of the time course of [Ca²⁺]_i as estimated from aequorin. The aequorin signal is proportionalto ([Ca²⁺]_i)^2.5, so the signal tends to underestimate the diastolic Ca²⁺ level. This then would tend to curtail the transient and to overestimatethe diastolic [Ca²⁺]_i if no allowance for this relationship is made. Accordingly,later studies (17), including this study, where more sensitivefluorescent probes have been used, have reported substantiallylower diastolic [Ca²⁺]_i and substantially longer [Ca²⁺]_i transients during the stimulated twitch (see Fig. 2A). Evenwith these fluorescent probes, reported [Ca²⁺]_i values should be considered with caution because it has beenrecently reported that the calculated subsarcolemmal [Ca²⁺]_i reaches a higher peak and falls more quickly than the bulk[Ca²⁺]_i during spontaneous Ca²⁺ release from the SR (29). This is presumably caused by a barrierto diffusion of Ca²⁺ that separates the bulk cytoplasm from the subsarcolemmal space.This phenomenon adds to the causes for the difference betweenour data and the computer results, because the [Ca²⁺]_i measurement using fura 2 is thought to reflect the [Ca²⁺]_i in the bulk cytoplasm. On the other hand, parameter valuesused for previous simulation (2) were obtained at low temperatures,e.g., the troponin Ca²⁺ binding sites and troponin Ca²⁺-Mg²⁺ binding sites at 4°C (14) and the SR pump rate at 15°C (21).The difference between the temperature in our experiments andthat used in the computer model may have reduced differences betweenobservations in this study and the results from the computer simulation.Still, it is clear that with the present quantitative data inhand it is worthwhile to model propagating Ca²⁺ waves on the basis of CICR coupled by Ca²⁺ diffusion again.

Limitation of resolution of fluorescence measurement. Injection of fura 2 into single cells for the measurement of D_myop probably allowed resolution within a few micrometers, suchthat transport from cell to cell (via GJs) could be monitored.In contrast, we cannot expect to resolve events at this levelwhen Ca²⁺ waves pass through the trabeculae. Trabeculae were ~90-µm thick,so that Ca²⁺ waves passing through the four cells above and below the planeof focus contributed to the wave observed by the IIC. This wouldblur the observed image in such a way as to make it impossibleto resolve events at the level of the cell edges. The above "averaging"effect may also explain why we have not observed local variationsin the velocity of Ca²⁺ waves as one would expect based on simple Ca²⁺ diffusion characteristics through GJs versus the adjacent cytosol.On the other hand, this error may be small because in one studyof Ca²⁺ waves and cell-cell coupling (25), no delay in propagationat the GJs was detected even using confocal microscopy. (Note,however, that in this latter study propagation occurred at lowervelocity than that in our study.)

Summary

1) Ca²⁺ waves were observed during TPCs in rat cardiac trabeculae and appeared to propagate at a constant velocity (1.69 ± 1.48mm/s) along this syncitium. 2) Fura 2 diffusion properties intrabeculae are consistent with the properties that have been reportedboth for fura 2 in the cytoplasm of isolated myocytes and forGJs. However, the diffusion properties alone do not allow fordisplacement of Ca²⁺ waves at the velocity measured in the trabeculae. 3) Octanol,which reduced the propagation velocity of TPCs, reduced only theP_GJ in trabeculae under our experimental conditions. These observationssupport the hypothesis that TPCs are caused by CICR from the SRmediated by diffusion of Ca²⁺ through cells and from cell to cell through GJs.

	ACKNOWLEDGEMENTS

This work was supported by grants from the Alberta Heart and Stroke Foundation. H. E. D. J. ter Keurs is a Medical Scientistof the Alberta Heritage Foundation for Medical Research. M. Miuraholds a postdoctoral research fellowship from Merck Frosst Canada.

	FOOTNOTES

Address for reprint requests: H. E. D. J. ter Keurs, Dept. of Medicine, Health Science Ctr., 3330 Hospital Dr. NW, Calgary, Alberta, Canada T2N 4N1 (E-mail: henk{at}cvrsun1.cvr.ucalgary.ca).

Received 29 May 1997; accepted in final form 15 August 1997.

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