Background and Objectives: Several real-world studies have been done in patients with nonvalvular atrial fibrillation (NVAF); however, information on its safety profile in patients with renal impairment is limited. XARENAL, a real-world study, aimed to prospectively investigate the safety profile of rivaroxaban in patients with NVAF with renal impairment (creatinine clearance [CrCl], 15–49 mL/min). Methods: XARENAL is an observational single-arm cohort study in renal impairment NVAF patients. Patients were followed up approximately every 3 months for 1 year or until 30 days following early discontinuation. The primary endpoint was major bleeding events. All adverse events, symptomatic thromboembolic events, treatment duration, and renal function change from baseline were the secondary endpoints. Results: XARENAL included 888 patients from 29 study sites. Overall, 713 (80.3%) had moderate renal impairment (CrCl, 30–49 mL/min), and 175 (19.7%) had severe renal impairment (CrCl, 15–29 mL/min) with a mean estimated glomerular filtration rate (eGFR) of 45.2±13.0 mL/min/1.73 m 2 . The mean risk scores were 3.3±1.4 and 1.7±0.9 for CHA 2 DS 2 -VASc score and HAS-BLED score, respectively. An incidence proportion of 5.6% (6.2 events per 100 patient-years) developed major bleeding; however, fatal bleeding occurred in 0.5% (0.5 events per 100 patient-years). The mean change in the eGFR was 2.22±26.47 mL/min/1.73 m 2 per year. Conclusions XARENAL observed no meaningful differences in major bleeding events from other previous findings as well as renal function changes in rivaroxaban-treated NVAF patients with renal impairment, which is considered to be acceptable in clinical practice.

Background and Objectives: Several real-world studies have been done in patients with nonvalvular atrial fibrillation (NVAF); however, information on its safety profile in patients with renal impairment is limited. XARENAL, a real-world study, aimed to prospectively investigate the safety profile of rivaroxaban in patients with NVAF with renal impairment (creatinine clearance [CrCl], 15–49 mL/min). Methods: XARENAL is an observational single-arm cohort study in renal impairment NVAF patients. Patients were followed up approximately every 3 months for 1 year or until 30 days following early discontinuation. The primary endpoint was major bleeding events. All adverse events, symptomatic thromboembolic events, treatment duration, and renal function change from baseline were the secondary endpoints. Results: XARENAL included 888 patients from 29 study sites. Overall, 713 (80.3%) had moderate renal impairment (CrCl, 30–49 mL/min), and 175 (19.7%) had severe renal impairment (CrCl, 15–29 mL/min) with a mean estimated glomerular filtration rate (eGFR) of 45.2±13.0 mL/min/1.73 m 2 . The mean risk scores were 3.3±1.4 and 1.7±0.9 for CHA 2 DS 2 -VASc score and HAS-BLED score, respectively. An incidence proportion of 5.6% (6.2 events per 100 patient-years) developed major bleeding; however, fatal bleeding occurred in 0.5% (0.5 events per 100 patient-years). The mean change in the eGFR was 2.22±26.47 mL/min/1.73 m 2 per year. Conclusions XARENAL observed no meaningful differences in major bleeding events from other previous findings as well as renal function changes in rivaroxaban-treated NVAF patients with renal impairment, which is considered to be acceptable in clinical practice.

