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Heart rate and cardiac autonomic responses to concomitant deep breathing, hand grip exercise, and circulatory occlusion in healthy young adult men and women

Abstract

Background

Deep breathing (DB) and handgrip (HG) exercise -with and without circulatory occlusion (OC) in muscle-, have been shown to have beneficial effects on cardiovascular function; however, the combination of these maneuvers on heart rate (HR) and cardiac sympathovagal balance have not been previously investigated. Therefore, the aim of the present study was to evaluate the effect of simultaneous DB, HG, and OC maneuvers on the sympathovagal balance in healthy women and men subjects.

Methods and results

Electrocardiogram and ventilation were measured in 20 healthy subjects (Women: n = 10; age = 27 ± 4 years; weight = 67.1 ± 8.4 kg; and height = 1.6 ± 0.1 m. Men: n = 10; age = 27 ± 3 years; weight = 77.5 ± 10.1 kg; and height = 1.7 ± 0.1 m) at baseline and during DB, DB + HG, or DB + HG + OC protocols. Heart rate (HR) and respiratory rate were continuously recorded, and spectral analysis of heart rate variability (HRV) were calculated to indirectly estimate cardiac autonomic function. Men and women showed similar HR responses to DB, DB + HG and DB + HG + OC. Men exhibited a significant HR decrease following DB + HG + OC protocol which was accompanied by an improvement in cardiac autonomic control evidenced by spectral changes in HRV towards parasympathetic predominance (HRV High frequency: 83.95 ± 1.45 vs. 81.87 ± 1.50 n.u., DB + HG + OC vs. baseline; p < 0.05). In women, there was a marked decrease in HR after completion of both DB + HG and DB + HG + OC tests which was accompanied by a significant increase in cardiac vagal tone (HRV High frequency: 85.29 ± 1.19 vs. 77.93 ± 0.92 n.u., DB + HG vs. baseline; p < 0.05). No adverse effects or discomfort were reported by men or women during experimental procedures. Independent of sex, combination of DB, HG, and OC was tolerable and resulted in decreases in resting HR and elevations in cardiac parasympathetic tone.

Conclusions

These data indicate that combined DB, HG and OC are effective in altering cardiac sympathovagal balance and reducing resting HR in healthy men and women.

Background

Sympathovagal imbalance is a common pathophysiological feature of many cardiovascular diseases, and thus an important target of therapeutic strategies [1]. Standard-of-care treatments for cardiovascular diseases have varying degrees of efficacy in attenuating sympathovagal imbalance and therefore additional pharmacological and/or non-pharmacological therapeutic options are desirable. Therefore, considering that autonomic imbalance is related to mortality and severity in different pathological conditions [2,3,4], studies looking at non-pharmacological and cost-effective strategies intended to improve cardiac autonomic fitness are needed.

Voluntary slow breathing exercises have been proposed as a potential non-pharmacological approach to improving outcomes in cardiovascular disease due to their effect on sympathovagal tone [5]. Voluntary slow breathing is generally characterized by decreased respiratory rate with increased respiratory amplitude. Previous studies have shown that a respiratory rate of ~ 0.1 Hz produces a strong entrainment of autonomic cardiovascular and respiratory rhythms as determined by spectral analysis of heart rate variability (HRV) [6]. The rhythmic entrainment and related salutary effects of deep breathing (DB) are likely mediated by activation of the Hering-Breuer reflex, related improvements in baroreflex sensitivity, and increased cardiac vagal tone and decreased cardiac sympathetic tone [6, 7]. While there is evidence that DB offers a non-pharmacological strategy to improve cardiac autonomic function [8], there are other non-pharmacological therapies that have been shown to have similar effects, such as isometric handgrip exercise [9].

