Regional, age-dependent, and genotype-dependent differences in ventricular action potential duration and activation time in 410 Langendorff-perfused mouse hearts

Although numerous studies have reported the effects of genetic alterations on murine electrophysiology, the range of normal values for ventricular activation, repolarization, and arrhythmias in mouse hearts is not known. We analyzed right ventricular (RV), left ventricular (LV), and septal activation times, monophasic action potential durations (APD), and right ventricular effective refractory periods during spontaneous rhythm, induced AV nodal block, right ventricular pacing (100–300 ms paced cycle length), and programmed stimulation in 410 beating, Langendorff-perfused, wild-type mouse hearts of CD1, DBAC3H, FVBN, C57/Bl6, and hybrid backgrounds (age 203 ± 132 days). Action potential duration was longer at longer cycle lengths. LV-APD prolonged more than RV-APD, resulting in an increased heterogeneity of APD at longer pacing cycle lengths. Higher heart weight/body weight ratio and DBAC3H and FVB/N backgrounds were associated with long APD, C57Bl/6 background was associated with short APD. Activation times were longer in older hearts. There were no clear-cut sex-dependent APD differences. Sustained spontaneous arrhythmias occurred in 1% of hearts, non-sustained arrhythmias in 18%. Induction of AV block and C57Bl/6 genetic background were associated with spontaneous arrhythmias. Programmed stimulation induced arrhythmias in 51% of hearts. Inducible arrhythmias were associated with advanced age and shorter refractory periods. Ventricular APD in beating mouse hearts show rate- and site-dependent changes comparable to man and large animals. Bradycardia provokes spontaneous arrhythmias in mouse heart, while age-dependent conduction slowing and short refractory periods predispose to induced arrhythmias. Genetic background influences repolarization and arrhythmogenesis. These findings provide systematic data for the design and interpretation of arrhythmia studies in murine disease models.     

Simultaneous measurements of action potential duration and intracellular ATP in isolated ferret hearts exposed to cyanide

Shortening of the cardiac action potential during ischemia and anoxia is likely to contribute to the decline in contractility that occurs under such conditions. It has been hypothesized that a decrease in the intracellular ATP concentration ([ATP]i) underlies the changes in the action potential. The recently discovered potassium channel activated at low ATP concentrations might provide the link between action potential shortening and low [ATP]i. However, it has yet to be shown that [ATP]i falls to the range required for channel activation at the time when action potential shortening occurs. We have measured action potentials and [ATP]i simultaneously in isolated ferret hearts during inhibition of both oxidative phosphorylation and anaerobic glycolysis (metabolic blockade). Metabolic blockade caused a rapid decline in cardiac contractility, accompanied by a rapid fall in action potential duration. [ATP]i fell only slightly and remained well above the range where activation of the ATP-sensitive K+ channel would be expected to occur. Moreover, reintroduction of glucose to the perfusate led to a substantial recovery in both contraction and in action potential duration, again in the absence of any great change in [ATP]i. These results suggest that the action potential shortening observed in metabolic blockade cannot be explained by the simple hypothesis of K+ channel opening as a consequence of a decrease in bulk [ATP]i unless the Km for suppression of channel activity by ATP is very much higher in intact cells than in any of the patch configurations studied. An alternative explanation is that the channel may be regulated under these conditions by mechanisms other than a change in [ATP]i.     

Tumor necrosis factor-alpha downregulates the voltage gated outward K+ current in cultured neonatal rat cardiomyocytes: a possible cause of electrical remodeling in diseased hearts.

BACKGROUND: Inflammatory cytokines have been reported to contribute to the progression of cardiac remodeling in various heart diseases and a remarkable prolongation of the monophasic action potential duration and reductions in the expression of Kv4.2 and K+ channel-interacting protein-2 (KChIP-2) in a rat autoimmune myocarditis model have been documented. In this study, the effect of tumor necrosis factor-alpha (TNF-alpha) on cultured cardiomyocytes was evaluated, focusing on the change in the voltage-gated outward K+ current and expression of related molecules. METHODS AND RESULTS: Cardiomyocytes isolated from 1-day-old Lewis rats were cultured for 72 h and treated with TNF-alpha (50 ng/ml) for an additional 48 h. The myocytes treated with TNF-alpha showed a 22% reduction in the peak K+ current, which consisted of a transient outward K+ current (Ito) and 1.4-fold enhancement of the cell-capacitance in comparison with the control. Among the cardiac ion channel related molecules evaluated in this study, Kv4.2 and KChIP-2 mRNA exhibited remarkable reductions (p < 0.05). CONCLUSIONS: Treatment with TNF-alpha induced reductions in Ito as well as cellular hypertrophy in neonatal cultured myocytes, which indicates that TNF-alpha might play a role in promoting electrical remodeling of cardiomyocytes under inflammatory conditions.     

