Effect of a hypertensive response during exercise on growth rates of aortic diameters.

BACKGROUND: Aortic diameters are related to age, sex, and body size. There are a scarcity of data on the long-term sequelae of a hypertensive response to exercise (HRE) on aortic diameters. In this retrospective cohort study, we aimed to evaluate the relationship between the growth rates of the aorta in individuals with a HRE. METHODS: Our analysis included follow-up data of 649 patients recruited between January 2009 and December 2014 with a HRE. Participants with known connective tissue disease or a history of acute aortic syndrome were excluded. Sinus of Valsalva (SoV) and ascending aorta (AscAo) diameters were measured by transthoracic echocardiography using leading edge to leading edge convention at end-diastole. RESULTS: At baseline, median age, maximum systolic blood pressure (BP), body mass index (BMI), diameter of the SoV, and AscAo were 62 years, 208 mmHg, 26.9 kg/m2, 35 mm, and 35 mm respectively. 32% of patients were female and 67% had hypertension. After a median follow-up of 7.1 years, mean yearly growth rates (±SD) of the SoV and AscAo were 0.09 (0.41) mm and 0.13 (0.56) mm respectively. No significant associations were observed between growth rates of aortic diameters and maximum systolic and diastolic BP or when considering only individuals with a baseline diameter > 40mm. CONCLUSION: In this large cohort study, maximum systolic and diastolic BP during exercise showed no association with growth rates of aortic diameters. Furthermore, the mean growth rates of aortic diameters in this population were in line with growth rates in a normal population.

Hypertensive response to exercise, hypertension and heart failure with preserved ejection fraction (HFpEF)-a continuum of disease?

INTRODUCTION: Heart failure with preserved ejection fraction (HFpEF) has been shown to be a long-term consequence of uncontrolled arterial hypertension (aHT). Other than that, hypertensive response to exercise (HRE) precedes aHT. We aim to evaluate the available evidence for a continuum of HRE, aHT and HFpEF. METHODS: A literature search on PubMed was conducted to assembly the most recent data on the topic. After collecting the data, a qualitative analysis was instrumented. RESULTS: 10 studies including 16,165 subjects were analyzed with respect to the association between HRE and the future risk of developing aHT. With the exception of one study, all reported on a positive association between HRE and the future development of aHT despite methodological issues related to different definitions for HRE. Furthermore, HRE was associated with an increased risk of coronary artery disease. Moreover, we analysed 6 studies including overall 1366 subjects investigating the association between HRE and HFpEF. In these studies, increased left atrial volume index (LAVI), elevated E/e' (as surrogate parameters of increased LV end-diastolic filling pressure and of diastolic dysfunction) and higher LV mass index have been proposed as independent predictor of HRE in patients with no known HFpEF diagnosis. DISCUSSION AND CONCLUSION: The literature search revealed suggestive data on a connection of HRE, aHT and HFpEF. HRE seems to be an independent risk factor for aHT and aHT in turn is one of the main risk factors for HFpEF. However, further research is needed to improve our knowledge of a possible continuum of disease.

Determinants of LV mass in athletes: the impact of sport, constitutional traits and cardiovascular risk factors.

