Denise Maria Servantes

How much do the benefits cost? Effects of a home-based training programme on cardiovascular fitness, quality of life, programme cost and adherence for patients with coronary disease

Objective: To evaluate cost, adherence and effects on cardiovascular function and quality of life of a home-based cardiac rehabilitation programme for patients with coronary disease. Design: A randomized, prospective controlled trial. Setting: Department of Rehabilitation, University Hospital, Brazil. Subjects: Thirty-nine low-risk patients were assigned to a home exercise training group (n = 19) or a control group (n = 20). Interventions: The home group performed home-based training for three months with biweekly telephone monitoring. Main outcome measures: The aerobic capacity and the quality of life (Medical Outcomes Study 36-Item Short Form Survey (SF-36)) of all patients were evaluated before and after the three-month period. Adherence was evaluated weekly. Programme cost was estimated using the Brazilian Classification of Medical Procedures. Results: After training, the home group had higher peak Vo2 from 28.8 (6.4) to 31.7 (8.1) mL/kg per minute, peak heart rate from 135 (22) to 143 (20) bpm, work rate from 4780 (2021) to 7103 (3057) kpm/min and exercise time from 11.5 (1.9) to 13.6 (2.3) minutes (P ≤ 0.05). The control group showed reduction in peak Vo2 from 28.6 (6.6) to 26.8 (7.2) mL/kg per minute, peak Vo2 pulse from 15.5 (3.9) to 14.3 (3.8) mL/bpm and exercise time from 11.5 (2.3) to 11.4 (2.7) minutes (P ≤ 0.05). The home group reported improvements in all domains of SF-36. The control group showed improvement in only three domains of SF-36. In the home group the average cost per patient was US

Effects of home-based exercise training for patients with chronic heart failure and sleep apnoea: a randomized comparison of two different programmes

502.71 and the adherence achieved 100%. Conclusion: The programme seems to provide an efficient low-cost approach to cardiac rehabilitation in low-risk patients.

Correlação entre qualidade de vida e capacidade funcional na insuficiência cardíaca

Objective: To evaluate the effects of home-based exercise for patients with chronic heart failure and sleep apnoea and to compare two different training programmes. Design: A randomized, prospective controlled trial. Setting: Department of Cardiology, University Hospital, Brazil. Subjects: Fifty chronic heart failure patients with sleep apnoea were randomized in three groups: Group 1 (aerobic training, n = 18), Group 2 (aerobic with strength training, n = 18), and Group 3 (untrained, n = 14). Interventions: The training programme for Groups 1 and 2 began with three supervised exercise sessions, after they underwent three months of home-based exercise. Patients were followed by weekly telephone call and were reviewed monthly. Group 3 had the status of physical activity evaluated weekly by interview to make sure they remained untrained. Main outcome measures: At baseline and after three months: cardiopulmonary exercise testing, isokinetic strength and endurance, Minnesota living with heart failure questionnaire and polysomnography. Adherence was evaluated weekly. Results: Of the 50 patients enrolled in the study, 45 completed the programme. Clinical events: Group 1 (one death), Group 2 (one myocardial infarction), Group 3 (one death and two strokes). None were training related. Training groups showed improvement in all outcomes evaluated and the adherence was an important factor (Group 1 = 98.5% and Group 2 = 100.2%, P = 0.743). Untrained Group 3 demonstrated significant decrease or no change on measurements after three months without training. Conclusion: Home-based exercise training is an important therapeutic strategy in chronic heart failure patients with sleep apnoea, and strength training resulted in a higher increase in muscle strength and endurance.

