Atrial fibrillation (AF) is associated with increased morbidity and is in addition the most prevalent cardiac arrhythmia. Compounds used in pharmacological treatment has traditionally been divided into Na+ channel inhibitors, [beta]-blockers, K+ channel inhibitors, and Ca2+ channel inhibitors, whereas newer multichannel blockers such as amiodarone and ranolazine have been introduced later. This study was devoted to the evaluation of an acute pacing-induced in vivo model of AF in rats. Antiarrhythmic effects of well-known compounds such as lidocaine, dofetilide, and ranolazine were confirmed in this model. In addition, antiarrhythmic effects of different inhibitors of Ca2+-activated small conductance K+ (SK) channels were demonstrated. Intravenous application of 5 mg/kg of the negative SK channel modulator NS8593 reduced AF duration by 64.5%, and the lowest significantly effective dose was 1.5 mg/kg. A dose-effect relationship was established based on 6 different dose groups. Furthermore, it was demonstrated that the antiarrhythmic effect of NS8593 and other tested drugs was associated with an increase in atrial effective refractory period. The functional role of SK channels was confirmed by 2 other SK channel inhibitors, UCL1684 and apamin, thereby confirming the hypothesis that these channels might constitute a new promising target for antiarrhythmic treatment.