Objective: Deleterious electrical abnormalities evolve during myocardial infarction. The goal of this study was to analyse current changes during the late decompensated phase of heart disease induced by coronary ligation and to compare them in various heart regions. Methods: Young rats were submitted to left coronary ligature. After 4–6 months, cells were enzymatically dissociated and isolated from the upper part basal region of the left ventricle, as well as from the septum, apex and the right ventricle before being studied under whole-cell patch-clamp. Results: Basal L-type Ca²⁺ current, I_CaL elicited at +10 mV did not exhibit regional dependence neither in control nor after post-myocardial infarction (PMI). I_CaL showed both a significantly reduced peak amplitude (17.1±2.8 pA/pF versus 9.9±1.4 pA/pF in seven control and seven PMI hearts, n=32 and 40, respectively) and a slower inactivation, such that the amount of inward charges during a 200 ms-depolarizing pulse was nearly unchanged. β-Adrenergic stimulation was less effective in increasing I_CaL in PMI cells but it slowed inactivation further. Significant differences in the K⁺ currents were observed. A regional distribution was seen for I_to only, with the largest amplitude in the right ventricle (in pA/pF: 23.1±2.4, 18.2±3.9, 14.8±2.4, 8.3±1.7 in the right ventricle, apex, septum and left ventricle, respectively n=8, 7, 8 and 9). This was also true in failing heart cells despite I_to being halved in each of the four regions (in pA/pF: 12.2±2.5, 11.2±1.9, 5.1±1.0 and 4.8±1.0, respectively n=12, 12, 11 and 13). I_K1 was also significantly reduced by 20% in the PMI cells. Two-way analyses of variance demonstrated the absence of interaction between the topographical origin of the cells and the physiological state of the rats. The α₁-adrenergic agonist, methoxamine significantly reduced I_to and I_K1 to the same extent in both sham and PMI cells, by about 35% and 20% respectively. Conclusions: Long-term left coronary occlusion induces significant alterations in both Ca²⁺ and K⁺ currents that occur with similar amplitude in both ventricles. They include a marked reduction in I_to amplitude as well as a slowing of I_CaL inactivation. Both factors could contribute to the disturbances in cellular electrical behaviour and the occurrence of arrhythmias in the post-myocardial infarcted heart.