Mechanically induced action potential changes and arrhythmia in isolated and in situ canine hearts

Stretch of excised myocardial tissue causes electrophysiological and potentially arrhythmogenic changes in transmembrane action potentials but corresponding data of the intact mammalian heart are lacking. The effects of increases in ventricular volume and pressure on epicardial monophasic action potentials were therefore investigated in isolated, cross circulated and in situ canine hearts. In seven isolated hearts, increases in ventricular volume and pressure resulted in (1) a linearly related decrease in action potential amplitude (r = 0.988; slope = 0.41% amplitude.ml-1; volume intercept = 17.6 ml), mainly due to a decrease in maximum diastolic potential; (2) a decrease in action potential plateau duration (at 20% repolarisation) by 19 (SD 8)%; and (3) appearance of early afterdepolarizations, reaching up to 18% of total action potential amplitude. Afterdepolarizations occurred only when ventricular outflow was obstructed at end diastole but not at end systole. In eight in situ hearts, increase in left intraventricular pressure produced by transient occlusions of the ascending aorta was also accompanied by decrease in maximum diastolic potential and action potential plateau duration, and by appearance of early afterdepolarizations. In both isolated and in situ intact ventricles, the loading induced electrophysiological changes were associated with occurrence of ectopic ventricular beats. These data show that mechanical overload produces significant electrophysiological changes in the intact canine ventricle which may lead to arrhythmia.     

Heterogeneous changes in action potential and intracellular Ca2+ in left ventricular myocyte sub-types from rabbits with heart failure

OBJECTIVE: Myocardial cellular electrophysiology and intracellular Ca2+ regulation are altered in heart failure. The extent of these changes may vary within the layers of the ventricular wall. To examine this, cell size, action potential and intracellular Ca2+ transient characteristics (Fura-2) were measured in single cardiac myocytes from sub-epicardial, mid-myocardial, and sub-endocardial regions of the left ventricle of rabbits with heart failure. METHODS: Myocytes were isolated from animals with heart failure induced by chronic coronary artery ligation and from sham operated controls. Trans-membrane potential was measured using high resistance microelectrodes electrodes (30 M omega; 2 M KC1). Fura-2 was loaded into cells by incubation with the AM form. Subsequent fluorescence measurements were used to measure intracellular Ca2+ concentration at a range of stimulus frequencies. RESULTS: Resting cell length was significantly greater in the heart failure group; approximately 115% of control values in sub-epicardial and mid-myocardial cells, and approximately 108% in sub-endocardial cells. Using criteria described by previous studies on other mammalian hearts, functional M cells were identified by a higher maximum rate of depolarisation and longer action potential duration at 90% repolarisation (APD90) compared to the two other myocyte sub-types. In the heart failure group, APD90 and Ca2+ transient duration (CaD50) were prolonged in sub-epicardial and M cells but shortened in sub-endocardial myocytes. These changes were significant at lower stimulus frequencies, but the relative effect diminished at higher frequencies (3 Hz). Peak systolic [Ca2+] was reduced in sub-epicardial and M cells but increased in sub-endocardial cells in the heart failure group compared to controls. At higher stimulus frequencies, end diastolic Ca2+ levels were lower in sub-epicardial cells but higher in sub-endocardial myocytes of the heart failure group compared with controls. In general, changes were greater in heart failure animals with more severe in vivo ventricular dysfunction (ejection fraction < or = 44%). CONCLUSIONS: Heart failure was associated with an increased cell size throughout the left ventricle, but the form of the changes in electrophysiology and Ca2+ transient were dependent on the myocyte sub-type. In particular sub-endocardial cells displayed markedly different changes compared to the other myocyte sub-types.     

