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JEPonline

Effects of Abdominal Exercises in the Blood Pressure and Autonomic Indexes in Healthy Young Adults

Raphael M. Cunha1, Raphael G. Parente1, Paulo J.D.C. Jaime1, Mayara C.C. Souza1, Ademar A. Soares Júnior1, Tiago P. Oliveira2, Daniel Umpierre3

¹Exercise Physiology Laboratory (LAFEX /ESEFFEGO) UEG/Brazil, ²Laboratory of Motor Assessment (LAM / UFJF) – UFJF/Brazil,³Exercise Pathophysiology Research Laboratory – UFRGS/Brazil

ABSTRACT

Cunha RM, Parente RG, Jaime PJDC, Souza MCC, Júnior AAS, Oliveira TP, Umpierre D. Effects of Abdominal Exercises in the Blood Pressure and Autonomic Indexes in Healthy Young Adults.JEPonline2014;17(1):40-49. The purpose of the present study was to compare the blood pressure (BP) as well as the autonomic responses during different types of abdominal exercises in 30 subjects (age 18 to 25 yrs of age) who performed an exercise session consisting of 3 types of abdominal exercises (straight partial sit-up - SPSU, oblique partial sit-up – OPSU, and lying hip flexion - LHF), 3 sets, 15 to 20 repetitions, and a control session with the identical experimental procedures but without exercise. Brachial BP was measured before, during, and after interventionat 5, 10, and 20 min. Heart rate variability (HRV) was assessed at baseline, during abdominal exercises, and in the post-intervention periods.Compared with baseline, systolic BP increased immediately after the SPSU, OPSU, and LHF exercises (P<0.001). Systolic BP and diastolic BP were not altered during the control session. In both sessions, BP was not affected in the post-intervention periods. In comparison with the control session, systolic BP increased 7.6%, 5.8%, and 7.6% after the SPSU, OPSU, and LHF exercises, respectively (P<0.001). Diastolic BP did not differ between sessions. After the LHF exercise, HRV was significantly decreased(P<0.05) when compared to the control session. In healthy subjects, abdominal exercises at low-to-moderate intensities induced small increases in BP, which was accompanied by a discrete decrease in HRV.

Key Words: Abdominal Muscles, Blood Pressure, Heart Rate

INTRODUCTION

Several studies have described the influence of aerobic and resistance exercises on blood pressure(BP) and autonomic responses (8,9,20,26,28,35). A typical aerobic exercise session, such as 45min of cycling at 70% of the maximal heart rate, increases the systolic blood pressure while maintains or reduces the diastolic blood pressure (14). Underlying the commonly observed increases in heart rate (HR), the cardiac autonomic responses are also affected by showing significant vagal withdrawal and up-regulated sympathetic outflow at the sinus node (27).

On the other hand, resistance exercises present mixed muscular efforts that are characterized not only by the dynamic component of muscle contractions that are similar to the aerobic stimulus, but also by an isometric component that is especially active whenever heavy loads are used. Depending on the level of this component, the increase in vascular resistance may be more pronounced, which may exacerbate the increase in blood pressure during exercise (15,30). Additionally, Heffernan et al. (11) found greater autonomic distress induced by resistance exercises. They reported greater values in HR and smaller values in heart rate variability (HRV) after a resistance exercise session that consisted of 3 sets of 10 repetitions of 10 resistance exercises compared to a 30-min aerobic session on a cycle ergometer.

While strong abdominal muscles contribute to the support and posture of the body, weak abdominal muscles are associated with low back pain(34). Given that a large percent of the population has weak abdominal muscles, it is common to exercise these muscles in exercise programs for both healthy and clinical settings (12,23,32,33). Previous studies (2,6) have indicated that abdominal exercises increase blood pressure, which is dramatically increased when the Valsalva maneuver is performed (6). Considering that patients with cardiovascular diseases such as hypertension and chronic heart failure experience impairments in autonomic balance (18,22), it would be clinically useful to determine the cardiac autonomic behavior during commonly used abdominal exercises (1). Thus, the purpose of the present study was to compare the BP as well as the autonomic responses during 3 types of different types of abdominal exercises in healthy subjects.