BACKGROUND: Whether cardiovascular (CV) risk factors might impact Left Ventricular (LV) mass in athletes is unknown. METHODS: The impact of CV risk factors (Total/LDL cholesterol, triglycerides, positive family history, smoking, body fat, blood pressure), constitutional characteristics (age, sex, body mass index) and type of sport was assessed in 1111 Olympic athletes. RESULTS: Multivariate logistic regression analysis demonstrated a significant impact: BMI ≥ 30 kg/m2 (odds ratio [OR] = 2.8. 95° Confidence Interval [CI] 0.9-13.7; < 0.001; in males); age ≥ 20-year (OR = 2.1, CI 1.4-3.3; p < 0.001) in males; (OR = 2.3; CI 1.4-3.7) in females; systolic blood pressure ≥ 130 mmHg (OR = 1.1, CI 1.01-1.16; p < 0.001) in males; (OR = 1.03; CI 1.01-1.06; p < 0.03) in females; diastolic ≥ 85 mmHg (OR = 1.1, CI 1.03-1.2; p = 0.003) in males; (OR = 1.05, CI 1.02-1.08, p < 0.001) in females. No association was found for family history, smoking, body fat, LDL, total cholesterol, triglycerides. Overall, constitutional traits explain > 60% of the LV mass. Sport explains on average 14%, but large differences existed among disciplines, i.e., endurance showed the highest impact (55%, mixed: 20%, power: 17%, skill: 8%; p < 0.001). CONCLUSION: LV mass in athletes is largely governed by constitutional traits and type of sport, and independent from CV risk factors, except for systolic and diastolic blood pressure. Overall, constitutional traits explain more than 60% of LV mass. The impact of sport is largely different in relation to the discipline, and highest in endurance, moderate mixed and power and mild in skill disciplines.

Hypertensive Response to Exercise in Athletes: Unremarkable Finding or Relevant Marker for Future Cardiovascular Complications?

Background: In the general population, hypertensive response to exercise (HRE) predicts new-onset resting hypertension or other cardiovascular diseases. Methods: PubMed was searched for English articles published between January 1st 2000 and April 30th 2020. Additional studies were identified via reference lists of included studies. 92 papers were selected for full text analysis, finally 30 studies were included. Results: The results from 5 follow-up studies suggested an association between HRE and the risk of developing hypertension, while 10 studies reported a link with adverse cardiovascular events in the general population. Another study showed an association between HRE and future hypertension in athletes after a follow-up of 7 years. HRE in athletes was associated with left ventricular hypertrophy in three studies. Two other studies showed a link between HRE and focal myocardial fibrosis in triathletes and myocardial injury, respectively. One study found lower Apoliprotein-1 serum levels in athletes with HRE leading to a higher risk for cardiovascular disease. Only in one study no association with cardiovascular dysfunction in athletes with HRE was found. Conclusions: Based on current evidence, HRE is not a normal finding in athletes. If detected, it should be interpreted as a risk factor for future cardiovascular complications. Future research should address the adequate follow-up and management of athletes with HRE.

Barlow disease: effect of mitral valve repair on ventricular arrhythmias in 82 patients in a retrospective long-term study.

BACKGROUND: Patients (pt) with mitral valve prolapse (MVP) due to Barlow disase (BD) have an increased incidence of ventricular arrhythmias (VA; including ventricular tachycardias VT) and sudden cardiac death (SCD). Data on the effect of MV repair on VA are scarce. METHODS: Pre- and postoperative VA in severe mitral regurgitation (MR) with MVP due to BD undergoing surgical mitral valve repair were analyzed. Patients with degenerative mitral valve disease not fulfilling BD criteria were excluded. Information was from charts, ECG/Holter ECG and/or pacemaker/ implantable cardioverter defibrillator (ICD) data. SCD, sustained VT>30 sec and/or ventricular fibrillation necessitating an ICD-shock were considered major events. Event probability was calculated using the Kaplan-Meier estimator throughout the follow-up period of 20.7 years. RESULTS: There were 82 pts (61% males), mean age at surgery 62±14 years. Bileaflet MVP was present in 54%, mitral annular dysjunction (MAD) in 37% and left ventricular ejection fraction (LVEF) <50% in 12%. MV repair included ring annuloplasty in all and artificial chords in 48%. Mean follow-up was 3.1 years (0.2 to 14.2 years). Postoperative rhythm surveillance by Holter ECG and/or pacemaker was available in 67%. A VA load of ≥10% and/or any VT was noted in 26% before and 32% after surgery (P=0.44). Postoperative VA load was not predicted by MAD, artificial chords, LVEF of <50%, age at surgery >50 years and/or residual ≥moderate MR (all P<0.05), it correlated only with bileaflet MVP (P=0.009). Major events occurred in 3 pts: SCD in 2 pts and ICD for sustained polymorphic VT in 1 pt (incidence 1.2%/year). The event probability of receiving a SCD or an ICD-shock was 4.9%. CONCLUSIONS: VA burden does not seem to change after MV repair in MVP due to BD. The occurrence of major arrhythmic events can not be predicted reliably, thus, patients with MVP due to BD may need lifelong postoperative follow-up, especially in bileaflet MVP which was an independent risk factor for increased VA burden in this retrospective long-term study in a small but well selected patient group.