Isometric exercise involves sustained contraction against an immovable load or resistance with no or minimal change in length of the involved muscle group. Importantly, it has been shown that this training modality produces significant and clinically meaningful reductions in heart rate (HR) and blood pressure (BP) [10], and better cardiovascular outcomes compared to dynamic aerobic and/or resistance exercise [10]. The beneficial effects of HG exercise on cardiovascular function are likely related to the activation of the mechano-metaboreflex during muscle contraction [8, 11, 12]. Mechanical compression and metabolite accumulation within the muscle tissue during HG stimulates mechano/metabo sensitive afferent fibers (groups III and IV) which promote sympathoexcitation and parasympathetic withdrawal [8, 11, 12]. Interestingly, it has been proposed that circulatory occlusion (OC) through external compression of muscle would likely elicit comparable effects on the neural regulation of cardiovascular function as the ones observed during HG exercise [12].

Despite the fact that several studies indicate DB, HG, and OC individually may exert similar salutary effects on autonomic control of cardiovascular function in physiological and pathophysiological states, there are currently no studies that have addressed the potential additive or synergistic effect of these approaches in combination. Therefore, the aim of the present study was to identify suitability and feasibility of the combination of DB, HG and OC as an affordable strategy to improve HR control through cardiac sympathovagal modulation. Gender differences on the effects of the combined maneuvers on cardiac sympathovagal balance were also determined.

Results

Body mass and body height were significantly different between men and women (p < 0.01); however, body mass index (BMI) was similar between groups (Table 1). Similarly, age, systolic blood pressure (SBP), diastolic BP (DBP), pulse pressure (PP), and mean arterial BP (MABP) were not different between groups (Table 1). In terms of physical activity, 40% of the total participants (n = 8) were classified as sedentary and 60% (n = 12) declared to participate in recreational exercise activities 3–4 times per week (70 and 50% of men and women, respectively). Based on BMI, subjects were classified as follows: 13 normal range (6 men and 7 women), 5 overweight (3 men and 2 women), and 2 obese (1 man and 1 woman). No women were taking oral contraceptives during the study (Table 1).

Table 1 Demographic and Cardiovascular characteristics of study participants

Effects of DB, DB + HG and DB + HG + OC on HR

HR is showed in Fig. 1. No significant differences were observed between men and women at baseline (68.2 ± 3.9 vs. 71.5 ± 4.3 beats/min, respectively) (Fig. 1A–C). Compared to resting values, both men and women displayed slight differences in HR during the recovery phases following interventions. Men showed a significant decrease in HR during recovery 3 (post DB + HG + OC) compared to baseline values (66.6 ± 3.4 vs 68.2 ± 3.9 beats/min, Recovery 3 vs. Baseline, respectively, statistical power (SP): 0.78) (Fig. 1B). In addition, a decrease in HR was observed during recovery 2 (post DB + HG) and recovery 3 in women (post DB + HG + OC) (69.3 ± 2.2 vs. 67.8 ± 1.7 vs. 71.5 ± 4.3 beats/min, respectively, SP: 0.68) (Fig. 1C).

Fig. 1
figure 1

Effect of deep breathing (DB), DB + hand grip (DB + HG) and DB + HG + circulatory occlusion (DB + HG + OC) on heart rate response. A Representative HR response during DB, DB + HG, and DB + HG + OC from one man and one woman. Note that the decrease of HR during recovery period was more pronounced in women than men. B Summary results of HR response during the different interventions in men. Note that HR during the recovery period 3 (post DB + HG + OC) was significantly different compared to the Baseline period. C Summary results of HR response during the different maneuvers in women. Note that the HR during recovery period 2 (DB + HG) and 3 (post DB + HG + OC) were significantly different compared to the Baseline period. Data analyzed by one-way ANOVA, followed by Holm-Sidak post hoc. *, p < 0.05; **, p < 0.01

Effects of DB, HG and OC on cardiac autonomic function

We evaluated cardiac autonomic function through heart rate variability (HRV) analysis, during baseline and the recovery period after DB + HG + OC in men. We found that low frequency to high frequency (LF/HF) ratio was significantly decreased during recovery compared to baseline values (0.21 ± 0.02 vs. 0.31 ± 0.07 LF/HF ratio, Recovery 3 vs. Baseline, respectively, SP: 0.86) (Fig. 2A and B). To determine the contribution of sympathetic and parasympathetic components of HRV to changes in sympathovagal balance, we evaluated each component separately (Fig. 2C). We found that the LF component of HRV was significantly reduced (LF: 17.62 ± 1.03 vs. 20.40 ± 3.49 n.u., Recovery 3 vs. Baseline, SP: 0.73) while the HF component was increased (HF: 83.95 ± 1.45 vs. 81.87 ± 1.50 n.u., Recovery 3 vs. Baseline, SP: 0.71) during the recovery period following DB + HG + OC (Fig. 2C). In addition, we evaluated the interindividual variability of LF and HF responses (Fig. 2D and E). Our data reveal that most of our subjects showed similar LF and HF spectral components during the measurement periods (Fig. 2D and E).