Cardiac cell action potential duration is dependent upon induced changes in free Ca2+ activity during pH changes in vitro

We examined how changes in solution pH alter myocardial cell action potentials (AP) with and without changes in free [Ca2+] caused by pH induced effects on calcium binding. Guinea pig ventricular tissue was isolated, superfused either with Krebs-Ringer (K-R) bicarbonate, phosphate buffered solution, or with Hepes buffered solution, and electrically paced during control (5% CO2 in O2), acidic (12% CO2), and alkalotic (0% CO2) conditions. Action potentials were recorded with intracellular microelectrodes. Extracellular free [Ca2+] was measured with a calcium ion selective electrode and total soluble calcium was measured by ultrafiltration and spectrophotometry. With a total [CaCl2] of 2.5 mM in the K-R solution, we found a free [Ca2+] of 2.14 mM at pH 7.44 (control), 2.48 mM at pH 6.97 and 1.60 mM at pH 8.19; total soluble calcium concentration was 2.00 mM at pH 8.19. In the Hepes solution, free [Ca2+] was only slightly altered (2.42 to 2.55 mM) within this pH range. Equivalent acidosis of either K-R or Hepes suffusate significantly, and similarly, prolonged the AP and its refractory period. Alkalosis of the Hepes suffusate shortened the AP; but equivalent alkalosis of the K-R suffusate prolonged the AP as did a reduction of [CaCl2] in Hepes suffusate from 3.0 to 1.5 mM at pH 7.43. Our study demonstrates that a paradoxical increase in APD occurs because free Ca2+ ion activity falls in K-R solution and overrides the effect of alkalosis alone to decrease APD.(ABSTRACT TRUNCATED AT 250 WORDS)     

From behavior to membranes: testosterone-induced changes in action potential duration in electric organs.

The electric organ of mormyrid fishes consists of action potential-generating cells called electrocytes, which together produce a pulse-like electric organ discharge (EOD). The appearance of an EOD depends, in part, on the characteristic features of a single electrocyte's action potentials. In some species, gonadal steroid hormones induce increases in EOD duration, which mimic natural sex differences. We now show that testosterone-induced changes in EOD duration are associated with a 2- to 3-fold increase in the duration of action potentials generated by single electrocytes. Together with other anatomical and biochemical data, the results emphasize the exquisite interrelationship between steroid hormone action and the cellular machinery determining the electrical properties of single cells that underlie sexually dimorphic and seasonal behaviors.     

Changes in Ca(2+) cycling proteins underlie cardiac action potential prolongation in a pressure-overloaded guinea pig model with cardiac hypertrophy and failure

Ventricular arrhythmias are common in both cardiac hypertrophy and failure; cardiac failure in particular is associated with a significant increase in the risk of sudden cardiac death. We studied the electrophysiologic changes in a guinea pig model with aortic banding resulting in cardiac hypertrophy at 4 weeks and progressing to cardiac failure at 8 weeks using whole-cell patch-clamp and biochemical techniques. Action potential durations (APDs) were significantly prolonged in banded animals at 4 and 8 weeks compared with age-matched sham-operated animals. APDs at 50% and 90% repolarization (APD(50) and APD(90) in ms) were the following: 4 week, banded, 208+/-51 and 248+/-49 (n = 15); 4 week, sham, 189+/-68 and 213+/-69 (n = 16); 8 week, banded, 197+/-40 and 226+/-40 (n = 21); and 8 week, sham, 156+/-42 and 189+/-45 (n = 22), respectively; P<0.05 comparing banded versus sham-operated animals. We observed no significant differences in the K(+) currents between the 2 groups of animals at 4 and 8 weeks. However, banded animals exhibited a significant increase in Na(+) and Na(+)-Ca(2+) exchange current densities compared with controls. Furthermore, we have found a significant attenuation in the Ca(2+)-dependent inactivation of the L-type Ca(2+) current in the banded compared with sham-operated animals, likely as a result of the significant downregulation of the sarcoplasmic reticulum Ca(2+) ATPase, which has been documented previously in the heart failure animals. Our data provide an alternate mechanism for APD prolongation in cardiac hypertrophy and failure and support the notion that there is close interaction between Ca(2+) handling and action potential profile.     