Background: The ionic mechanism underlying Brugada syndrome (BrS) arises from an imbalance in transient outward current flow between the epicardium and endocardium.Previous studies report that artemisinin, originally derived from a Chinese herb for antimalarial use, inhibits the Ito current in canines. In a prior study, we showed the antiarrhythmic effects of artemisinin in BrS wedge preparation models. However, quinidine remains a well-established antiarrhythmic agent for treating BrS. Therefore, this study aims to investigate the efficacy of combining artemisinin with low-dose quinidine in suppressing ventricular tachyarrhythmia (VTA) in experimental canine BrS models. Methods: Transmural pseudo-electrocardiogram and epicardial/endocardial action potential (AP) were recorded from coronary-perfused canine right ventricular wedge preparation. To mimic the BrS model, acetylcholine (3 μM), calcium channel blocker verapamil (1 μM), and Ito agonist NS5806 (6–10 μM) were administered until VTA was induced. Subsequently, lowdose quinidine (1–2 μM) combined with artemisinin (100 μM) was perfused to mitigate VTA.Key parameters, including AP duration, J wave area, notch index, and T wave dispersion, were measured. Results: After administering the provocation agents, all sample models exhibited prominent J waves and VTA. Artemisinin alone (100–150 μM) suppressed VTA and restored the AP dome in all three preparations. Its infusion resulted in reductions in the J wave area and epicardial notch index. Consequently, low-dose quinidine (1–2 μM) did not fully restore the AP dome in all six sample models. However, when combined with additional artemisinin (100 μM), lowdose quinidine effectively suppressed VTA in all six models and restored the AP dome while also decreasing the J wave area and epicardial notch index. Conclusion Low-dose quinidine alone fails to fully alleviate VTA in the BrS wedge model.However, its combination with artemisinin effectively suppresses VTA. Artemisinin may reduce the therapeutic dose of quinidine, potentially minimizing its associated adverse effects.

Background: The ionic mechanism underlying Brugada syndrome (BrS) arises from an imbalance in transient outward current flow between the epicardium and endocardium.Previous studies report that artemisinin, originally derived from a Chinese herb for antimalarial use, inhibits the Ito current in canines. In a prior study, we showed the antiarrhythmic effects of artemisinin in BrS wedge preparation models. However, quinidine remains a well-established antiarrhythmic agent for treating BrS. Therefore, this study aims to investigate the efficacy of combining artemisinin with low-dose quinidine in suppressing ventricular tachyarrhythmia (VTA) in experimental canine BrS models. Methods: Transmural pseudo-electrocardiogram and epicardial/endocardial action potential (AP) were recorded from coronary-perfused canine right ventricular wedge preparation. To mimic the BrS model, acetylcholine (3 μM), calcium channel blocker verapamil (1 μM), and Ito agonist NS5806 (6–10 μM) were administered until VTA was induced. Subsequently, lowdose quinidine (1–2 μM) combined with artemisinin (100 μM) was perfused to mitigate VTA.Key parameters, including AP duration, J wave area, notch index, and T wave dispersion, were measured. Results: After administering the provocation agents, all sample models exhibited prominent J waves and VTA. Artemisinin alone (100–150 μM) suppressed VTA and restored the AP dome in all three preparations. Its infusion resulted in reductions in the J wave area and epicardial notch index. Consequently, low-dose quinidine (1–2 μM) did not fully restore the AP dome in all six sample models. However, when combined with additional artemisinin (100 μM), lowdose quinidine effectively suppressed VTA in all six models and restored the AP dome while also decreasing the J wave area and epicardial notch index. Conclusion Low-dose quinidine alone fails to fully alleviate VTA in the BrS wedge model.However, its combination with artemisinin effectively suppresses VTA. Artemisinin may reduce the therapeutic dose of quinidine, potentially minimizing its associated adverse effects.

Background: The ionic mechanism underlying Brugada syndrome (BrS) arises from an imbalance in transient outward current flow between the epicardium and endocardium.Previous studies report that artemisinin, originally derived from a Chinese herb for antimalarial use, inhibits the Ito current in canines. In a prior study, we showed the antiarrhythmic effects of artemisinin in BrS wedge preparation models. However, quinidine remains a well-established antiarrhythmic agent for treating BrS. Therefore, this study aims to investigate the efficacy of combining artemisinin with low-dose quinidine in suppressing ventricular tachyarrhythmia (VTA) in experimental canine BrS models. Methods: Transmural pseudo-electrocardiogram and epicardial/endocardial action potential (AP) were recorded from coronary-perfused canine right ventricular wedge preparation. To mimic the BrS model, acetylcholine (3 μM), calcium channel blocker verapamil (1 μM), and Ito agonist NS5806 (6–10 μM) were administered until VTA was induced. Subsequently, lowdose quinidine (1–2 μM) combined with artemisinin (100 μM) was perfused to mitigate VTA.Key parameters, including AP duration, J wave area, notch index, and T wave dispersion, were measured. Results: After administering the provocation agents, all sample models exhibited prominent J waves and VTA. Artemisinin alone (100–150 μM) suppressed VTA and restored the AP dome in all three preparations. Its infusion resulted in reductions in the J wave area and epicardial notch index. Consequently, low-dose quinidine (1–2 μM) did not fully restore the AP dome in all six sample models. However, when combined with additional artemisinin (100 μM), lowdose quinidine effectively suppressed VTA in all six models and restored the AP dome while also decreasing the J wave area and epicardial notch index. Conclusion Low-dose quinidine alone fails to fully alleviate VTA in the BrS wedge model.However, its combination with artemisinin effectively suppresses VTA. Artemisinin may reduce the therapeutic dose of quinidine, potentially minimizing its associated adverse effects.