Fig. 2
figure 2

Effect of deep breathing (DB) + hand grip (DB + HG) + occlusion (DB + HG + OC) on heart rate variability (HRV) during recovery period 3 in men. A Representative time-varying spectrum of HRV during baseline period, DB + HG + OC and recovery period 3 from one man. Note that the power spectral density at low frequency (LF, 0.04–0.08 Hz) and high frequency (HF, 0.08–0.45 Hz) component of HRV, were decreased and increased, respectively, during recovery period 3 compared to the baseline. B Summary data of LF to HF ratio during baseline, DB + HG + OC, and during recovery period 3. Note that LF/HF ratio was significantly reduced in recovery period 3 compared to the baseline. C Summary data of LF and HF during baseline, DB + HG + OC, and during recovery period 3. D, E Interindividual response of LF and HF of HRV in men, respectively. Data analyzed by one-way ANOVA, followed by Holm-Sidak post hoc. *, p < 0.05; **, p < 0.01

Compared to men, DB + HG (recovery 2) was sufficient to elicit a significant reduction in chronotropy in women. After evaluating autonomic responses during recovery 2, we found that following DB + HG the LF/HF ratio was significantly reduced when compared to previous resting values (0.17 ± 0.02 vs. 0.37 ± 0.02 LF/HF ratio, Recovery 2 vs. Baseline, respectively, SP: 0.79) (Fig. 3A and B). Accordingly, spectral components showing the relative sympathetic and parasympathetic contribution to HRV were also significantly different during the recovery period after DB + HG (Fig. 3C). More specifically, the LF components were reduced (LF: 13.81 ± 1.26 vs. 22.09 ± 0.52 n.u., Recovery 2 vs. Baseline. SP: 0.82) while HF components were significantly increased during the recovery period following DB + HG (HF: 85.29 ± 1.19 vs. 77.93 ± 0.92 n.u., Recovery 2 vs. Baseline, SP: 0.79). Similar to what we observed in men, DB + HG had an effect on HRV spectral components in the recovery period (Fig. 3D and E).

Fig. 3
figure 3

Effect of deep breathing (DB) + hand grip (DB + HG) on heart rate variability (HRV) during recovery period 2 in women. A Representative time-varying spectrum of HRV during baseline period, DB + HG, and recovery period 2 from one woman. Note that the power spectral density at low frequency (LF, 0.04–0.08 Hz) and high frequency (HF, 0.08–0.45 Hz) component of HRV, were increased and decreased, respectively, during recovery period 2 compared to the baseline. B Summary data of LF to HF ratio during baseline, DB + HG and during recovery period 2. Note that LF/HF ratio was significantly reduced in recovery period 2 compared to the baseline. C Summary data of LF and HF during baseline, DB + HG, and during recovery period 2. D, E Interindividual response of LF and HF of HRV in men, respectively. Data analyzed via one-way ANOVA, followed by Holm-Sidak post hoc. *p < 0.05; ***p < 0.001

Discussion

In the present study we observed that: (i) women had a significant reduction in resting HR after DB + HG, which was more pronounced after DB + HG + OC, (ii) men had a reduction in resting HR only after the combination of DB + HG + OC, (iii) reductions in resting HR following intervention were accompanied by spectral shifts in HRV and, (iv) men and women both showed a predominance of vagal autonomic modulation of heart rate following DB + HG and DB + HG + OC. Considering the limited literature in the area, these results support the notion that the combination of these maneuvers may elicit beneficial reductions in resting HR and changes in cardiac sympathovagal balance, offering an readily available non-pharmacological strategy to help in cardiovascular improvements following disease-related autonomic failure.

