In the past decade, HCM SCD risk stratification has been an area of intense research and discussion. In 2011, American guidelines7 recommended implantable cardioverter defibrillator (ICD) implantation for primary prevention (Class IIa recommendation) in patients with family history of SCD in a first-degree relative, with severe hypertrophy (≥30 mm) or who presented one or more episodes of recent and unexplained syncope. In patients with non-sustained ventricular tachycardia (NSVT) or an abnormal blood pressure response to exercise (ABPRE), ICD placement could be considered (Class IIb recommendation) in the presence of other SCD modifying risk factors.

In 2012, O’Mahony et al.31 performed a validation study of this strategy concluding that it is effective in preventing SCD in HCM patients, but its low discriminatory power results in the implantation of ICDs in a much larger number of patients than really needed. In 2014, a new SCD risk prediction clinical model was published,5 using mathematical models to weigh up the effects of specific risk markers, which are assessed as continuous variables, as opposed to the American strategy which treats risk factors, such as LV wall thickness, as binary variables. The HCM Risk-SCD model was included in the 2014 European HCM guidelines4 and is accessible as an online calculator. By entering the values obtained for seven clinical and imaging parameters, it is possible to obtain 5-year SCD risk estimate for a specific patient (Table 2).

Several independent validation studies followed. Maron et al.32 reported, based on the evaluation of this algorithm in a cohort of 1629 patients, a high specificity for patients with low risk of SCD but a low sensitivity for patients with SCD events, concluding that the European strategy minimizes the overtreatment of HCM patients with ICD, however, leaves a significant percentage of patients at high-risk of SCD unprotected. Conversely, O’Mahony et al.33 performed a meta-analysis involving 7291 patients, confirming that the HCM Risk-SCD model's ability to predict SCD events in low risk (predicted<4%) and high-risk groups (predicted≥6%), with a pooled prevalence of SCD endpoints of 1.01% and 8.4%, respectively. Although this meta-analysis suggested an overestimation of risk in the intermediate group, which presented a pooled prevalence of SCD endpoints of 2.43%, at the end, more than two thirds of SCD occurred in the intermediate and high-risk groups, and, accordingly, the pragmatic approach is to continue to target these patients for primary prevention ICD.

Recently, the enhanced American strategy for prevention of SCD in HCM patients34 and American College of Cardiology (ACC)/American Heart Association (AHA) guidelines29 were published, modifying the American algorithm to redefine the importance of the following markers, now considered to be of high risk: The presence of LV apical aneurysms, extensive LGE in CMR (usually ≥15% of LV mass) and LV systolic dysfunction (defined as LV ejection fraction <50%). Together these risk markers were associated with more than 25% of appropriate ICD therapies in this study. The presence of any of these risk factors or the former ones (with the exception of the ABPRE, which was excluded from the new algorithm) may be an indication for ICD implantation, with different levels of strength. In the group of patients >60 years of age, known to be associated with a low likelihood of SCD,35 the decision to implant an ICD for primary prevention should be individualized.

In a conceptual analysis of the two strategies, one of the main strengths of the European score is the inclusion of continuous variables as they are naturally, since it is unlikely that a septum with 29 mm portends a significant different SCD risk when compared to a 30 mm septum. In addition, the HCM Risk-SCD model incorporates age, which is known to be associated with ventricular arrhythmias,10 and provides an individualized and objective SCD risk prediction. On the other hand, the enhanced American strategy includes new robust risk factors such as systolic disfunction, presence of apical aneurysm and LGE amount, which seem to increase substantially the accuracy of this algorithm (Table 2).

In the absence of a perfect stratification system, both strategies should be applied and discussed and, importantly, the patient's preference should always be considered in a shared decision making process. In controversial cases, other less consensual emerging risk factors may be important and could work in the future as referees, although their role in decision making has not been established (Table 3).

Hypertrophic cardiomyopathy research has been strongly focused on risk stratification and prevention of SCD. Consequently, important progress has been achieved in this area and the coexistence of appropriate therapies has drastically reduced mortality from SCD in HCM. HF is now emerging as an increasingly prominent management issue. In fact, HF is an important cause of HCM-related morbidity and mortality, and is a frequent pattern of disease progression.

Melacini et al.36 studied a cohort of 293 HCM patients, assessed between 1980 and 2001 at a HCM referral center, and during a median follow-up of 6 years they detected the presence of severe progressive HF (New York Heart Association (NYHA) class III or IV) in 50 of these patients (17%). Three different HF profiles were defined, based on the predominant pathophysiological component:

• 1)

  End-stage systolic dysfunction, defined as LV ejection fraction <50% (n=15, 30% of HF). In this group, LV was more dilated than in the others and had extensive areas of replacement fibrosis, often transmural, probably a consequence of microvascular ischemia, whereas in the other groups, there was either no fibrosis or this was only focal. Natural history of this subgroup of patients was addressed by Harris et al.,37 reporting poor outcomes in 66% of these patients, who died from progressive HF, had sudden death events or underwent heart transplant in a mean follow-up of 3.3 years. Time from HCM symptom onset to systolic disfunction was 10 to 14 years, but time from systolic disfunction to death or heart transplant was 2.7 years. Risk factors for systolic disfunction were younger age at HCM diagnosis, more severe symptoms at presentation, larger LV cavity, less frequent LV outflow tract obstruction (LVOTO), more frequent family history of both HCM (70%) and end-stage HCM (20%).