Left ventricular hypertrophy in athletes, a case-control analysis of interindividual variability.

BACKGROUND: A variability in cardiac remodeling is observed in athletes regardless of age, sex, body size and sport participated. We sought to investigate whether other individual characteristics could affect the extent of Left ventricular hypertrophy (LVH). METHODS: From 2120 consecutive Olympic athletes, those with LVH (defined as LV Wall thickness ≥ 13 mm) were matched 1:1 by age, gender, body surface area and type of sport with non-LVH Athletes. Clinical and Echocardiographic variables were compared. RESULTS: 48 athletes with LVH (2.3%) and 48 matched non-LVH athletes were identified. LVH Athletes had higher body weight (90 ± 18 vs 81 ± 11Kg; p = 0.006) body mass index (26 ± 2 vs 24 ± 2 Kg/m2; p < 0.001) and body fat percentage (15 ± 7% vs 12 ± 4%; p = 0.016) compared to non-LVH Athletes. They also had higher systolic (123 ± 1 vs 116 ± 11 mmHg; p = 0.002) and diastolic blood pressure (76 ± 8 vs 71 ± 9 mmHg; p = 0.002). On exercise testing, LVH Athletes reached a lower index workload (3.7 ± 0.9 vs 4.1 ± 0.8 W/Kg; p = 0.013) and a higher peak diastolic blood pressure (79 ± 10 vs 74 ± 11 mmHg; p = 0.012) than those without LVH. Binary logistic regression analysis showed that diastolic blood pressure (OR 1.052; 95% CI from 1.011 to 1.130; p = 0.020) and BMI (OR 1.220; 95% CI from 1.016 to 1.465; p = 0.033) had the strongest association with LVH as categorical variable. CONCLUSIONS: Our study showed that increased blood pressure at rest and during exercise, together with larger body weight, body mass and fat percentage are associated with a higher degree of LVH, which is not associated with a greater physical performance and therefore possibly disproportionate to the sport activity.

Definitions for Hypertensive Response to Exercise.

Broad evidence indicates that hypertensive response to exercise (HRE) is associated with future hypertension (aHT) at rest and cardiovascular morbidity and mortality. Nevertheless, a consensus on the definition of HRE is lacking and the comparability of the available data is difficult due to a wide variation of definitions used. This review aims to harmonize currently available definitions of HRE in normotensive and athletic populations and to propose a generally valid cut-off applicable in everyday clinical practice. A literature search on PubMed and Embase was conducted to assemble and analyze the most recent data. Various definitions of HRE were identified and linked with future cardiovascular diseases. Forty-one studies defined HRE at a peak systolic blood pressure (SBP) above or equal to 200 mmHg in men and 25 studies for 190 mmHg in women. Peak diastolic blood pressure (DBP) between 90 and 110 mmHg was reported in 14 studies, relative DBP increase in four. Eight studies defined HRE as SBP between 160 and 200 mmHg at 100 watts. 17 studies performed submaximal exercise testing, while two more looked at BP during recovery. A plethora of other definitions was identified. In athletes, total workload and average blood pressure during exercise were considerably higher. Based on the presented data, the most commonly used definition of HRE at peak exercise is 210/105 mmHg for men, 190/105 mmHg for women, and 220/210 mmHg for athletes. Furthermore, a uniform exercise testing protocol, a position statement by leading experts to unify the definition of HRE, and prospective studies are warranted to confirm these cut-offs and the associated morbidity and mortality.

Athletes and Hypertension.

