👤 David Maron

Lipoprotein(a) (Lp[a]) can refine atherosclerotic cardiovascular disease risk assessment and guide lipid-lowering therapy intensification (LLTI). However, the association between Lp(a) testing and LLTI across large health systems is not well characterized. Using Veterans Affairs electronic health record data, we conducted a retrospective cohort study of veterans undergoing lipid testing from January 1, 2017, to June 30, 2024. We first compared a 1:1 propensity-matched cohort with concurrent low-density lipoprotein cholesterol (LDL-C) and Lp(a) testing with those with LDL-C testing alone. We then compared veterans with elevated versus nonelevated Lp(a) (>50 versus <50 mg/dL). The primary outcome was LLTI within 12 months, defined as therapy initiation, dose escalation, or addition of another lipid-lowering agent. LDL-C goal attainment (<100 mg/dL primary prevention; <70 mg/dL secondary prevention) was assessed within 12 months. Multivariable logistic regression adjusted for sociodemographic and clinical factors. Among 6 941 840 veterans with LDL-C testing, 10 384 (0.1%) underwent Lp(a) testing. The propensity-matched cohort included 20 768 veterans (mean±SD age, 58.4±15.3 years; 12.4% women; 19.2% Black individuals). Elevated Lp(a) (>50 mg/dL) was present in 25% (n=2562). Lp(a) testing was associated with greater LLTI (odds ratio [OR], 2.11 [95% CI, 1.95-2.29]), LDL-C testing (OR, 1.27 [95% CI, 1.19-1.36]), and LDL-C goal attainment (OR, 1.22 [95% CI, 1.12-1.33]). Compared with Lp(a) <50 mg/dL, Lp(a) >50 mg/dL was associated with increased LLTI (OR, 1.73 [95% CI, 1.55-1.94]). Lp(a) >100 mg/dL was associated with lower LDL-C goal attainment (OR, 0.68 [95% CI, 0.56-0.84]). Lp(a) testing was associated with increased LLTI and LDL-C goal attainment. Elevated Lp(a) identified individuals more likely to undergo LLTI, suggesting testing may motivate preventive treatment optimization. Show less

The 2025 American Society for Preventive Cardiology meeting highlighted evolving strategies in cardiovascular disease prevention, spanning risk models based on traditional risk factors, emerging biomarkers, novel therapeutics, and digital health innovations. Key discussions addressed lipoprotein(a) [Lp(a)] and inflammation as a causal risk factor, their clinical management, and readiness for targeted therapies; optimal systolic blood pressure targets informed by recent randomized controlled trials; and ongoing debate regarding apolipoprotein B versus low-density lipoprotein cholesterol (LDL-C) as the primary lipid target. Advances in digital health emphasized prevention through artificial intelligence, health equity in technology, and the growing role of wearables. Imaging emerged as a central theme, with sessions highlighting its role in risk assessment, monitoring treatment response, and refining prevention strategies, especially in young adults. Sessions on women's cardiovascular health underscored female-specific risk enhancers and limitations of current risk prediction models. Additional debates addressed the use of polygenic risk scores in young adults and strategies for universal screening with LDL-C, hsCRP, and Lp(a). Heart failure prevention was highlighted as a critical frontier, with emphasis on stage-based risk stratification, early identification of subclinical disease, and targeted interventions to avert progression to symptomatic heart failure. Updates on renal denervation reaffirmed its safety, efficacy, and durability as an adjunctive therapy in resistant hypertension. Collectively, these highlights emphasize the rapid evolution of preventive cardiology, integrating precision risk stratification, digital tools, and novel therapies into routine care. Show less

Hypertrophic cardiomyopathy (HCM) is a common heritable heart disease where the most frequently associated mutations occur in the myosin-binding protein C ( To elucidate the common and distinctive pathological pathways across species and foster a greater understanding of the concordance of mouse HCM models to clinical These common biological processes across species are consistent with known phenotypic aspects of HCM such as hypertrophy, hypercontractility, diastolic dysfunction, and altered energy metabolism. Surprisingly, among conserved biological processes within cardiomyocytes across species, the individual genes driving the biological processes were distinct. This work to identify common and species-specific disease-promoting pathway differences will allow development of targeted therapies for both human and veterinary application and will facilitate an understanding of the idiosyncrasies of mouse models. Show less