The present study showed that the combination of two interventions was effective in reducing resting HR (study primary outcome) in a healthy population. Previous work has shown that slow breathing techniques decreases both resting HR and BP in humans with cardiovascular disease [6, 7]. Importantly, reductions in resting HR are closely related to a decreased risk of adverse cardiovascular events and all-cause mortality in patients with coronary heart disease and hypertension [7]. These salutary effects have been associated with improvements in cardiac autonomic modulation [7]. Here we reported that deep breathing strategies coupled with HG exercise with/without OC reduces resting HR and significantly shifts autonomic modulation of the heart towards parasympathetic predominance. Indeed, we observed a large increase in the parasympathetic modulation of HRV during the recovery period following DB + HG + OC in men and DB + HG in women. Thus, we speculate that in pathophysiological conditions, the combination of these strategies may offer a non-pharmacological approach to improve cardiovascular health and prognosis [6].

One of the principal mechanisms related to the beneficial cardiovascular effects of DB is activation of the baroreflex by stimulation of stretch receptors located in the aortic arch and carotid sinuses [13]. Arterial baroreceptors are activated by increases in BP which increase afferent neural discharge to central–neural–autonomic regions leading to heightened parasympathetic efferent activity through the vagus nerve to the sinoatrial (SA) node ultimately leading to decreases in HR [14]. Then, it is possible that fluctuations in intrathoracic pressure during expansion of the thorax results in fluctuations in venous filling, stroke volume, cardiac output, and peripheral blood flow (the respiratory pump) that contribute to a temporary rise in BP [15]. This in turn triggers parasympathetic activation and a subsequent decrease in HR. Importantly, studies on the effects of respiratory pattern on baroreflex function show that slow breathing at 0.1 Hz (with inspiration/expiration ratio of 1) increases baroreflex gain [16]. Unfortunately, we did not perform continuous BP recordings in our study to assess baroreflex sensitivity. Nevertheless, our data show that the HF component of HRV was markedly increased by deep breathing and isometric HG exercise. The latter has been shown to elicit brief hypertensive epochs secondary to sympathoexcitation [10, 17]. Indeed, HG exercise triggers post-exercise ischemia which in turn results in marked elevations in muscle sympathetic nerve activity, total peripheral resistance, and subsequently, BP [17]. Therefore, it is plausible that larger increases in BP may take place during concomitant deep breathing and repeated isometric muscle contractions resulting in a potentiated parasympathetic response to cope with the sympathoexcitation and pressor response elicited by DB and HG. In support of this notion, our data showed that DB and HG significantly reduced resting HR in women. However, men showed a significant reduction in resting HR only after DB and HG was coupled to OC (a more intensive stimuli for metaboreflex). The observed discrepancy between men and women may be associated with gender differences in baroreflex sensitivity [18]. Other factors may also account for gender-differences in our results like hormonal, nutritional and stress-related factors (i.e. anti-oxidant capacities). Accordingly, further studies are needed to address the contribution of baroreflex control of HR or any other factor that may contribute to the sex-differences observed in cardiac/autonomic responses following deep breathing and HG exercise.

Limitations

Our study provide evidence showing gender-related differences in the cardiac/autonomic responses to DB, HG and OC. Although we assessed the potential of these interventions in the short-term, long-term studies are needed to gain a clearer picture of their efficacy and tolerability in humans. Another limitation is that we used indirect techniques to assess cardiac autonomic function. With that said, it is important to mention that this technique has been widely used in the clinical setting due to its low cost and non-invasive nature [10, 19]. Future studies using sympathetic nerve recordings along with pharmacological interventions are required to fully understand the cardiovascular response to DB, HG and OC. Finally, other limitation of the study is the relatively small number of subjects in which we performed the experiments. The latter should be taken into account when thinking of applying these techniques into larger cohorts of subjects. Further studies enrolling more robust number of participants will be needed in the future to validate these interventions.