PURPOSE OF REVIEW: We reviewed most current medical literature in order to describe the epidemiology, clinical manifestation, outcome, and management of hypertension in athletes. RECENT FINDINGS: An estimated quarter of the world's population is suffering from hypertension and this prevalence is also reflected in athletes and in individuals involved in leisure time sport activities. Several studies found an inverse relationship between physical activity and blood pressure. Therefore, physical exercise is recommended to prevent, manage, and treat hypertension. On the other hand, the prevalence of hypertension may vary by sport and in some cases may even be higher in athletes competing in certain disciplines than in the general population. Hypertension is the most common medical condition in athletes and may raise concerns about its management and the individual's eligibility for competitive sports. A thorough clinical evaluation should be performed to correctly diagnose or rule out hypertension in athletes, describe the individual's risk profile, rule out secondary causes, and detect possible hypertension-mediated organ damage caused by hypertension at an early stage. Based on most recent clinical research and international consensus documents, we propose a diagnostic algorithm as well the non-pharmacological and pharmacological management of hypertension in athletes. Although elevated blood pressure levels are less common in the active population, athletes are not protected from hypertension. A thorough diagnostic approach may help to identify individual at risk for adverse cardiovascular events and to address the optimal treatment as well as sport recommendations.

The use of cardiac imaging in the evaluation of athletes in the clinical practice: A survey by the Sports Cardiology and Exercise Section of the European Association of Preventive Cardiology and University of Siena, in collaboration with the European Association of Cardiovascular Imaging, the European Heart Rhythm Association and the ESC Working Group on Myocardial and Pericardial Diseases.

AIMS: Pre-participation evaluation (PPE) is recommended to prevent sudden cardiac death in athletes. Although imaging is not advocated as a first-line screening tool, there is a growing interest in the use of echocardiography in PPE of athletes. This survey aimed to map the use of imaging in the setting of PPE and explore physician beliefs and potential barriers that may influence individual practices. METHODS: An international survey of healthcare professionals was performed across ESC Member Countries. Percentages were reported based on the number of respondents per question. RESULTS: In total, 603 individuals from 97 countries participated in the survey. Two-thirds (65%) of respondents use echocardiography always or often as part of PPE of competitive athletes and this practice is not influenced by the professional or amateur status of the athlete. The majority (81%) of respondents who use echocardiography as a first-line screening tool perform the first echocardiogram during adolescence or at the first clinical evaluation, and 72% repeat it at least once in the athletes' career, at 1-5 yearly intervals. In contrast, cardiac magnetic resonance is reserved as a second-line investigation of symptomatic athletes. The majority of the respondents did not report any barriers to echocardiography, while several barriers were identified for cardiac magnetic resonance. CONCLUSIONS: Echocardiography is frequently used as a first-line screening tool of athletes. In the absence of scientific evidence, before such practice is recommended, large studies using echocardiography in the PPE setting are necessary.

Variants in MHY7 Gene Cause Arrhythmogenic Cardiomyopathy.

BACKGROUND: Arrhythmogenic Cardiomyopathy (ACM) is a disease of the cardiac muscle, characterized by frequent ventricular arrhythmias and functional/ structural abnormalities, mainly of the right ventricle. To date, 20 different genes have been associated with ACM and the majority of them encode for desmosomal proteins. In this study, we describe the characterization of two novel variants in MHY7 gene, segregating in two ACM families. MYH7 encodes for myosin heavy chain ß (MHC-ß) isoform, involved in cardiac muscle contractility. METHOD AND RESULTS: In family A, the autopsy revealed ACM with biventricular involvement in both the proband and his father. In family B, the proband had been diagnosed as affected by ACM and implanted with implantable cardioverter defibrillator (ICD), due to ECG evidence of monomorphic ventricular tachycardia after syncope. After clinical evaluation, a molecular diagnosis was performed using a NGS custom panel. The two novel variants identified predicted damaging, located in a highly conserved domain: c. 2630T>C is not described while c.2609G>A has a frequency of 0.00000398. In silico analyses evaluated the docking characteristics between proteins using the Haddock2.2 webserver. CONCLUSIONS: Our results reveal two variants in sarcomeric genes to be the molecular cause of ACM, further increasing the genetic heterogeneity of the disease; in fact, sarcomeric variants are usually associated with HCM phenotype. Studies on the role of sarcomere genes in the pathogenesis of ACM are surely recommended in those ACM patients negative for desmosomal mutation screening.