METHODS

Subjects

Thirty subjects(18 to 25 yrs of age) who were not engaged in regular exercise programs were recruited in this study. None of the subjects hadhigh blood pressure or overt cardiovascular disease. Exclusion criteria consisted of a body mass index ≥30 kg·m-2, diabetes mellitus, cardiac, renal or hepatic diseases, orthopedic limitations or any other limitations to perform exercises. The study protocol was approved by the Institutional Review Board of the General Hospital of Goiania (Registration Number, 070/11), which conforms to the provisions of the Declaration of Helsinki. All subjects read and signed the informed consent before participation in the study.

Procedures

This study included 3 visits to the Exercise Physiology Laboratory. On the first day, body mass, body fat, and height measurements were determined and, then, the subjects were familiarized with the proper abdominal exercise techniques. On different days, thesubjects performed two experimental protocols in a randomized order that carried out at the same time of the dayfollowing a 2-hr fast. The subjects were requested to not drink alcohol throughout their participation in the phases of the study.

Both the exercise session (ES) and the control session (CS) took place in a controlled temperature environment (22 to 24°C)at least 48 hrs apart. The ES consisted of 3 abdominal exercises performed on the floor in the supine position without the use of external devices. The 3 exercises consisted of: (a) straight partial sit-up (SPSU) (6); (b) oblique partial sit-up (OPSU) (6); and (c) lying hip flexion (LHF) (started out lying on the back with knees and hips flexed at ~90º, flexing thehips toleavethe floorslightly).

The ES consisted of abdominal exercises that are usually prescribed in rehabilitation and conditioning programs. Abdominal exercises 1 and 3 consisted of 3 sets of 15 repetitions. Movement 2 consisted of 3 sets of 20 repetitions (with 10 repetitions for each side). One-min intervals were allowed between the sets and the exercises. The subjects were asked to breathe continuously to avoid the Valsalva maneuver. In the CS, the subjects were lying down as during the ES but they did not perform the exercises.

Measurements

An automatic BP device (Omron 705CP®, Omron Healthcare, USA) was used to measure BP, which were based on the Seventh Report of the Joint National Committee on Prevention, Detection, Evaluation, and Treatment of High Blood Pressure (5). Baseline (resting)BP was measured after 10 min seated in a chair. Exercise BP was measured after each of the 3 exercises while lying on a mattress on the floor at 5, 10, and 20 min. Recovery BP was measured while seated in a chair.

Heart rate (HR) was continuously recorded using a HR monitor(Polar, RS 800 CX®, USA). In order to analyze HR and heart rate variability (HRV), data containing the time series of RR-interval (RRi) were exported to Matlab software (MathWorks, EUA). Initially, a third-order median filter operation was applied on RRi time series, where each discrepant value was replaced with the median of the value as well as the preceding and following values. The first and last values were not filtered by the median. Then, the filtered signal was divided according to each phase of the protocol (i.e., baseline, SPSU, OPSU, LHF, and 5-10, 10-15, and 15-20 min of recovery). For each window, the mean HR and the root mean square of successive differences in RR intervals (RMSSD) were calculated. Since the HR data were not stationary during the whole experimental sessions, we chose not to perform HRV analysis in the frequency domain (31).

Statistical Analyses

Values are expressed as mean ±standard error (SE). Data distribution was assessed by the Shapiro Wilk test. To compare hemodynamic responses during the exercise sessions, a two-way repeated measures analysis of variance (time and session) was used with the Newman–Keuls method to identify significant differences. A two-tailed P value of less than 0.05 was considered as statistically significant.