Ankle-brachial index and ventricular hypertrophy in arterial hypertension

BACKGROUND: Patients with cardiac failure (CF) present progressive incapacity and decreased quality of life, both related to dyspnea and fatigue. Thus, there is the increasing interest in measring the quality of life (QL), by generic instrument, such as the 36-item Short-Form Health Survey (SF-36), by specific instrument, such as Minnesota Living with Heart Failure (MLHFQ). OBJECTIVE: This study has the objective to correlate the QL surveys, SF-36 and MLHFQ, with the functional capacity of patients with CF, expressed by the cardiopulmonary test and the TC6M. METHODS: Using the SF-36 and MLHFQ surveys for QL evaluation, for the evaluation of the functional capacity, it was used the cardiopulmonary test, being executed using a tredmill with Weber protocol, as well sa the distance covered in the walk test of six minutes (TC6M). RESULTS: Forty-six patients were selected with CF diagnosis (22 men, average age of 52 years old), classes II and III of New York Heart Association. It was observed that the mild correlation between the physical and emotional domains of SF-36 and VE/VCO2.peak (r=-0.3; p<0.05) and the distance covered in TC6M (r=0.4; p<0.05), respectively. It was also observed the mild to moderate correlations of MLHFQ total score with VO2.peak (r=-0.5; p<0.05), the aerobic threshold (r=-0.4; p<0.05) and the distance covered in TC6M (r=-0.5; p<0.05). CONCLUSION: The data suggest that the application of both evaluation instruments of QL, generic (SF-36) and specific (MLHFQ) in patients with CF, showed mild and moderate correlation with the variable of the cardiopulmonary test with the variables of the cardiopulmonary test and the distance covered in TC6M.

Índice tornozelo-braquial e hipertrofia ventricular na hipertensão arterial

The ankle-brachial index (ABI) is a marker of peripheral arterial disease. Very few reports have correlated this index with left ventricular hypertrophy (LVH), functional capacity (FC) and Framingham risk score (FRS). The objective of this study was to verify the correlation between ABI, LVH, FC and FRS in men with arterial hypertension (AH). Prospective and cross-sectional study of male patients (n = 40) with a mean age of 57.92 ± 7.61 years and no cardiovascular complications. This population was submitted to ABI measurements, echocardiography (ECHO), exercise test (ET) and laboratory tests. The ABI (right and left) was considered abnormal when the ratio between the highest mean systolic pressures of the ankles and arms was 0.9 or higher than 1.3 mmHg. LVH was identified by transthoracic ECHO and the FC by the ET. Peripheral blood samples were collected to calculate the FRS. Normal ABI values were observed in 33 patients (82.5%), who were included in Group I; seven patients (17.5%) with abnormal ABI constituted Group II. Left ventricular mass index (LVMI) at the ECO were 111.18 ± 34.34 g/m2 (Group I) and 150.29 ± 34.06 g/m2 (Group II) (p = 0.009). The prevalence of LVH was 4% (Group I) and 35.3% (Group II) (p = 0.01), demonstrating a significant difference between the groups. As for the FC in ET, there was no difference between the groups. Regarding the FRS, the mean in Group I was below that in Group II: 13.18 ± 2.11 versus 15.28 ± 1.79 (p = 0.019). In hypertensive patients, the presence of LVH defined by the LVMI was more frequent in cases with abnormal ABI, identifying a higher cardiovascular risk.The ankle-brachial index (ABI) is a marker of peripheral arterial disease. Very few reports have correlated this index with left ventricular hypertrophy (LVH), functional capacity (FC) and Framingham risk score (FRS). The objective of this study was to verify the correlation between ABI, LVH, FC and FRS in men with arterial hypertension (AH). Prospective and cross-sectional study of male patients (n = 40) with a mean age of 57.92 ± 7.61 years and no cardiovascular complications. This population was submitted to ABI measurements, echocardiography (ECHO), exercise test (ET) and laboratory tests. The ABI (right and left) was considered abnormal when the ratio between the highest mean systolic pressures of the ankles and arms was 0.9 or higher than 1.3 mmHg. LVH was identified by transthoracic ECHO and the FC by the ET. Peripheral blood samples were collected to calculate the FRS. Normal ABI values were observed in 33 patients (82.5%), who were included in Group I; seven patients (17.5%) with abnormal ABI constituted Group II. Left ventricular mass index (LVMI) at the ECO were 111.18 ± 34.34 g/m(2) (Group I) and 150.29 ± 34.06 g/m(2) (Group II) (p = 0.009). The prevalence of LVH was 4% (Group I) and 35.3% (Group II) (p = 0.01), demonstrating a significant difference between the groups. As for the FC in ET, there was no difference between the groups. Regarding the FRS, the mean in Group I was below that in Group II: 13.18 ± 2.11 versus 15.28 ± 1.79 (p = 0.019). In hypertensive patients, the presence of LVH defined by the LVMI was more frequent in cases with abnormal ABI, identifying a higher cardiovascular risk.