• 2)

  Obstructive (O)-HCM (n=11, 22% confidence interval). In this group, patients were older at the time of HCM diagnosis and LV was more hypertrophied when compared to other HF groups.

• 3)

  Nonobstructive (NO)-HCM with preserved systolic function (n=24, 48% of HF). Diastolic dysfunction was common in this group. These patients showed the most accelerated progression to advanced HF, four to six years after symptoms onset, and to adverse outcome defined as death or transplant or last follow-up, another four to six years. In histopathological analysis, LV was hypertrophied and nondilated, with no significant fibrosis. NO-HCM with preserved systolic function and advanced HF patients were also assessed by Rowing et al.,38 in a study including 46 NO-HCM pts who were listed for heart transplant. Twenty of these patients had LVEF≥50%. Similar to Melacini's report, these patients had hypertrophied and nondilated LV, most of them with little or no fibrosis in CMR, and evidence of diastolic dysfunction according to echocardiographic criteria. Family history of HCM was present in 14 of the 20 patients. Interestingly, in five cases (25%), first-degree relatives developed “burn-out” HCM, suggesting a familiar HCM clustering of higher risk HCM, but not equivalent phenotypes.

Concerning HF related to O-HCM, specific treatment options are available, such as surgical myectomy and alcohol septal ablation: in experienced centers, both have demonstrated being very effective and have improved HF morbidity and mortality in O-HCM patients. However, there is a gap in specific therapy for NO-HCM-related HF, perhaps because its molecular basis is still not well understood. The just published AHA/ACC guidelines29 recommend treating HF symptoms in patients with NO-HCM similarly to other patients with HF. However, the literature demonstrates that this group continues to present a worse prognosis when compared to other groups of HCM patients. Intensive research is needed to better treat these patients.

Atrial fibrillation is a frequent complication of HCM and has historically been associated with increased morbidity and mortality in these patients.39,40 However, more recent studies41 suggest, under the current treatment strategy, that AF is not an important contributor to HF or a cause of SCD. In fact, AF is rarely the primary cause of death in HCM and is almost virtually limited to the context of embolic stroke, which supports a low threshold for starting anticoagulant therapy. Rowing et al.41 report no difference in the outcomes of patients with HCM and AF vs. HCM without AF, comparing age and sex-adjusted cohorts, regarding SCD, global or HCM-related mortality or NYHA class progression. Although each episode of paroxysmal AF can manifest itself with great clinical exuberance, the decrease in a patient's quality of life is transient and treatable, and arrhythmia will not inevitably be progressive. Only 25% of patients progress to permanent AF.

Atrial fibrillation treatment in patients with HCM also has some specificities: a take-home message is, in the absence of contraindications, there must be a low threshold to start anticoagulation, usually after the first episode of AF. Guttmann et al.42 developed a prediction model in HCM for thromboembolic events (TE) at five years based on the following clinical variables: age, AF, previous TE, NYHA class, left atrium (LA) diameter, vascular disease and maximum LV wall thickness. Although it has not been demonstrated that patients with HCM in sinus rhythm with a high estimated risk of TE should undergo anticoagulation prior to the first AF episode, the recommendation of frequent ECG monitoring in an outpatient setting in patients with dilated LA is supported. In fact, the authors demonstrate a linear relationship between the diameter of the LA and TE risk until 45-50 mm. Above that cut-off, TE risk increases exponentially. In contrast, the CHA2DS2-VASc score has a very low predictive acuity in this population and should not be used in HCM.

Despite the scarcity of randomized trials on the use of new oral anticoagulants in HCM, data from large observational studies43–45 suggest a non-inferiority of these new agents in relation to warfarin, associated with a greater comfort of administration. Indeed, current AHA/ACC guidelines29 recommend direct-acting oral anticoagulants as a first line option in these patients.

Drug selection for rhythm maintenance in patients with HCM is based on extrapolation from studies on AF in the general population. Most recent HCM recommendations29 consider reasonable therapy with amiodarone, dofetilide or sotalol. However, current evidence in AF-HCM patients suggests rhythm maintenance pharmacological therapy has limited efficacy, especially over time.46

Similarly, AF catheter ablation does not appear to be as effective as in non-HCM AF patients.47 Even so, current evidence suggests an improvement in the outcome of patients with HCM and AF undergoing ablation vs. those controlled with pharmacological therapy.48 A meta-analysis including five comparative studies of AF ablation success in HCM vs. non-HCM patients49 reported that patients with HCM and AF had a two-fold increase of risk of recurrence of arrhythmia compared to non-HCM patients. However, the outcome in patients with HCM, with less dilated atria and paroxysmal AF appeared to approximate that of the general population. Since the risk of procedure-related adverse events was low, the authors conclude that catheter ablation may be effective in patients with AF and HCM, particularly in patients with small atria.