RESULTS

Although 30 subjects wereinitially included in the study, 11 did not complete the protocol. For these subjects, lack of time was indicated as the primary reason for dropping out of the study. Theresults therefore represent the data from the remaining 19 subjects (13 women and 6 men). As shown in Table 1, values for BMI and blood pressure were within the normal range for clinical purposes.

Table 1. Subject Characteristics.

Variables / Results
Age (yrs) / 20.9±2.3
Weight (kg) / 60.2±8.8
Height (m) / 1.67±0.09
BMI (kg·m-2) / 21.5±2.1
Body Fat (%) / 21.8±8.6
SBP at Rest (mmHg) / 108±10.5
DBP at Rest (mmHg) / 67±6.4

Values expressed as mean ± standard error.

In comparison with the ES baselineSBP of 110 mmHg, it increased 5.5%, 4.2%, and 7.3% after the SPSU, OPSU, and LHF abdominal exercises, respectively (P<0.001). During the recovery, the SBP responses were not significantly different from the ES baseline. In the CS, SBP did not differ significantly throughout the protocols when compared with baseline values. After the CS intervention, the SBP responses were not significantly different from the baseline. In comparison with the CS, SBP increased 7.6%, 5.8%, 7.6% during the SPSU, OPSU, and LHF exercises, respectively (P<0.001). Additionally, SBP was similar between both sessions at the post-intervention timepoints (recovery) (Figure 1). For the DBP responses, ES did not differ from CS throughout the protocols (Figure 2).

Figure 1.Systolic Blood Pressure Responses throughout the

Exercise and Control Session.

Figure 2. Diastolic Blood Pressure Responses throughout the

Exercise and Control Session.

Compared with baseline, the subjects’ HR responses were not significantly increased during the SPSU and OPSU exercises. However, the LHF exercise resulted in a significant increase of 6.7% in HR the baseline (P = 0.03). During the recovery phase of the ES exercise, the HR values were similar to the baseline at 5 min. When compared to the CS, HR during the ES was significantly increased during the 3 abdominal exercises. During the recovery, HR was not significantly different between the sessions (Figure 3).

Figure 3. Heart Rate Responses throughout the Exercise and

Control Session.

Figure 4 shows the RMSSD index during the experimental sessions. The RMSSD values of SPSU and OPSU exercises did not differ significantly from the baseline values or between sessions. However, during the LHF exercise, the RMSSD was significantly decreased compared with baseline and to the CS. During the recovery period, the RMSSD values were similar to baseline and also between sessions.

Figure 4. Heart Rate Variability Responses throughout the Exercise

and Control Session.

DISCUSSION

The present study indicates that common types of abdominal exercises performed at low-to-moderate intensity resulted inrelatively small increases in SBP, HR, and the RMSSD index. Although the subjects’ SBP response increased significantly during the exercises, the response was expectedgiven the increased hemodynamic demand caused by the exercise. During the recovery, the values returned to baseline values. The DBP did not change throughout the different conditions of the study.

Although previous studies have assessed blood pressure (13,15,24) and autonomic responses (10,11) during acute and chronic resistance training, there are only a few studies (2,6,25) that have assessed the cardiovascular responses during specific resistance exercises used for conditioning and rehabilitation purposes (2,6,25). Our data show that the increase in SBP was small, and it did not differ across the abdominal exercise type. This finding is in agreement with a previous study (6) with normotensive adults who performed 3 abdominal exercises with and without breath holding. Finnoff and colleagues (6) did not present SBP differences in abdominal exercises carried out without breath holding. This was also the case with Rao and Bellare (25) who reported on 21 females following muscular exercises for abdominal wall strengthening with similar increases in SBP after two different abdominal exercises. In contrast, Boone and Johns (2) evaluated the BP response after inversion abdominal exercise. They reported a significantly greater increase in BP, but comparison to the present study is made difficult by the specific methodology and position of the inverted subjects.