Background and Objectives: Several real-world studies have been done in patients with nonvalvular atrial fibrillation (NVAF); however, information on its safety profile in patients with renal impairment is limited. XARENAL, a real-world study, aimed to prospectively investigate the safety profile of rivaroxaban in patients with NVAF with renal impairment (creatinine clearance [CrCl], 15–49 mL/min). Methods: XARENAL is an observational single-arm cohort study in renal impairment NVAF patients. Patients were followed up approximately every 3 months for 1 year or until 30 days following early discontinuation. The primary endpoint was major bleeding events. All adverse events, symptomatic thromboembolic events, treatment duration, and renal function change from baseline were the secondary endpoints. Results: XARENAL included 888 patients from 29 study sites. Overall, 713 (80.3%) had moderate renal impairment (CrCl, 30–49 mL/min), and 175 (19.7%) had severe renal impairment (CrCl, 15–29 mL/min) with a mean estimated glomerular filtration rate (eGFR) of 45.2±13.0 mL/min/1.73 m 2 . The mean risk scores were 3.3±1.4 and 1.7±0.9 for CHA 2 DS 2 -VASc score and HAS-BLED score, respectively. An incidence proportion of 5.6% (6.2 events per 100 patient-years) developed major bleeding; however, fatal bleeding occurred in 0.5% (0.5 events per 100 patient-years). The mean change in the eGFR was 2.22±26.47 mL/min/1.73 m 2 per year. Conclusions XARENAL observed no meaningful differences in major bleeding events from other previous findings as well as renal function changes in rivaroxaban-treated NVAF patients with renal impairment, which is considered to be acceptable in clinical practice.

Background: The ionic mechanism underlying Brugada syndrome (BrS) arises from an imbalance in transient outward current flow between the epicardium and endocardium.Previous studies report that artemisinin, originally derived from a Chinese herb for antimalarial use, inhibits the Ito current in canines. In a prior study, we showed the antiarrhythmic effects of artemisinin in BrS wedge preparation models. However, quinidine remains a well-established antiarrhythmic agent for treating BrS. Therefore, this study aims to investigate the efficacy of combining artemisinin with low-dose quinidine in suppressing ventricular tachyarrhythmia (VTA) in experimental canine BrS models. Methods: Transmural pseudo-electrocardiogram and epicardial/endocardial action potential (AP) were recorded from coronary-perfused canine right ventricular wedge preparation. To mimic the BrS model, acetylcholine (3 μM), calcium channel blocker verapamil (1 μM), and Ito agonist NS5806 (6–10 μM) were administered until VTA was induced. Subsequently, lowdose quinidine (1–2 μM) combined with artemisinin (100 μM) was perfused to mitigate VTA.Key parameters, including AP duration, J wave area, notch index, and T wave dispersion, were measured. Results: After administering the provocation agents, all sample models exhibited prominent J waves and VTA. Artemisinin alone (100–150 μM) suppressed VTA and restored the AP dome in all three preparations. Its infusion resulted in reductions in the J wave area and epicardial notch index. Consequently, low-dose quinidine (1–2 μM) did not fully restore the AP dome in all six sample models. However, when combined with additional artemisinin (100 μM), lowdose quinidine effectively suppressed VTA in all six models and restored the AP dome while also decreasing the J wave area and epicardial notch index. Conclusion Low-dose quinidine alone fails to fully alleviate VTA in the BrS wedge model.However, its combination with artemisinin effectively suppresses VTA. Artemisinin may reduce the therapeutic dose of quinidine, potentially minimizing its associated adverse effects.