Randomized clinical trials (RCTs) for hypertrophic cardiomyopathy (HCM) have long been challenging caused by the condition's rarity, low event rates, and diverse clinical presentations. However, recent advances in targeted therapies have sparked increased interest in HCM research. Despite this, designing effective RCTs remains complex, particularly in identifying clinically meaningful endpoints. HCM, often linked to sequence variation in sarcomeric protein genes like MYH7 and MYBPC3, exhibits varied phenotypic expressions that influence disease progression and treatment responses. This genetic variability underscores the need for personalized approaches in clinical trials. Emerging gene therapies, such as CRISPR/Cas9, show promise in addressing these genetic factors. A major challenge in HCM RCTs is ensuring that endpoints are both statistically and clinically significant, given issues like test-retest variability and missing data. Primary endpoints often focus on symptom relief and functional improvement, while secondary and exploratory endpoints provide broader insights into treatment effects. Regulatory authorities are increasingly open to a wider range of endpoints, including patient-reported outcomes and functional measures, although the cost-risk balance is crucial, especially for high-risk interventions. Future HCM RCTs may incorporate hard clinical endpoints such as heart failure hospitalization, atrial fibrillation recurrence, and all-cause mortality, offering a more comprehensive evaluation of treatment efficacy. Integrating genetic insights and advanced technologies will be essential to improving trial design and enhancing patient outcomes in HCM. Show less

The myosin-binding protein C ( We studied 60 probands with HCM caused by Genetic and clinical evaluation of relatives identified 49 genotype-positive (G+) relatives with left ventricular hypertrophy (G+/LVH+), 59 G+without LVH (G+/LVH-) and 117 genotype-negative relatives (unaffected). Compared with HCM probands, G+/LVH+ relatives were older at HCM diagnosis, had less LVH, a less prevalent diastolic dysfunction, fewer ECG abnormalities, lower serum N-terminal pro-B-type natriuretic peptide (NT-proBNP) and high-sensitivity cardiac troponin I levels, and fewer symptoms. The penetrance of HCM was influenced by age and sex; specifically, LVH was present in 39% of G+males but only 9% of G+females under age 40 years (p=0.015), versus 86% and 83%, respectively, after age 60 (p=0.89). G+/LVH- subjects had normal wall thicknesses, diastolic function and NT-proBNP levels, but subtle changes in LV geometry and more ECG abnormalities than their unaffected relatives. Phenotypic expression of the Icelandic Show less

The 2 most commonly affected genes in hypertrophic cardiomyopathy (HCM) are MYH7 (β-myosin heavy chain) and MYBPC3 (β-myosin-binding protein C). Phenotypic differences between patients with mutations in these 2 genes have been inconsistent. Scarce data exist on the genotype-phenotype association as assessed by tomographic imaging using cardiac magnetic resonance imaging. Cardiac magnetic resonance imaging was performed on 358 consecutive genotyped hypertrophic cardiomyopathy probands at 5 tertiary hypertrophic cardiomyopathy centers. Genetic testing revealed a pathogenic mutation in 159 patients (44.4%). The most common genes identified were MYH7 (n=53) and MYBPC3 (n=75); 33.1% and 47% of genopositive patients, respectively. Phenotypic characteristics by cardiac magnetic resonance imaging of these 2 groups were similar, including left ventricular volumes, mass, maximal wall thickness, morphology, left atrial volume, and mitral valve leaflet lengths (all This multicenter multinational study shows lack of phenotypic differences between MYH7- and MYBPC3-associated hypertrophic cardiomyopathy when assessed by cardiac magnetic resonance imaging. Postmutational mechanisms appear more relevant to thick-filament disease expression and outcome than the disease-causing variant per se. Show less

To highlight similarities in hypertrophic cardiomyopathy (HCM) that are shared between humans and domestic cats. Contemporary clinical and scientific findings were selected from the literature. Evidence is provided to support the concept that HCM in humans and felines are fundamentally the same disease. A number of remarkable similarities have been reported in certain spontaneously occurring myocardial disorders in domestic animals that closely resemble the clinical and phenotypic features of their corresponding diseases in humans. Chief among these conditions are hypertrophic cardiomyopathy (HCM) in the cat as well as arrhythmic right ventricular cardiomyopathy in cats and Boxer dogs, and non-hypertrophied restrictive cardiomyopathy in cats. Hypertrophic cardiomyopathy occurs commonly in the cat where it is a prominent cause of congestive heart failure and cardiovascular disability. Its prevalence in certain breeds suggests that it is a familial condition. Despite some inter-species differences in the expression of HCM in man and cats, their phenotypic expressions are very similar, supporting the belief that they are essentially the same disease in both species. These similarities include marked disease heterogeneity with unexplained asymmetric left ventricular hypertrophy, histopathology that includes disorganized myocyte arrangement, microvascular disease, and interstitial fibrosis, and end-stage cardiac remodeling. In cats two causal mutations have been identified in the myosin binding protein C (MYBPC3), though in man, mutations associated with 11 genes encoding for cardiac sarcomeric proteins are responsible for HCM. Given the similarities of HCM in both cats and man, the study of feline HCM may help expand the understanding of disease pathophysiology and help lead to improved disease management. Show less