Electrical pacing counteracts intrinsic shortening of action potential duration of neonatal rat ventricular cells in culture

Previous studies have demonstrated the relationship between the functional electrophysiological properties of cultured neonatal rat ventricular myocytes (NRVMs) and the ability of the substrate to induce and sustain arrhythmia. The goal of this study was to examine the effects of chronic pacing at a constant rate akin to that in vivo, on the functional electrophysiological properties of NRVM monolayers. Confluent NRVM monolayers grown on 20 mm diameter cover slips were left either unpaced or were stimulated at 3 Hz for the duration of the culture, and were optically mapped on days 4, 6, or 8. Action potential duration at 80% repolarization (APD80), conduction velocity (CV), and Kv4.3 (Ito) and NCX protein expression were measured. The effects of the excitation-contraction uncoupler 2,3-butadione monoxime (BDM) were also investigated. The 2 Hz APD80 of non-paced monolayers decreased significantly on days 6 (137.1+/-13.9 ms) and 8 (109.8+/-9.0 ms) compared with day 4 (197.0+/-11.8 ms), while that of paced monolayers did not (206.8+/-9.7, 209.1+/-9.2, and 210.6+/-9.9 ms, respectively). The 2 Hz CV of non-paced monolayers increased significantly on days 6 (26.0+/-1.6 cm/s) and 8 (26.5+/-1.0 cm/s) compared with day 4 (20.0+/-1.0 cm/s), while that of paced monolayers did not change significantly (26.0+/-2.0, 26.0+/-1.0, and 23.8+/-1.2 cm/s, respectively). The restitution curves of APD80 and CV of paced monolayers were also unchanging from days 4 through 8. Despite the unchanging APD80 and CV, a decrease in Kv4.3 expression and an increase in NCX expression were observed in paced compared with non-paced monolayers. Cessation of pacing or administration of BDM caused a reversal of phenotype back to that of non-paced monolayers. In summary, chronic electrical stimulation of confluent NRVM monolayers results in stabilization of APD80 and an advancement of the developmental rise of CV that is mediated by electromechanical coupling. These effects produce a steadier functional phenotype that may be beneficial for electrophysiological studies.     

Restitution of action potential duration during sequential changes in diastolic intervals shows multimodal behavior

Restitution of action potential duration (APD) is thought to be critical in activation instability. Although restitution is used to predict APD during sequential changes in diastolic interval (DI), currently used protocols to determine restitution do not use sequential changes in DI. We explored restitution using a new pacing protocol to change DI sequentially and independently of APD. Transmembrane potentials were recorded from right ventricular endocardial tissue isolated from six dogs. We used three patterns of DIs: oscillatory, to demonstrate differences in APDs depending on previous activation history; random, to minimize effects of previous activation history, each DI preceding an APD had an equal probability of being short or long; and linear, to compare restitution relationship obtained during sequential changes in DI with those obtained using currently used protocols; DIs mimicked those that resulted using currently used protocols, except that they changed in sequence. During oscillatory DIs, restitution showed bimodal trajectory similar to hysteresis. Decrease in APD during decreasing DIs was faster than increase in APD during increasing DIs. When effects of previous activation history were minimized, we observed that for a given DI there were multiple values of APD. Restitution relationship obtained during sequential changes in DI was shallower than those obtained using currently used protocols. Our results show that the new pacing protocol may permit direct evaluation of effects of memory on APD. Sequential and explicit control of DI suggests that use of a unimodal relationship to predict APD when DIs change in sequence may not be appropriate.     

Chronic inhibition of Na+/H+-exchanger attenuates cardiac hypertrophy and prevents cellular remodeling in heart failure