Athletes with valvular heart disease and competitive sports: a position statement of the Sport Cardiology Section of the European Association of Preventive Cardiology.

This article provides an overview of the recommendations from the Sports Cardiology section of the European Association of Preventive Cardiology on sports participation in individuals with valvular heart disease (VHD). The aim of these recommendations is to encourage regular physical activity including sports participation, with reasonable precaution to ensure a high level of safety for all affected individuals. Valvular heart disease is usually an age-related degenerative process, predominantly affecting individuals in their fifth decade and onwards. However, there is an increasing group of younger individuals with valvular defects. The diagnosis of cardiac disorders during routine cardiac examination often raises questions about on-going participation in competitive sport with a high dynamic or static component and the level of permissible physical effort during recreational exercise. Although the natural history of several valvular diseases has been reported in the general population, little is known about the potential influence of chronic intensive physical activity on valve function, left ventricular remodelling pulmonary artery pressure, and risk of arrhythmia. Due to the sparsity of data on the effects of exercise on VHD, the present document is largely based on clinical experience and expert opinion.

Role of echocardiography in screening and evaluation of athletes.

The term athlete's heart describes structural, functional and electrical adaptations of the cardiovascular system due to repetitive intense exercise. Physiological cardiac adaptations in athletes, however, may mimic features of cardiac diseases and therefore make it difficult to distinguish physiological adaptions from disease. Furthermore, regular exercise may also lead to pathological adaptions that can promote or worsen cardiac disease (eg, atrial dilation/atrial fibrillation, aortic dilation/aortic dissection and rhythm disorders). Sudden cardiac death (SCD) is a major concern in sports cardiology, and preparticipation screening (PPS) has demonstrated to be effective in identifying athletes at risk for SCD. In Europe, PPS is advocated to include personal and family history, physical examination and ECG, with further workup including echocardiography only if the initial screening investigations show abnormal findings. We review the current available evidence for echocardiography as a screening tool for conditions associated with SCD in recreational and professional athletes and advocate to include screening echocardiography to be performed at least twice in an athlete's career. We recommend that the first echocardiography is performed during adolescence to rule out structural heart conditions associated with SCD that cannot be detected by ECG, especially mitral valve prolapse, coronary artery anomalies, bicuspid aortic valve and dilatation of the aorta. A second echocardiography could be performed from the age of 30-35 years, when athletes age and become master athletes, to especially evaluate pathological cardiac remodelling to exercise (eg, atrial and/or right ventricular dilation), late onset cardiomyopathies and wall motion abnormalities due to myocarditis or coronary artery disease.

Recommendations for participation in competitive sport in adolescent and adult athletes with Congenital Heart Disease (CHD): position statement of the Sports Cardiology & Exercise Section of the European Association of Preventive Cardiology (EAPC), the European Society of Cardiology (ESC) Working Group on Adult Congenital Heart Disease and the Sports Cardiology, Physical Activity and Prevention Working Group of the Association for European Paediatric and Congenital Cardiology (AEPC).

Improved clinical care has led to an increase in the number of adults with congenital heart disease (CHD) engaging in leisure time and competitive sports activities. Although the benefits of exercise in patients with CHD are well established, there is a low but appreciable risk of exercise-related complications. Published exercise recommendations for individuals with CHD are predominantly centred on anatomic lesions, hampering an individualized approach to exercise advice in this heterogeneous population. This document presents an update of the recommendations for competitive sports participation in athletes with cardiovascular disease published by the Sports Cardiology & Exercise section of the European Association of Preventive Cardiology (EAPC) in 2005. It introduces an approach which is based on the assessment of haemodynamic, electrophysiological and functional parameters, rather than anatomic lesions. The recommendations provide a comprehensive assessment algorithm which allows for patient-specific assessment and risk stratification of athletes with CHD who wish to participate in competitive sports.