Conclusions

Our results indicate that concomitant DB + HG + OC reduces resting HR in men while DB + HG with and without OC were both effective to reduce resting HR in women. Also, DB + HG + OC in men and DB + HG in women induced marked shifts in HRV towards parasympathetic predominance. Together, these findings support the use of DB, HG and OC for cardiac autonomic modulation in healthy young adults.

Methods

This study was approved by the ethics committee of the corporation of rehabilitation Club de Leones Cruz del Sur (Punta Arenas, Chile) (#20190719). Participants were carefully informed about the experimental procedures and the possible risks and benefits associated with their participation in the study. An appropriate signed informed consent document was obtained from all participants in accordance with the Declaration of Helsinki.

Participants

Inclusion criteria for this study were as follows: (i) age between 20 and 35 years old; (ii) non-smoker; (iii) free of comorbidities including hypertension, diabetes, and heart failure; and (iv) free of arm lesions and/or arm surgeries in the 6 months prior to the study. Exclusion criteria were: (i) use of recreational drugs; (ii) taking any of the following medications: beta blockers, statins and/or any blood pressure reducing agents, anticonvulsant drug therapy, or any another drug that could influence the autonomic nervous system (i.e. Baclofen, valproic acid); (iii) pregnancy; and (iv) abnormal cardiac autonomic function at rest as determined by HRV analysis (low to high frequency ratio of HRV < 2.3) [20]. None of the participants declared to had participated in regular strength training or competitive sports activity in the 6-month period preceding the study. From 87 possible participants screened, 67 subjects were excluded, and 20 healthy individuals met the inclusion criteria and were enrolled in the study (Fig. 4). Women included in the study declared not to be under contraceptive treatment.

Fig. 4
figure 4

Flow chart illustrating allocation of participants and experimental description. Beginning with 87 potential participants, 67 were excluded from the study by inclusion/exclusion criteria and the study was carried out with 20 participants. From 20, 10 were men and 10 were women. After enrollment, subjects were familiarized to the procedures and body height, mass and BP were measured before the placement of ECG leads. Then, deep breathing (DB), DB + hand grip (DB + HG) and DB + HG + circulatory occlusion (DB + HG + OC) were performed in each experimental subject

Experimental procedures

All participants were familiarized with the experimental procedures one week before measurements were taken. All experimental procedures were done between 09:00 and 17:00 h in a noise-isolated room at 21–23 °C. Experimental procedures were always administered by the same qualified investigators in the same order to all participants (DB, DB + HG, DB + HG + OC). The day before experimental procedures, participants were instructed to: (i) sleep ~ 8 h and (ii) not consume coffee or other caffeine-containing beverages.

Prior to all experimental procedures, height, body mass, SBP, DBP, and 3-lead ECG were recorded. In all sessions and prior to exercises BP was determined using a sphygmomanometer (Tenso Medical Instruments Co, China) and a stethoscope (3 M, UK) by the same experienced physical therapist. MABP, PP, HR, and HRV were calculated. Height was measured using a wall-mounted stadiometer (HR-200, Tanita, Japan) and recorded to the nearest 0.1 cm. Body mass was measured to the nearest 0.1 kg using a digital scale (BF-350, Tanita, IL, USA). BMI was calculated and expressed as kg/m2.

Physiological experiments consisted of 5 min of seated baseline data, followed by 5 min of DB (0.1 Hz) [6, 21], followed by 5 min at rest (no paced breathing). Then, participants completed 5 min of DB + HG exercise (using their dominant hand) using a rehabilitation medical ball [10], followed by 5 min at rest. Lastly, participants completed 5 min of DB + HG (dominant hand) with a supra-systolic occlusion of their exercising dominant arm [12]. At the end of the 5 min period of DB + HG + OC, the occlusion band was released and a recovery period of 5 min was allowed. OC was attained by pumping the occlusion band to supra-systolic pressure and verified by complete disappearance of the index finger pulse wave [22].

Deep breathing (DB)

DB exercise was performed as previously described [23]. Briefly, participants were asked to wear a nose clip on their nose to occlude both nostrils. Then, they were instructed to breathe at a rate of 0.1 Hz for 5 min with the help of a digital metronome that set each breathing cycle [21]. ECG, HR, breathing movements, and respiratory rate (Rf) were recorded during the experiment using an analog–digital acquisition interface (PowerLab, AD Instruments, New Zealand).

