#2696 IN SILICO ELECTROPHYSIOLOGICAL STUDY REVEALS TAMSULOSIN MEDIATE URETER SMOOTH MUSCLE CONTRACTION BY INCREASING POTASSIUM CURRENT

Abstract

Abstract Background and Aims Tamsulosin is a common α1-AR antagonist that is prescribed to patients with acute kidney stone episodes [Scotland et al., 2021]. According to accumulated experimental data, abnormal peristaltic contraction of the ureter smooth muscle (USM) causes acute kidney stone episodes [Lang et al., 2006]. Intracellular electrical activities like membrane depolarization and action potentials play important roles in modulating the USM contraction by releasing intracellular calcium from the sarcoplasmic reticulum. Therefore, an electrophysiological study will be helpful to assess the USM cell's electrical activities and in diagnosing abnormal USM contraction. Transient potassium channels (KA) are prevalent in different systems and hold immense importance for maintaining/performing selective electrophysiological functions. The present study investigates the altered electrophysiological characteristics of the USM cell because of the induction of Tamsulosin doses. Method The single isolated USM cell comprises several voltage-gated ion channels, such as two voltage-gated calcium (T-type, and L-type) channels, one voltage-gated fast potassium (KA) channel, one calcium-dependent large conductance potassium channel, and an HCN channel. The individual ion channel currents and the membrane potential are recorded by utilizing both the voltage clamp and current clamp protocols. A Tamsulosin drug (0.5 mg) model for the KA channel is introduced by multiplying the maximal conductance of the KA channel with a scaling factor between 0 and 1 to mimic the drug concentration. Statistical analysis protocols are evaluated for analytical purposes. Results In this in silico electrophysiological model, the resting membrane potential is maintained at −75 mV, as this value is cited by various experimental studies. The ionic concentrations and biophysical parameters for all ion channels are varied in the physiological ranges. Under the voltage clamp protocol, the voltage steps are increased from a holding potential of −80 mV to −10 mV with a 10 mV of step voltage. In Figure 1, the red and blue solid lines represent recorded outward KA current from the isolated USM cell under both control and applied Tamsulosin dose conditions. Figure 1 reveals that the KA current is elevated after the application of the Tamsulosin drug regarding all step voltages. As a result, the total outward current is elevated and the USM action potential duration is shortened. It is also observed that the steady-state activation curve of the KA channel is shifted to more negative after applying Tamsulosin. The USM cell is electrically less excitable with the Tamsulosin. Conclusion This first in-silico study reveals the KA ionic current, which plays a major role in coordinating ureteral contractions, is altered due to Tamsulosin. It implies that the pharmacological maneuver of Tamsulosin is substantially beneficial to treat dysfunctional peristalsis by reducing the symptoms and installation complexities from the ureteral stents procedure.