The geographic isolation and homogeneous population of Iceland are ideally suited to ascertain clinical and genetic characteristics of hypertrophic cardiomyopathy (HCM) at the population level. Medical records and cardiac imaging studies obtained between 1997 and 2010 were reviewed to identify Icelandic patients with HCM. Surviving patients were recruited for clinical and genetic studies. A previously identified Icelandic mutation, MYBPC3 c.927-2A>G, was genotyped, and mutation-negative samples were sequenced for HCM genes and other hypertrophic genes. Record review identified 180 patients with HCM. Genetic analyses of 151 patients defined pathogenic mutations in 101 (67%), including MYBPC3 c.927-2A>G (88 patients, 58%), 4 other MYBPC3 or MYH7 mutations (5 patients, 3.3%), and 2 GLA mutations (8 patients, 5.3%). Haplotype and genetic genealogical data defined MYBPC3 c.927-2A>G as a founder mutation, introduced into the Icelandic population in the 15th century, with a current population prevalence of 0.36%. MYBPC3 c.927-2A>G mutation carriers exhibited phenotypic diversity but were younger at diagnosis (42 versus 49 years; P=0.001) and sustained more adverse events (15% versus 2%; P=0.02) than mutation-negative patients. All-cause mortality for patients with HCM was similar to that of an age-matched Icelandic population (hazard ratio, 0.98; P=0.9). HCM-related mortality (0.78%/y) occurred at a mean age of 68 compared with 81 years for non-HCM-related mortality (P=0.02). A founder MYBPC3 mutation that arose >550 years ago is the predominant cause of HCM in Iceland. The MYBPC3 c.927-2A>G mutation is associated with low adverse event rates but earlier cardiovascular mortality, illustrating the impact of genotype on outcomes in HCM. Show less

End-stage hypertrophic cardiomyopathy (ES-HC) has an ominous prognosis. Whether genotype can influence ES-HC occurrence is unresolved. We assessed the spectrum and clinical correlates of HC-associated mutations in a large multicenter cohort with end-stage ES-HC. Sequencing analysis of 8 sarcomere genes (MYH7, MYBPC3, TNNI3, TNNT2, TPM1, MYL2, MYL3, and ACTC1) and 2 metabolic genes (PRKAG2 and LAMP2) was performed in 156 ES-HC patients with left ventricular (LV) ejection fraction (EF) <50%. A comparison among mutated and negative ES-HC patients and a reference cohort of 181 HC patients with preserved LVEF was performed. Overall, 131 mutations (36 novel) were identified in 104 ES-HC patients (67%) predominantly affecting MYH7 and MYBPC3 (80%). Complex genotypes with double or triple mutations were present in 13% compared with 5% of the reference cohort (p = 0.013). The distribution of mutations was otherwise indistinguishable in the 2 groups. Among ES-HC patients, those presenting at first evaluation before the age of 20 had a 30% prevalence of complex genotypes compared with 19% and 21% in the subgroups aged 20 to 59 and ≥60 years (p = 0.003). MYBPC3 mutation carriers with ES-HC were older than patients with MYH7, other single mutations, or multiple mutations (median 41 vs 16, 26, and 28 years, p ≤0.001). Outcome of ES-HC patients was severe irrespective of genotype. In conclusion, the ES phase of HC is associated with a variable genetic substrate, not distinguishable from that of patients with HC and preserved EF, except for a higher frequency of complex genotypes with double or triple mutations of sarcomere genes. Show less

Risk stratification strategies employing sarcomere gene mutational analysis have proved imprecise in identifying high-risk patients with hypertrophic cardiomyopathy (HCM). Therefore, additional genetic risk markers that reliably determine which patients are predisposed to sudden death are needed. The objective of this study was to determine whether multiple disease-causing sarcomere mutations can be regarded as markers for sudden death in the absence of other conventional risk factors. Databases of 3 HCM centers were accessed, and 18 probands with 2 disease-causing mutations in genes encoding proteins of the cardiac sarcomere were identified. Severe disease progression or adverse cardiovascular events occurred in 7 of these 18 patients (39%), including 3 patients (ages 31, 37, and 57 years) who experienced sudden cardiac arrest but also were without evidence of conventional HCM risk factors; 2 survived with timely defibrillation and therapeutic hypothermia and 1 died. These 3 probands carried distinct and heterozygous disease-causing sarcomere mutations (including a man who inherited 1 mutation independently from each of his parents with HCM)-that is, double MYBPC3 and TNNI3 mutations and compound MYBPC3 mutations-as the only predisposing clinical markers evident to potentially explain their unexpected cardiac event. These observations support the emerging hypothesis that double (or compound) mutations detected by genetic testing may confer a gene dosage effect in HCM, thereby predisposing patients to adverse disease progression. In 3 families, multiple sarcomere mutations were associated with a risk of sudden death, even in the absence of conventional risk factors. Show less