Handgrip (HG) exercise and occlusion (OC)

HG exercise and OC protocols were performed as described previously [24]. Subjects were given a rehabilitation medical ball (TH9, anti-stress ball, EYESMKT®, Chile) and were asked to perform maximal HG exercise [10]. Following the DB (only) period, subjects exercised the dominant forearm through an isometric contraction of the medical ball while they continued to perform DB for 5 min. When finished, subjects were allowed to recover for 5 min before the last training session where they performed DB + HG and OC [12, 25]. For OC, each participant was subjected to supra-systolic occlusion of the exercising arm (occlusion band located at the muscle belly of the biceps) using a rehabilitation elastic band (192 and 7.5 cm, length and width, respectively: Occlusion Cuff®, UK). OC was maintained for 5 min while the subject performed DB and HG. Pulse wave recordings from the index finger of the dominant hand in the exercising arm was performed to confirm supra-systolic occlusion as evidenced by the complete disappearance of the pulse signal [26].

Electrocardiogram and ventilatory movements recordings

During all experimental procedures, ventilatory movements and a 3-lead ECG (35 min total time) were continuously recorded [27]. ECG electrodes were placed in DII lead according to Einthoven’s triangle with the positive electrode placed in the left leg, the negative electrode in the right hand and the ground electrode in the left arm [28, 29]. The ECG signal was low-pass (500 Hz) and high-pass (1000 Hz) filtered. The ventilatory movements were recorded with a thorax expansion device (AD Instruments, New Zealand). The inspiratory peak was used to calculate breathing rate. All recordings were digitalized and sampled at 1 kHz. HR and Rf were analyzed using Lab Chart Pro 8.0 software (AD Instruments, New Zealand).

Arterial blood pressure

Prior to experimental maneuvers, SBP and DBP were determined. From SBP and DBP, MABP (1/3 of SBP + 2/3 of DBP) and PP (SBP-DBP) were calculated. Measurements were determined using a sphygmomanometer (Tenso Medical Instruments Co, China) and a stethoscope (3 M, UK) by the same experienced investigator.

Heart rate variability (HRV)

HRV was used as an indirect measure of cardiac autonomic function [30]. From ECG recordings, RR time series were obtained, and spectral non-stationary analysis (1-min resolution) was used to obtain the power spectral density (PSD) of HRV during all experiments. Cut-off frequencies were defined as follows: very low frequency: DC-0.04; LFHRV: 0.04–0.08 Hz and HFHRV: 0.08–0.45 Hz [31]. Additionally, the LF/HFHRV ratio was calculated as an indicator of sympathovagal balance. LFHRV and HFHRV were expressed as normalized units (n.u.). Analysis was performed within a 35 min window using Kubios HRV Premium Software v3.1 (Kubios, Finland).

Statistical analysis

The independent variables were the different interventions (DB, HG, and OC) and the dependent variables were HR and HRV. Data is expressed as mean ± standard deviation (SD). All data were tested for normality (Shapiro–Wilk) and homoscedasticity (Levene). Data were evaluated as dictated by data structure using either an unpaired t-test or a repeated measures analysis of variance (ANOVA) (rest – DB – rest – DB + HG – rest – DB + HG + OC − recovery) followed by Holm-Sidak post-hoc analysis. Non-parametric variables were evaluated using Kruskal–Wallis analysis followed by Dunn´s post-test. The statistical power (SP, 1-β) for each significant comparison was also calculated considering arithmetic mean, standard deviation and number of subjects with an α < 0.05 (GPower, version 3.9.9.3, Dusseldorf, Germany) [32]. A p-value < 0.05 was considered statistically significant. All analyses were performed with GraphPad Prism 8.0 (La Jolla, CA).

Availability of data and materials

The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.

