Abstract
Mechanical stretch has been shown to provoke arrhythmia. We wanted to analyze ventricular arrhythmia induced by local left ventricular stretch in order to find out, where arrhythmias originate and whether they can be prevented pharmacologically. Isolated rabbit hearts (Langendorff technique) were submitted to increased left ventricular stretch at the left wall by insertion of an additional intraventricular balloon and adjusting the end-diastolic pressure (EDP) to 25 mmHg for 10 min followed by 20 min recovery at normal EDP of 5–8 mmHg. Activation and repolarization processes were investigated by ventricular 256 electrode epicardial mapping. The hearts were treated during the whole procedure either with vehicle, 0.5 μM flecainide (sodium channel blocker) or 100 μM streptomycin (here used as stretch-activated ion-channel blocker). In addition, we performed a series of experiments, in which we enhanced EDP to 30 mmHg (global stretch instead of local stretch) by inflating the left ventricular pressure balloon (strain, 0.148 ± 0.034). Each series was performed with n = 6. Stretch resulted in local strain of 25 % at the left wall together with a local slowing of the activation process at the left wall, in a change in the activation pattern, and in ventricular arrhythmia. Coronary flow was not affected. Ventricular arrhythmias originated from the border between the stretched area and the non-stretched region. Flecainide and streptomycin reduced the prolongation of the activation process at the stretched left wall and mitigated the difference in total activation time between left and front wall but only partially prevented arrhythmia. In the additional global stretch experiments relative coronary flow and the other parameters remained unchanged, in particular TAT. Thus, in contrast to the local stretch series, there was no difference in the change in TAT between left and front wall. Only rare single ventricular extrasystoles (<1/min; originating from LV (front and left wall) i.e. from within the stretched region) were seen during stretch (but not at the beginning) and during recovery. Local left ventricular stretch can elicit ventricular arrhythmias. Local slowing of electrical activation seems involved so that the difference in total activation time of the stretched free left wall and the non-stretched increased.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Arisi G, Macchi E, Baruffi S, Spaggiari S, Taccardi B (1983) Potential field on the ventricular surface of the exposed dog heart during normal excitation. Circ Res 52:706–715
Belus A, White E (2002) Effects of streptomycin sulphate on I(CaL), I(Kr) and I(Ks) in guinea-pig ventricular myocytes. Eur J Pharmacol 445:171–178
Belus A, White E (2003) Streptomycin and intracellular calcium modulate the response of single guinea-pig ventricular myocytes to axial stretch. J Physiol 546:501–509
Beyder A, Rae JL, Bernard C, Strege PR, Sachs F, Farrugia G (2010) Mechano-sensitivity of Nav1.5, a voltage-sensitive sodium channel. J Physiol 588(Pt 24):4969–4985
Beyder A, Strege PR, Reyes S, Bernard CE, Terzic A, Makielski J, Ackerman MJ, Farrugia G (2012a) Ranolazine decreases mechanosensitivity of the voltage-gated sodium ion channel Na(v)1.5: a novel mechanism of drug action. Circulation 125:2698–2706
Beyder A, Strege PR, Bernard C, Farrugia G (2012b) Membrane permeable local anesthetics modulate Na(V)1.5 mechanosensitivity. Channels (Austin) 6:308–316
Buchanan JW, Saito T, Gettes LS (1985) The effects of antiarrhythmic drugs, stimulation frequency and potassium induced resting membrane potential changes on conduction velocity and dV/dt max in guinea pig myocardium. Circ Res 56:696–703
Calaghan SC, White E (1999) The role of calcium in the response of cardiac muscle to stretch. Prog Biophys Mol Biol 71:59–90
Coronel R, Fiolet JWT, Wilms-Schopman FJG, Schaapherder AFM, Johnson TA, Gettes LS, Janse MJ (1988) Distribution of extracellular potassium and its relation to electrophysiologic changes during acute myocardial ischemia in the isolated perfused porcine heart. Circulation 77:1125–1138
Coronel R, Wilms-Schopman FJG, Opthof T, Cinca J, Fiolet JWT, Janse MJ (1992) Reperfusion arrhythmias in isolated perfused pig hearts. Inhomogeneities in extracellular potassium, ST and TQ potentials and transmembrane action potentials. Circ Res 71:1131–1142
Dhein S, Müller A, Gerwin R, Klaus W (1993) Comparative study on the proarrhythmic effects of some class I antiarrhythmic agents. Circulation 87:617–631
Durrer D, Van der Tweel LH (1954) Spread of activation in the left ventricular wall of the dog. Activation conditions at the epicardial surface. Am Heart J 47:192–203
Eckardt L, Kirchhof P, Mönnig G, Breithardt G, Borggrefe M, Haverkamp W (2000) Modification of stretch-induced shortening of repolarization by streptomycin in the isolated rabbit heart. J Cardiovasc Pharmacol 36:711–721
Franz MR (1996) Mechano-electrical feedback in ventricular myocardium. Cardiovasc Res 32:15–24
Healy SN, McCulloch AD (2005) An ionic model of stretch-activated and stretch-modulated currents in rabbit ventricular myocytes. Europace 7(Suppl 2):128–134