Validation of a novel sleep-quality questionnaire to assess sleep in the coronary care unit: a polysomnography study

The ankle-brachial index (ABI) is a marker of peripheral arterial disease. Very few reports have correlated this index with left ventricular hypertrophy (LVH), functional capacity (FC) and Framingham risk score (FRS). The objective of this study was to verify the correlation between ABI, LVH, FC and FRS in men with arterial hypertension (AH). Prospective and cross-sectional study of male patients (n = 40) with a mean age of 57.92 ± 7.61 years and no cardiovascular complications. This population was submitted to ABI measurements, echocardiography (ECHO), exercise test (ET) and laboratory tests. The ABI (right and left) was considered abnormal when the ratio between the highest mean systolic pressures of the ankles and arms was 0.9 or higher than 1.3 mmHg. LVH was identified by transthoracic ECHO and the FC by the ET. Peripheral blood samples were collected to calculate the FRS. Normal ABI values were observed in 33 patients (82.5%), who were included in Group I; seven patients (17.5%) with abnormal ABI constituted Group II. Left ventricular mass index (LVMI) at the ECO were 111.18 ± 34.34 g/m2 (Group I) and 150.29 ± 34.06 g/m2 (Group II) (p = 0.009). The prevalence of LVH was 4% (Group I) and 35.3% (Group II) (p = 0.01), demonstrating a significant difference between the groups. As for the FC in ET, there was no difference between the groups. Regarding the FRS, the mean in Group I was below that in Group II: 13.18 ± 2.11 versus 15.28 ± 1.79 (p = 0.019). In hypertensive patients, the presence of LVH defined by the LVMI was more frequent in cases with abnormal ABI, identifying a higher cardiovascular risk.The ankle-brachial index (ABI) is a marker of peripheral arterial disease. Very few reports have correlated this index with left ventricular hypertrophy (LVH), functional capacity (FC) and Framingham risk score (FRS). The objective of this study was to verify the correlation between ABI, LVH, FC and FRS in men with arterial hypertension (AH). Prospective and cross-sectional study of male patients (n = 40) with a mean age of 57.92 ± 7.61 years and no cardiovascular complications. This population was submitted to ABI measurements, echocardiography (ECHO), exercise test (ET) and laboratory tests. The ABI (right and left) was considered abnormal when the ratio between the highest mean systolic pressures of the ankles and arms was 0.9 or higher than 1.3 mmHg. LVH was identified by transthoracic ECHO and the FC by the ET. Peripheral blood samples were collected to calculate the FRS. Normal ABI values were observed in 33 patients (82.5%), who were included in Group I; seven patients (17.5%) with abnormal ABI constituted Group II. Left ventricular mass index (LVMI) at the ECO were 111.18 ± 34.34 g/m(2) (Group I) and 150.29 ± 34.06 g/m(2) (Group II) (p = 0.009). The prevalence of LVH was 4% (Group I) and 35.3% (Group II) (p = 0.01), demonstrating a significant difference between the groups. As for the FC in ET, there was no difference between the groups. Regarding the FRS, the mean in Group I was below that in Group II: 13.18 ± 2.11 versus 15.28 ± 1.79 (p = 0.019). In hypertensive patients, the presence of LVH defined by the LVMI was more frequent in cases with abnormal ABI, identifying a higher cardiovascular risk.