Abbreviations

DB:

Deep breathing

HG:

Hand grip

OC:

Occlusion

HR:

Heart rate

BP:

Blood pressure

SBP:

Systolic blood pressure

DBP:

Diastolic blood pressure

PP:

Pulse pressure

MABP:

Mean arterial blood pressure

HRV:

Heart rate variability

LF:

Low frequency

HF:

High frequency

SA:

Sinoatrial

ECG:

Electrocardiogram

Rf :

Respiratory frequency

PSD:

Power spectral density

SD:

Standard deviation

ANOVA:

Analysis of variance

SP:

Statistical power

BMI:

Body mass index

References

  1. Jordan J, Kurschat C, Reuter H. Arterial hypertension. Dtsch Arztebl Int. 2018;115(33–34):557–68.

    PubMed  PubMed Central  Google Scholar 

  2. DiBona GF. Sympathetic nervous system and hypertension. Hypertension. 2013;61(3):556–60.

    Article  CAS  Google Scholar 

  3. Carnagarin R, Lambert GW, Kiuchi MG, Nolde JM, Matthews VB, Eikelis N, et al. Effects of sympathetic modulation in metabolic disease. Ann N Y Acad Sci. 2019;1454(1):80–9.

    Article  Google Scholar 

  4. Diaz HS, Toledo C, Andrade DC, Marcus NJ, Del Rio R. Neuroinflammation in heart failure: new insights for an old disease. J Physiol. 2020;598(1):33–59.

    Article  CAS  Google Scholar 

  5. Critchley HD, Nicotra A, Chiesa PA, Nagai Y, Gray MA, Minati L, et al. Slow breathing and hypoxic challenge: cardiorespiratory consequences and their central neural substrates. PLoS One. 2015;10(5):e0127082.

  6. Sharma M, Frishman WH, Gandhi K. RESPeRATE: nonpharmacological treatment of hypertension. Cardiol Rev. 2011;19(2):47–51.

    Article  Google Scholar 

  7. Zou Y, Zhao X, Hou YY, Liu T, Wu Q, Huang YH, et al. Meta-analysis of effects of voluntary slow breathing exercises for control of heart rate and blood pressure in patients with cardiovascular diseases. Am J Cardiol. 2017;120(1):148–53.

    Article  Google Scholar 

  8. Matic Z, Platisa MM, Kalauzi A, Bojic T. Slow 0.1 Hz breathing and body posture induced perturbations of RRI and respiratory signal complexity and cardiorespiratory coupling. Front Physiol. 2020;11:24.

    Article  Google Scholar 

  9. Kamiya A, Michikami D, Fu Q, Niimi Y, Iwase S, Mano T, et al. Static handgrip exercise modifies arterial baroreflex control of vascular sympathetic outflow in humans. Am J Physiol Regul Integr Comp Physiol. 2001;281(4):R1134–9.

    Article  CAS  Google Scholar 

  10. Carlson DJ, Dieberg G, Hess NC, Millar PJ, Smart NA. Isometric exercise training for blood pressure management: a systematic review and meta-analysis. Mayo Clin Proc. 2014;89(3):327–34.

    Article  Google Scholar 

  11. Jin YZ, Yan S, Yuan WX. Effect of isometric handgrip training on resting blood pressure in adults: a meta-analysis of randomized controlled trials. J Sports Med Phys Fitness. 2017;57(1–2):154–60.

    PubMed  Google Scholar 

  12. Spranger MD, Krishnan AC, Levy PD, O’Leary DS, Smith SA. Blood flow restriction training and the exercise pressor reflex: a call for concern. Am J Physiol Heart Circ Physiol. 2015;309(9):H1440–52.

    Article  CAS  Google Scholar 

  13. Heusser K, Tank J, Engeli S, Diedrich A, Menne J, Eckert S, et al. Carotid baroreceptor stimulation, sympathetic activity, baroreflex function, and blood pressure in hypertensive patients. Hypertension. 2010;55(3):619–26.

    Article  CAS  Google Scholar 

  14. Kougias P, Weakley SM, Yao Q, Lin PH, Chen C. Arterial baroreceptors in the management of systemic hypertension. Med Sci Monit. 2010;16(1):RA1–8.

    PubMed  Google Scholar 

  15. Russo MA, Santarelli DM, O’Rourke D. The physiological effects of slow breathing in the healthy human. Breathe (Sheff). 2017;13(4):298–309.