In disagreement with the previous studies (2,6,25), the present study did not observed significant changes in DBP values throughout the abdominal exercises. It is likely that two possible mechanisms are responsible for unexpected response in DBP during the abdominal exercises. First, the isometric component, which depends on exercise intensity, was insufficient to promote a significant increase in DBP. The second and more likely mechanism responsible for the DBP response is the fact that the measurements were performed immediately after each abdominal exercise. A rebound vasodilatation after each exercise cannot be ruled out (4).

Studies (17,26) have shown that a single resistance exercise session may reduce postexercise blood pressure in normotensive and hypertensive individuals. Since the abdominal exercises did not result in a significant decrease in blood pressureafter the 3-exercise protocols, it is possible that either a minimum amount of resistance exercises or a routine including different muscle groups is needed to promote postexercise hypotension. Additionally, traditional resistance training for the upper and lower limbs increases BP immediately after exercise (7,16,19). Nonetheless, comparisons with abdominal exercises are limited due to the distinct characteristics (i.e., given the supine position and low-to-moderate efforts).

Regarding the autonomic responses to the abdominal exercises, a small reduction of 0.5 ms (of RMSSD-logarithmic units) was observed in the vagal-related HRV index RMSSD. This finding occurred only during the LHF exercise. Interestingly, the small magnitudes in HR and HRV responses suggest that the acute and immediate effects of a 3-exercise abdominal routine may be safe for vulnerable populations (including but not limited to cardiac patients). Second, considering that the significant chronotropic effects appeared only during the 3rd exercise of the exercise protocol (LHF), it cannot be ruled out that the possible influence of additional exercises may have result in a more favorable effect on the cardiac autonomic responses. In fact, submaximal and maximal aerobic sessions and also supramaximal anaerobic and resistance sessions have been observed to produce a significant autonomic cardiovascular stress that is characterized by a prominent vagal reduction and increased sympathetic activity (3,11).

Overall, the exercise intensity used throughout the present study is likely the primary reason for the small changes in autonomic distress. Supporting this assumption, a previous study (29) has shown that, independently of the session duration, the postexercise HR and HRV dynamics were more affected after exercise protocols were performed at higher intensities. Other studies (3,21) have also demonstrated a reduction of HRV after maximal or supramaximal exertion. This reinforces the point that high exercise intensities may result in more consistent changes in HRV. Taken together, the present study seems to indicate the exercise prescription for vulnerable population may be started not only by low exercise intensities, but also by a limited amount of exercise within the same session.

Limitations of the Present Study

There are several limitations to the present study. First, blood pressure was not determined by way of intra-arterial or beat-by-beat measurements. Although it may affect the accuracy of the data, it is widely common to use the oscillometryin the clinical practice. Also, it appears to provide very useful information when the objective is to control blood pressure in different conditions. Second, the HRV measurements give only partial insight on the cardiac autonomic modulation during the abdominal exercise. Thus, it is important that the interpretation should be restricted to the type of exercise intervention used in the present study. It may not represent the neuromodulation in the peripheral vasculature. Finally, it is also possible that the RMSSD response might have been influenced by the breathing pattern.

CONCLUSIONS

Abdominal exercises of mild-to-moderate intensity result in significant but small increases in SBP. At the end of the 3-exercise routine, there was also a decrease in the RMSSD index from HRV. The latter finding indicates a reduction in the subjects’ vagal tone. Collectively, while the present results suggest that the abdominal exercise protocol may be used in rehabilitation programs, it is important to further evaluate the exercises when it comes to different clinical considerations.

ACKNOWLEDGMENTS

The authors thank Rhenan Bartels Ferreira for his support in statistical analyses. This work was supported in part by grants from FAPEG, Goiás, Brazil.

Address for correspondence:Raphael Martins Cunha. Exercise Physiology Laboratory - LAFEX /ESEFFEGO. State University of Goiás.Av. Anhanguera, n.1420, Vila Nova CEP:74.705-010, Goiânia- GO, Brasil, Email:

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