A Comparative Study of the Rapid (I Kr ) and Slow (I Ks ) Delayed Rectifier Potassium Currents in Undiseased Human, Dog, Rabbit, and Guinea Pig Cardiac Ventricular Preparations.
Márta ÁgostonZsófia KohajdaLászló VirágBeáta BalátiNorbert NagyCsaba LengyelMiklós BitayGábor BogátsAndrás VereckeiJulius Gy PappAndrás VarróNorbert JostPublished in: Pharmaceuticals (Basel, Switzerland) (2024)
To understand the large inter-species variations in drug effects on repolarization, the properties of the rapid (I Kr ) and the slow (I Ks ) components of the delayed rectifier potassium currents were compared in myocytes isolated from undiseased human donor (HM), dog (DM), rabbit (RM) and guinea pig (GM) ventricles by applying the patch clamp and conventional microelectrode techniques at 37 °C. The amplitude of the E-4031-sensitive I Kr tail current measured at -40 mV after a 1 s long test pulse of 20 mV, which was very similar in HM and DM but significant larger in RM and GM. The L-735,821-sensitive I Ks tail current was considerably larger in GM than in RM. In HM, the I Ks tail was even smaller than in DM. At 30 mV, the I Kr component was activated extremely rapidly and monoexponentially in each studied species. The deactivation of the I Kr component in HM, DM, and RM measured at -40 mV. After a 30 mV pulse, it was slow and biexponential, while in GM, the I Kr tail current was best fitted triexponentially. At 30 mV, the I Ks component activated slowly and had an apparent monoxponential time course in HM, DM, and RM. In contrast, in GM, the activation was clearly biexponential. In HM, DM, and RM, I Ks component deactivation measured at -40 mV was fast and monoexponential, while in GM, in addition to the fast component, another slower component was also revealed. These results suggest that the I K in HM resembles that measured in DM and RM and considerably differs from that observed in GM. These findings suggest that the dog and rabbit are more appropriate species than the guinea pig for preclinical evaluation of new potential drugs expected to affect cardiac repolarization.
Keyphrases
- endothelial cells
- glycemic control
- diffusion weighted imaging
- left ventricular
- blood pressure
- heart failure
- induced pluripotent stem cells
- stem cells
- type diabetes
- emergency department
- metabolic syndrome
- computed tomography
- single cell
- bone marrow
- mesenchymal stem cells
- human health
- skeletal muscle
- genetic diversity
- atrial fibrillation
- cell therapy
- drug induced
- adverse drug
- resting state