Dr Carolyn Lam:               Welcome to Circulation on the Run, your weekly podcast soiree and backstage pass to the journal and its editors. I'm Dr Carolyn Lam, Associate Editor for the National Heart Center and Duke National University of Singapore. Dr Greg Hundley:            And I'm Greg Hundley, Associate Editor from the Pauley Heart Center at VCU Health in Richmond, Virginia. Well, Carolyn, this week we're going to talk about carotid stenosis, and you remember how we measure those a lot with ultrasound, and what that thickness is, and IMT? Well, we're going to talk about getting some thresholds and an update in that with our feature discussion today. But before we get there, how about grab a cup of coffee and we get started with other papers. Dr Carolyn Lam:               All right. Well, I've got my coffee and I'm ready to tell you about two papers. They're both on left ventricular hypertrophy. One is basic and one is clinical. I will start with the basic paper because it is a super cool one that uncovers a novel mechanism underlying myocardial hypertrophy. And this involves S-nitrosylation, a prototypic, redux-based post-translational modification, S-nitrosylation. So this is from co-corresponding authors, Drs Xie, Han, and Ji from Nanjing Medical University, who performed a series of elegant experiments using myocardial samples from patients and animal models exhibiting myocardial hypertrophy, and they demonstrated that S-nitrosylation of muscle limb protein plays a crucial role in myocardial hypertrophy. This muscle limb protein modification enhanced binding to toll-like receptor 3 and receptor interacting protein kinase 3, which stimulated NOD-like receptor pyrin domain containing 3 or NLRP3 inflammasome activation and consequent caspace-1 and interleukin 1 beta activation, ultimately promoting myocardial hypertrophy. They further showed that the deficiency of S-nitrosylated muscle limb protein governed toll-like receptor 3 really alleviates pathological myocardial hypertrophy. Okay Greg, I can see the look on your face. You're like what? That was a lot. What are the clinical implications, right? Dr Greg Hundley:            Yeah, Carolyn, you are taking me back to molecular biology course 410, that I would take as a senior in college. Wow. So tell me what are the clinical implications? Dr Carolyn Lam:               All right, here's a take-home. The data really identify that S-nitrosylated muscle limb protein is a key regulator, which together with toll-like receptor 3 made therefore serve as putative therapeutic targets in treating pathological myocardial hypertrophy in heart failure. That's the take-home. Before any further comments, let's go to the clinical study. Now, this one focuses on a malignant subphenotype of left ventricular hypertrophy in which minimal elevations of cardiac biomarkers identify individuals with left ventricular hypertrophy at high risk for developing heart failure. And this is from corresponding author Dr James de Lemos from UT Southwestern. He and his colleagues tested the hypothesis that a higher prevalence of the malignant left ventricular hypertrophy phenotype among blacks may contribute to racial disparities in heart failure risk. So they pooled data from three large multi-ethnic cohorts, that is Eric, Dallas Heart Study, and MESA, totaling more than 15,700 participants. These participants were then classified into three groups: One, those without ECG left ventricular hypertrophy; two, those with ECG left ventricular hypertrophy but normal biomarkers; and three, those with ECG left ventricular hypertrophy and at normal levels of two biomarkers, high sensitivity troponin T above six nanogram per liters, or NT-proBNP above 100 picograms per milliliter. And that last group were the malignant left ventricular hypertrophy group. They found that the prevalence of malignant left ventricular hypertrophy was threefold higher among black men and women versus white men and women. Compared to p