OBJECTIVE: In patients with heart disease, the transition from compensatory hypertrophy to heart failure (HF) is associated with altered calcium handling. Up-regulated Na(+)/H(+)-exchanger (NHE-1) activity underlies increased [Na(+)](i) and disturbance of cellular calcium handling in HF. We hypothesize that chronic inhibition of NHE-1 activity prevents the hypertrophic response, cellular remodeling, and development of HF. METHODS: Rabbits received a control or cariporide (inhibitor of NHE-1) diet for 3 months, starting after induction of combined volume and pressure overload. Age-matched animals served as control. Development of HF was examined echocardiographically and electrocardiographically after 3 months. [Na(+)](i), [Ca(2+)](i), pH(i), and action potentials were measured in left ventricular midmural myocytes with SBFI, indo-1, SNARF, and di-4-anepps. Sarcoplasmic reticulum calcium content was calculated from the response of [Ca(2+)](i) to rapid cooling. Calcium after-transients were elicited by cessation of rapid stimulation (3 Hz) in the presence of 100 nmol/l noradrenalin. RESULTS: Chronic treatment of rabbits with the specific Na(+)/H(+)-exchanger activity inhibitor cariporide greatly attenuated development of hypertrophy and entirely abolished development of HF; the heart/body weight ratio increased only little, no change in lung weight occurred, left ventricular dimensions and fractional shortening changed mildly, ascites was not present, QT duration did not increase, and sudden death did not occur. Chronic cariporide treatment also prevented cellular electrical and ionic remodeling. Myocyte dimensions were unaltered, action potentials were not prolonged, cytoplasmic sodium and NHE-1 activity did not increase, cytoplasmic and SR calcium handling remained undisturbed, and no increase of the incidence of calcium after-transient dependent delayed after depolarizations (DADs) occurred. CONCLUSION: We conclude that enhanced activity of NHE-1 underlies cardiac cellular electrical and ionic remodeling in experimental heart failure, and that chronic dietary treatment with cariporide attenuates hypertrophy, development of HF, and cellular remodeling.     

急性心肌梗死对心室肌细胞钾电流的影响

目的 :研究急性心肌梗死 （AMI）心室肌细胞瞬时外向钾电流 （Ito）和内向整流性钾电流 （IK1 ）的变化。方法 :采用结扎兔冠状动脉左前降支的方法建立 AMI动物模型 ,应用膜片钳全细胞记录方法 ,记录比较 AMI后 1周心外膜梗死区心肌细胞 Ito和 IK1 的变化。结果 :心梗组 Ito明显下降 ,I- V曲线明显下移。指令电位为 +60 m V时 ,Ito在心梗组为 1.0 8± 0 .2 4n A（n=12 ） ,与对照组 （2 .0 9± 0 .3 9n A ,n=16）相比 ,显著下降 ,P<0 .0 1;心梗组 IK1 与对照组比较 ,明显下降 ,特别在超极化时。指令电位为 - 12 0 m V时 ,心梗组 IK1 为 3 .0 1± 0 .49n A （n=11） ,对照组为 4.12±0 .5 1n A（n=10 ,P<0 .0 5 ）。结论 :AMI可引起心室肌细胞 Ito和 IK1 的下降 ,从而导致动作电位平台期延长、复极异常 ,这可能是导致 AMI后出现折返性室性心律失常的原因     

Numerical simulation of paced electrogram fractionation: relating clinical observations to changes in fibrosis and action potential duration

Simulating paced electrogram fractionation. INTRODUCTION: Paced electrogram fractionation analysis (PEFA) may identify a re-entrant substrate in patients at risk of ventricular fibrillation (VF) by detecting prolonged, fractionated ventricular electrograms ("fractionation") in response to premature extrastimuli. Numerical simulations of action potential (AP) propagation through human myocardium following such premature stimulation were performed to study the relationship between electrogram fractionation, fibrosis, and changes in AP currents. METHODS AND RESULTS: Activation in a resistive monodomain 2 cm2 sheet of myocardium containing nonconducting fibrous tissue was modeled using standard numerical methods for solutions of partial differential equations using the Priebe-Beukelmann (PB) AP equations. Myocardial fibrosis significantly influenced electrogram morphology. High densities of closely spaced fibrous septa caused functional block and altered propagation paths at short coupling intervals, and produced large increases in electrogram duration similar to those associated with increased risk of VF in clinical studies. Prolongation of the cardiac AP using the heart failure variant of the PB model further increased the amount of fractionation and thereby replicated clinical recordings more closely than did fibrosis alone. Increasing AP dispersion by a variable reduction in the potassium current I(Kr) simulated results seen in patients with the long QT syndrome with an abrupt increase in electrogram duration, while a uniform reduction in I(Kr) alone did not result in fractionated electrograms. In contrast, increases in cytosolic Ca2+ and Ca2+ buffering by troponin to simulate HCM had little effect on fractionation. CONCLUSIONS: These results relate the effects of fibrosis, AP abnormalities, and dispersion of AP duration to the characteristic electrograms recorded in patients at risk of sudden death.