Effects of Exercise Training and CPAP in Patients With Heart Failure and OSA: A Preliminary Study

INTRODUCTION The sleep of patients admitted to coronary care unit (CCU) may be compromised. A feasible and cost-effective tool to evaluate sleep in this scenario could provide important data. The aim of this study was to evaluate sleep with a questionnaire developed specifically for the CCU and to validate it with polysomnography (PSG). METHODS Ninety-nine patients (68% male; 56 ± 10 years old) with acute coronary syndrome were included. PSG was performed within 36 h of admission. A specific 18-question questionnaire (CCU questionnaire) was developed and applied after the PSG. Cronbachs alpha test was used to validate the questionnaire. The Spearman test was used to analyze the correlation between the PSG variables and the questionnaire, and the Kruskal-Wallis test was used to compare the PSG variables among patients with good, regular, or poor sleep. RESULTS The total sleep time was 265 ± 81 min, sleep efficiency 62 ± 18%, REM sleep 10 ± 7%, apnea/hypopnea index 15 ± 23, and the arousal index 24 ± 15. Cronbachs alpha test was 0.69. The CCU questionnaire showed correlation with the sleep efficiency evaluated by PSG (r: 0.52; p < 0.001). Sleep quality was divided into three categories according to the CCU questionnaire: patients with good sleep had a sleep efficiency of 72 ± 9%, better than those with a regular or poor sleep (60 ± 16% and 53 ± 20%, respectively; p < 0.01). CONCLUSION The CCU questionnaire is a feasible and reliable tool to evaluate sleep in the CCU, showing correlation with the PSG sleep efficiency.

Índice tobillo-braquial y hipertrofia ventricular en la hipertensión arterial

Background Exercise and CPAP improve OSA. This study examined the effects of exercise in patients with heart failure (HF) and OSA. Methods Patients with HF and OSA were randomized to the following study groups: control, exercise, CPAP, and exercise + CPAP. Results Sixty‐five participants completed the protocol. Comparing baseline vs 3 months, the mean apnea‐hypopnea index (AHI) did not change significantly (in events per hour) in the control group, decreased moderately in the exercise group (28 ± 17 to 18 ± 12; P < .03), and decreased significantly more in the CPAP group (32 ± 25 to 8 ± 11; P < .007) and in the exercise + CPAP group (25 ± 15 to 10 ± 16; P < .007). Peak oxygen consumption, muscle strength, and endurance improved only with exercise. Both exercise and CPAP improved subjective excessive daytime sleepiness, quality of life, and the New York Heart Association functional class. However, compared with the control group, changes in scores on the 36‐item Medical Outcomes Study Short Form Survey and Minnesota Living with Heart Failure Questionnaire were only significant in the exercise groups. Conclusions In patients with HF and OSA, our preliminary results showed that exercise alone attenuated OSA and improved quality of life more than CPAP. In the landscape treatment of OSA in patients with HF, this analysis is the only randomized trial showing any treatment (in this case, exercise) that improved all the studied parameters. The results highlight the important therapeutic benefits of exercise, particularly because adherence to CPAP is low.

Teste ergométrico precoce após infarto do miocárdio: comparação com ecocardiograma, monitorização eletrocardiográfica e arteriografia coronariana