Horowitz A (1991) Structural considerations in formulating material laws for the myocardium. In: Glass L, Hunter P, McCulloch A (eds) Theory of heart. Springer, New York, pp 31–58
Iribe G, Ward CW, Camelliti P, Bollensdorff C, Mason F, Burton RA, Garny A, Morphew MK, Hoenger A, Lederer WJ, Kohl P (2009) Axial stretch of rat single ventricular cardiomyocytes causes an acute and transient increase in Ca2+ spark rate. Circ Res 104:787–795
Jozwiak J, Dhein S (2008) Local effects and mechanisms of antiarrhythmic peptide AAP10 in acute regional myocardial ischemia: electrophysiological and molecular findings. Naunyn Schmiedebergs Arch Pharmacol 378:459–470
Jozwiak J, Dietze A, Grover R, Savtschenko A, Etz C, Mohr FW, Dhein S (2012) Desipramine prevents cardiac gap junction uncoupling. Naunyn Schmiedebergs Arch Pharmacol 385:1063–1075
Kamkin A, Kiseleva I, Isenberg G (2000) Stretch-activated currents in ventricular myocytes: amplitude and arrhythmogenic effects increase with hypertrophy. Cardiovasc Res 48:409–420
Kockskämper J, von Lewinski D, Khafaga M, Elgner A, Grimm M, Eschenhagen T, Gottlieb PA, Sachs F, Pieske B (2008) The slow force response to stretch in atrial and ventricular myocardium from human heart: functional relevance and subcellular mechanisms. Prog Biophys Mol Biol 97:250–267
Kootsey JM (1991) Electrical propagation in distributed cardiac tissue. In: Glass L, Hunter P, McCulloch AD (eds) Theory of heart: biomechanics. Biophysics and non-linear dynamics of cardiac function. Springer, New York, pp 391–403
Lacampagne A, Gannier F, Argibay J, Garnier D, Le Guennec J-Y (1994) The stretch-activated ion channel blocker gadolinium also blocks L-type calcium channels in isolated ventricular myocytes of the guinea pig. Biochim Biophys Acta 1191:205–208
Millar CK, Kralios FA, Lux RL (1985) Correlation between refractory periods and activation recovery intervals from electrograms: effects of rate and adrenergic interventions. Circulation 72:1372–1379
Mills RW, Narayan SM, McCulloch AD (2005) The effects of wall stretch on ventricular conduction and refractoriness in the whole heart. In: Kohl P, Sachs F, Franz MR (eds) Cardiac mechano-electric feedback & arrhythmias. Elsevier, Philadelphia, pp 127–136
Mills RW, Narayan SM, McCulloch AD (2008) Mechanisms of conduction slowing during myocardial stretch by ventricular volume loading in the rabbit. Am J Physiol 295:H1270–H1278
Miura M, Nishio T, Hattori T, Murai N, Stuyvers BD, Shindoh C, Boyden PA (2010) Effect of nonuniform muscle contraction on sustainability and frequency of triggered arrhythmias in rat cardiac muscle. Circulation 121:2711–2717
Morris CE, Juranka PF (2007) Nav channel mechanosensitivity: activation and inactivation accelerate reversibility with stretch. Biophys J 93:822–833
Müller A, Dhein S, Klaus W (1991) Heterogeneously distributed sensitivities to potassium as a cause of hypokalemic arrhythmias in isolated rabbit hearts. J Cardiovasc Electrophysiol 2:145–155
Quinn TA, Kohl P (2013) Combining wet and dry research: experience with model development for cardiac mechano-electric structure-function studies. Cardiovasc Res 97:601–611
Reiter MJ, Landers M, Zetelaki Z, Kirchhof CJH, Allessie MA (1997) Electrophysiological effects of acute dilatation in the isolated rabbit heart. Cycle length-dependent effects on ventricular refractoriness and conduction velocity. Circulation 96:4050–4056
Salameh A, Dhein S (2013) Effects of mechanical forces and stretch on intercellular gap junction coupling. Biochim Biophys Acta 1828:147–156
Strege PR, Ou Y, Sha L, Rich A, Gibbons SJ, Szurszewski JH, Sarr MG, Farrugia G (2003) Sodium current in human intestinal interstitial cells of Cajal. Am J Physiol Gastrointest Liver Physiol 285:G1111–G1121
White E, Le Guennec J-Y, Nigretto JM, Gannier F, Argibay JA, Garnier D (1993) The effects of increasing cell length on auxotonic contractions. Membrane potential and intracellular calcium transients in single guinea-pig ventricular myocytes. Exp Physiol 78:65–78
Winegar BD, Haws CM, Lansman JB (1996) Subconductance block of single mechano-sensitive ion channels in skeletal fibres by aminoglycoside antibiotics. J Gen Physiol 107:433–443
Zabel M, Koller BS, Sachs F, Franz MR (1996) Stretch-induced voltage changes in the isolated beating heart: importance of timing stretch and implications for stretch-activated ion channels. Cardiovasc Res 32:120–130
Zeng T, Bett GCL, Sachs F (2000) Stretch-activated whole cell currents in adult rat cardiac myocytes. Am J Physiol 278:H548–H557
Conflict of interest
No conflict of interest to be declared.
Funding
Parts of this study were funded by DFG and by ProCordis Leipzig (grants to S.D.)
Author information
Authors and Affiliations
Corresponding author
Additional information
Stefan Dhein and Christine Englert contributed equally to this study.
Rights and permissions
About this article
Cite this article
Dhein, S., Englert, C., Riethdorf, S. et al. Arrhythmogenic effects by local left ventricular stretch: effects of flecainide and streptomycin. Naunyn-Schmiedeberg's Arch Pharmacol 387, 763–775 (2014). https://doi.org/10.1007/s00210-014-0988-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00210-014-0988-y