In Silico Human Cardiomyocyte Action Potential Modeling: Exploring Ion Channel Input Combinations.

In silico modeling offers an opportunity to supplement and accelerate cardiac safety testing. With in silico modeling, computational simulation methods are used to predict electrophysiological interactions and pharmacological effects of novel drugs on critical physiological processes. The O'Hara-Rudy's model was developed to predict the response to different ion channel inhibition levels on cardiac action potential duration (APD) which is known to directly correlate with the QT interval. APD data at 30% 60% and 90% inhibition were derived from the model to delineate possible ventricular arrhythmia scenarios and the marginal contribution of each ion channel to the model. Action potential values were calculated for epicardial, myocardial, and endocardial cells, with action potential curve modeling. This study assessed cardiac ion channel inhibition data combinations to consider when undertaking in silico modeling of proarrhythmic effects as stipulated in the Comprehensive in Vitro Proarrhythmia Assay (CiPA). As expected, our data highlight the importance of the delayed rectifier potassium channel (IKr) as the most impactful channel for APD prolongation. The impact of the transient outward potassium channel (Ito) inhibition on APD was minimal while the inward rectifier (IK1) and slow component of the delayed rectifier potassium channel (IKs) also had limited APD effects. In contrast, the contribution of fast sodium channel (INa) and/or L-type calcium channel (ICa) inhibition resulted in substantial APD alterations supporting the pharmacological relevance of in silico modeling using input from a limited number of cardiac ion channels including IKr, INa, and ICa, at least at an early stage of drug development.

Acute effect of passive heat exposure on markers of cardiometabolic function in adults with type 2 diabetes mellitus.

Heat therapy is a promising strategy to improve cardiometabolic health. This study evaluated the acute physiological responses to hot water immersion in adults with type 2 diabetes mellitus (T2DM). On separate days in randomized order, 13 adults with T2DM [8 males/5 females, 62 ± 12 yr, body mass index (BMI): 30.1 ± 4.6 kg/m2] were immersed in thermoneutral (34°C, 90 min) or hot (41°C, core temperature ≥38.5°C for 60 min) water. Insulin sensitivity was quantified via the minimal oral model during an oral glucose tolerance test (OGTT) performed 60 min after immersion. Brachial artery flow-mediated dilation (FMD) and reactive hyperemia were evaluated before and 40 min after immersion. Blood samples were drawn to quantify protein concentrations and mRNA levels of HSP70 and HSP90, and circulating concentrations of cytokines. Relative to thermoneutral water immersion, hot water immersion increased core temperature (+1.66°C [+1.47, +1.87], P < 0.01), heart rate (+34 beats/min [+24, +44], P < 0.01), antegrade shear rate (+96 s-1 [+57, +134], P < 0.01), and IL-6 (+1.38 pg/mL [+0.31, +2.45], P = 0.01). Hot water immersion did not exert an acute change in insulin sensitivity (-0.3 dL/kg/min/µU/mL [-0.9, +0.2], P = 0.18), FMD (-1.0% [-3.6, +1.6], P = 0.56), peak (+0.36 mL/min/mmHg [-0.71, +1.43], P = 0.64), and total (+0.11 mL/min/mmHg × min [-0.46, +0.68], P = 0.87) reactive hyperemia. There was also no change in eHSP70 (P = 0.64), iHSP70 (P = 0.06), eHSP90 (P = 0.80), iHSP90 (P = 0.51), IL1-RA (P = 0.11), GLP-1 (P = 0.59), and NF-κB (P = 0.56) after hot water immersion. The physiological responses elicited by hot water immersion do not acutely improve markers of cardiometabolic function in adults with T2DM.NEW & NOTEWORTHY Heat therapy has been shown to improve markers of cardiometabolic health in preclinical and clinical studies. However, the effects of heat therapy in individuals with type 2 diabetes mellitus (T2DM) remain understudied. We examined the acute effect of hot water immersion on glucose tolerance, flow-mediated dilation, reactive hyperemia, inflammatory markers, and heat shock proteins in adults with T2DM. Hot water immersion did not acutely improve the markers studied.

Simulated P wave morphology in the presence of endo-epicardial activation delay.

AIMS: Evidences of asynchrony between epicardial and endocardial activation in the atrial wall have been reported. We used a computer model of the atria and torso to investigate the consequences of such activation delay on P wave morphology, while controlling for P wave duration. METHODS AND RESULTS: We created 390 models of the atria based on the same geometry. These models differed by atrial wall thickness (from 2 to 3 mm), transmural coupling, and tissue conductivity in the endocardial and epicardial layers. Among them, 18 were in baseline, 186 had slower conduction in the epicardium layer and 186 in the endocardial layer. Conduction properties were adjusted in such a way that total activation time was the same in all models. P waves on a 16-lead system were simulated during sinus rhythm. Activation maps were similar in all cases. Endo-epicardial delay varied between -5.5 and 5.5 ms vs. 0 ± 0.5 ms in baseline. All P waves had the same duration but variability in their morphology was observed. With slower epicardial conduction, P wave amplitude was reduced by an average of 20% on leads V3-V5 and P wave area decreased by 50% on leads V1-V2 and by 40% on lead V3. Reversed, lower magnitude effects were observed with slower endocardial conduction. CONCLUSION: An endo-epicardial delay of a few milliseconds is sufficient to significantly alter P wave morphology, even if the activation map remains the same.