To date, recommended pharmacological therapy in patients with symptomatic O-HCM has been nonspecific and had limited benefits on symptom relief. In patients with moderate to severe symptoms, in spite of maximally tolerated drug therapy, invasive treatment to reduce LVOTO should be considered, surgical septal myectomy or alcohol septal ablation. Both strategies have a very high success rate in experienced centers, although neither is risk-free and some patients require multiple interventions, especially those who undergo alcohol septal ablation.

The pathophysiological mechanism involved in the development of LVOTO includes an hyperdynamic ejection and an exacerbated inotropism that, in HCM patients, results from an exaggerated interaction between actin and myosin filaments. This process results in hypercontractility, incomplete relaxation and increased waste of energy, which, ultimately, through several still unknown pathways, leads to myocardial dysfunction and fibrosis.

Mavacamten is a specific allosteric inhibitor of cardiac myosin ATPase, which has been shown in vitro to be able to restore the proportion of myosin in a super relaxed state, reducing excess interaction between the myosin and actin filaments and normalizing ATP consumption.50 Pre-clinical studies in HCM animal models demonstrated that the administration of mavacamten reduced myocardial contractility, eliminated mitral valve systolic anterior movement and decreased LVOT gradient and, if administered before the implementation of the hypertrophic phenotype, attenuated the development of left ventricular hypertrophy, myocardial disarray and fibrosis.51

The recently published EXPLORER-HCM multicenter phase 3 study aimed to assess the efficacy and safety of mavacamten in the treatment of symptomatic patients with O-HCM (NYHA class II or III).52 This clinical trial, which involved 251 patients, 123 receiving mavacamten and 128 placebo, lasted 30 weeks and was completed by 97% of patients. Mavacamten lead to a significant decrease in LVOT gradients after exercise. Almost 75% of patients showed a reduction to values <50 mmHg and 56% demonstrated complete disappearance of the obstruction. Mavacamten also demonstrated improvement in NYHA functional class, in peak VO2, in symptoms and quality of life assessed scores, and significant reductions in N terminal-pro nrain natriuretic peptide (NT-proBNP) and troponin I levels. Mavacamten was well tolerated, with a safety profile comparable to placebo. It is, therefore, a promising drug in O-HCM patients.

Based on in vitro tests that demonstrated the ability of mavacamten to reduce the interaction between myosin and actin filaments, it is possible that, through an improvement in diastolic function and an optimization of energy use, this new drug may be beneficial in a NO-HCM patient population. The MAVERICK-HCM study53 was a multicenter phase 2 study designed to evaluate the safety and tolerability of mavacamten in symptomatic patients (NYHA class II or III) with NO-HCM. Mavacamten was well tolerated by most patients: serious adverse events were detected in 10% of the group undergoing treatment vs. 21% in the placebo group, and in all cases, patients recovered without sequelae. In five out of 40 patients receiving mavacamten, EF decreased to values ≤45%, which was reversible after drug suspension. In addition, therapy was associated with a significant decrease in NT-proBNP and cardiac troponin-I which suggests an improvement in myocardial stress, paving the way for phase 3 studies to seek clinical benefit in this patient population.

Until very recently, an HCM diagnosis imposed an almost total restriction on intensive sports, based mainly on a study of causes of sudden death in young American athletes, which suggested that exercise increased the risk of SCD in patients with HCM.54 However, recent longitudinal studies seem to indicate that the risk of SCD during exercise is lower than previously considered. Pellicia et al.55 in a study with nine years of follow-up, found no difference in the incidence of symptoms or major events in athletes with HCM who stopped physical exercise (n=20) vs. athletes with HCM who continued to practice competitive sport (n=15). On the other hand, in a cross-sectional study involving 121 patients with HCM, the practice of vigorous physical exercise was similar in groups with or without ventricular arrhythmias.56

Current recommendations57 adopt a more liberal approach to sports participation in some patients with HCM, especially those who intend to maintain non-competitive physical activity. In fact, the most recent AHA/ACC guidelines29 comment on recreational exercise as having benefits on general health in HCM patients, similar to that of the general population. A rigorous evaluation must be carried out by experts, assessing HCM severity but also excluding other comorbidities such as hypertension or coronary heart disease. Recommendations57 advise against the practice of high intensity exercise for individuals who present any marker of increased risk, such as 1. History of SCD or unexplained syncope; 2. Estimated five-year risk of SCD≥4% using the HCM Risk-SCD model; 3. LVOTO at rest >30 mmHg; 4. ABPRE; 5. Exercise-induced arrhythmias. For these patients, the practice of recreational exercise of low to moderate intensity may be considered. In HCM patients without any of the aforementioned risk factors, practice of competitive high intensity physical exercise may be considered, with the exception of cases in which the occurrence of syncope may result in injury or death.

Also relevant in this area is another study underway, which is attempting to characterize the impact of physical exercise and lifestyle on the well-being of HCM patients (LIVE-HCM). Until accurate answers are obtained, the discussion of the clinical context with the patient and shared decision making is accepted as the best strategy for applying restrictions to exercise in this population.