The ankle-brachial index (ABI) is a marker of peripheral arterial disease. Very few reports have correlated this index with left ventricular hypertrophy (LVH), functional capacity (FC) and Framingham risk score (FRS). The objective of this study was to verify the correlation between ABI, LVH, FC and FRS in men with arterial hypertension (AH). Prospective and cross-sectional study of male patients (n = 40) with a mean age of 57.92 ± 7.61 years and no cardiovascular complications. This population was submitted to ABI measurements, echocardiography (ECHO), exercise test (ET) and laboratory tests. The ABI (right and left) was considered abnormal when the ratio between the highest mean systolic pressures of the ankles and arms was 0.9 or higher than 1.3 mmHg. LVH was identified by transthoracic ECHO and the FC by the ET. Peripheral blood samples were collected to calculate the FRS. Normal ABI values were observed in 33 patients (82.5%), who were included in Group I; seven patients (17.5%) with abnormal ABI constituted Group II. Left ventricular mass index (LVMI) at the ECO were 111.18 ± 34.34 g/m2 (Group I) and 150.29 ± 34.06 g/m2 (Group II) (p = 0.009). The prevalence of LVH was 4% (Group I) and 35.3% (Group II) (p = 0.01), demonstrating a significant difference between the groups. As for the FC in ET, there was no difference between the groups. Regarding the FRS, the mean in Group I was below that in Group II: 13.18 ± 2.11 versus 15.28 ± 1.79 (p = 0.019). In hypertensive patients, the presence of LVH defined by the LVMI was more frequent in cases with abnormal ABI, identifying a higher cardiovascular risk.The ankle-brachial index (ABI) is a marker of peripheral arterial disease. Very few reports have correlated this index with left ventricular hypertrophy (LVH), functional capacity (FC) and Framingham risk score (FRS). The objective of this study was to verify the correlation between ABI, LVH, FC and FRS in men with arterial hypertension (AH). Prospective and cross-sectional study of male patients (n = 40) with a mean age of 57.92 ± 7.61 years and no cardiovascular complications. This population was submitted to ABI measurements, echocardiography (ECHO), exercise test (ET) and laboratory tests. The ABI (right and left) was considered abnormal when the ratio between the highest mean systolic pressures of the ankles and arms was 0.9 or higher than 1.3 mmHg. LVH was identified by transthoracic ECHO and the FC by the ET. Peripheral blood samples were collected to calculate the FRS. Normal ABI values were observed in 33 patients (82.5%), who were included in Group I; seven patients (17.5%) with abnormal ABI constituted Group II. Left ventricular mass index (LVMI) at the ECO were 111.18 ± 34.34 g/m(2) (Group I) and 150.29 ± 34.06 g/m(2) (Group II) (p = 0.009). The prevalence of LVH was 4% (Group I) and 35.3% (Group II) (p = 0.01), demonstrating a significant difference between the groups. As for the FC in ET, there was no difference between the groups. Regarding the FRS, the mean in Group I was below that in Group II: 13.18 ± 2.11 versus 15.28 ± 1.79 (p = 0.019). In hypertensive patients, the presence of LVH defined by the LVMI was more frequent in cases with abnormal ABI, identifying a higher cardiovascular risk.

Immediate effects of submaximal effort on pulse wave velocity in patients with Marfan syndrome

BACKGROUND: Predischarge exercise testing early after myocardial infarction is useful for risk stratification, exercise prescription, and assessment of prognosis and treatment. OBJECTIVE: The objective of this study was to compare the findings of exercise testing early after myocardial infarction with those of echocardiography, electrocardiographic monitoring (24-hour Holter monitoring) and coronary angiography. METHODS: We evaluated 60 cases (mean age of 51.42 ± 9.34 years), of which 46 were males (77%). The symptom-limited maximal exercise test according to the Naughton protocol12 was performed between the sixth day of hospitalization and hospital discharge, with the patients on medication. During hospitalization, the patients underwent echocardiography, electrocardiographic monitoring and coronary angiography. The significance level was set at 0.05 (a = 5%). RESULTS: Exercise testing had a poor performance in the detection of multivessel coronary artery disease (sensitivity, 42%; specificity, 69%). No significant differences were found when the presence of ischemia on exercise test was compared with multivessel coronary disease, complex ventricular arrhythmias on electrocardiographic monitoring, and the finding of an ejection fraction lower than 60% on echocardiography (p = 0.56), as well as with the presence of multivessel lesions, complex ventricular arrhythmias on electrocardiographic monitoring and abnormal ejection fraction on echocardiography (p = 0.36). CONCLUSION: The presence of ischemia during exercise testing was associated with the occurrence of ventricular arrhythmias on electrocardiographic monitoring, with reduced ejection fraction on echocardiography, as well as with the presence of multivessel coronary lesions, which constitutes an indicator of a high coronary risk.