Background and Objectives: Several real-world studies have been done in patients with nonvalvular atrial fibrillation (NVAF); however, information on its safety profile in patients with renal impairment is limited. XARENAL, a real-world study, aimed to prospectively investigate the safety profile of rivaroxaban in patients with NVAF with renal impairment (creatinine clearance [CrCl], 15–49 mL/min). Methods: XARENAL is an observational single-arm cohort study in renal impairment NVAF patients. Patients were followed up approximately every 3 months for 1 year or until 30 days following early discontinuation. The primary endpoint was major bleeding events. All adverse events, symptomatic thromboembolic events, treatment duration, and renal function change from baseline were the secondary endpoints. Results: XARENAL included 888 patients from 29 study sites. Overall, 713 (80.3%) had moderate renal impairment (CrCl, 30–49 mL/min), and 175 (19.7%) had severe renal impairment (CrCl, 15–29 mL/min) with a mean estimated glomerular filtration rate (eGFR) of 45.2±13.0 mL/min/1.73 m 2 . The mean risk scores were 3.3±1.4 and 1.7±0.9 for CHA 2 DS 2 -VASc score and HAS-BLED score, respectively. An incidence proportion of 5.6% (6.2 events per 100 patient-years) developed major bleeding; however, fatal bleeding occurred in 0.5% (0.5 events per 100 patient-years). The mean change in the eGFR was 2.22±26.47 mL/min/1.73 m 2 per year. Conclusions XARENAL observed no meaningful differences in major bleeding events from other previous findings as well as renal function changes in rivaroxaban-treated NVAF patients with renal impairment, which is considered to be acceptable in clinical practice.

PURPOSE: This study aims to assess and predict lifespan of dental prostheses using newly developed Korean Association of Prosthodontics (KAP) criteria through a large-scale, multi-institutional survey. MATERIALS AND METHODS: Survey was conducted including 16 institutions. Cox proportional hazards model and principal component analysis (PCA) were used to find out relevant factors and predict life expectancy. RESULTS: 1,703 fixed and 815 removable prostheses data were collected and evaluated. Statistically significant factors in fixed prosthesis failure were plaque index and material type, with a median survival of 10 to 18 years and 14 to 20 years each. In removable prosthesis, factors were national health insurance coverage, antagonist type, and prosthesis type (complete or partial denture), with median survival of 10 to 13 years, 11 to 14 years, and 10 to 15 years each. For still-usable prostheses, PCA analysis predicted an additional 3 years in fixed and 4.8 years in removable prosthesis. CONCLUSION Life expectancy of a prosthesis differed significantly by factors mostly controllable either by dentist or a patient. Overall life expectancy was shown to be longer than previous research.

PURPOSE: This study aimed to analyze factors influencing the success and failure of implant prostheses and to estimate the lifespan of prostheses using standardized evaluation criteria. An online survey platform was utilized to efficiently gather large samples from multiple institutions. MATERIALS AND METHODS: During the one-year period, patients visiting 16 institutions were assessed using standardized evaluation criteria (KAP criteria). Data from these institutions were collected through an online platform, and various statistical analyses were conducted. Risk factors were assessed using both the Cox proportional hazard model and Cox regression analysis. Survival analysis was conducted using Kaplan-Meier analysis and nomogram, and lifespan prediction was performed using principal component analysis. RESULTS: The number of patients involved in this study was 485, with a total of 841 prostheses evaluated. The median survival was estimated to be 16 years with a 95% confidence interval. Factors found to be significantly associated with implant prosthesis failure, characterized by higher hazard ratios, included the ‘type of clinic’, ‘type of antagonist’, and ‘plaque index’. The lifespan of implant prostheses that did not fail was estimated to exceed the projected lifespan by approximately 1.34 years. CONCLUSION To ensure the success of implant prostheses, maintaining good oral hygiene is crucial. The estimated lifespan of implant prostheses is often underestimated by approximately 1.34 years. Furthermore, standardized form, online platform, and visualization tool, such as nomogram, can be effectively utilized in future follow-up studies.