    Article  Google Scholar 

  16. Wang YP, Kuo TB, Lai CT, Chu JW, Yang CC. Effects of respiratory time ratio on heart rate variability and spontaneous baroreflex sensitivity. J Appl Physiol (1985). 2013;115(11):1648–55.

    Article  Google Scholar 

  17. Credeur DP, Jones R, Stanford D, Stoner L, McCoy S, Jessee M. Central cardiovascular hemodynamic response to unilateral handgrip exercise with blood flow restriction. Eur J Appl Physiol. 2019;119(10):2255–63.

    Article  Google Scholar 

  18. Santa Cruz Chavez GC, Li BY, Glazebrook PA, Kunze DL, Schild JH. An afferent explanation for sexual dimorphism in the aortic baroreflex of rat. Am J Physiol Heart Circ Physiol. 2014;307(6):H910–21.

    Article  CAS  Google Scholar 

  19. Kowalewski MA, Urban M. Short- and long-term reproducibility of autonomic measures in supine and standing positions. Clin Sci (Lond). 2004;106(1):61–6.

    Article  CAS  Google Scholar 

  20. Nunan D, Sandercock GR, Brodie DA. A quantitative systematic review of normal values for short-term heart rate variability in healthy adults. Pacing Clin Electrophysiol. 2010;33(11):1407–17.

    Article  Google Scholar 

  21. Noble DJ, Hochman S. Hypothesis: pulmonary afferent activity patterns during slow, deep breathing contribute to the neural induction of physiological relaxation. Front Physiol. 2019;10:1176.

    Article  Google Scholar 

  22. Patterson SD, Hughes L, Warmington S, Burr J, Scott BR, Owens J, et al. Blood flow restriction exercise: considerations of methodology, application, and safety. Front Physiol. 2019;10:533.

    Article  Google Scholar 

  23. Peng CK, Henry IC, Mietus JE, Hausdorff JM, Khalsa G, Benson H, et al. Heart rate dynamics during three forms of meditation. Int J Cardiol. 2004;95(1):19–27.

    Article  Google Scholar 

  24. Crisafulli A, de Farias RR, Farinatti P, Lopes KG, Milia R, Sainas G, et al. Blood flow restriction training reduces blood pressure during exercise without affecting metaboreflex activity. Front Physiol. 2018;9:1736.

    Article  Google Scholar 

  25. Park SY, Kwak YS, Harveson A, Weavil JC, Seo KE. Low intensity resistance exercise training with blood flow restriction: insight into cardiovascular function, and skeletal muscle hypertrophy in humans. Korean J Physiol Pharmacol. 2015;19(3):191–6.

    Article  CAS  Google Scholar 

  26. Sprick JD, Rickards CA. Cyclical blood flow restriction resistance exercise: a potential parallel to remote ischemic preconditioning? Am J Physiol Regul Integr Comp Physiol. 2017;313(5):R507–17.

    Article  Google Scholar 

  27. Scott BR, Peiffer JJ, Thomas HJ, Marston KJ, Hill KD. Hemodynamic responses to low-load blood flow restriction and unrestricted high-load resistance exercise in older women. Front Physiol. 2018;9:1324.

    Article  Google Scholar 

  28. Samol A, Bischof K, Luani B, Pascut D, Wiemer M, Kaese S. Recording of bipolar multichannel ECGs by a smartwatch: modern ECG diagnostic 100 years after Einthoven. Sensors (Basel). 2019;19(13):2894.

    Article  Google Scholar 

  29. Barold SS. Willem Einthoven and the birth of clinical electrocardiography a hundred years ago. Card Electrophysiol Rev. 2003;7(1):99–104.

    Article  Google Scholar 

  30. Electrophysiology TFotESoCtNASoP. Heart Rate Variability. Circulation. 1996;93(5):1043–65.

  31. Shaffer F, Ginsberg JP. An overview of heart rate variability metrics and norms. Front Public Health. 2017;5:258.

    Article  Google Scholar 

  32. Faul F, Erdfelder E, Lang AG, Buchner A. G*Power 3: a flexible statistical power analysis program for the social, behavioral, and biomedical sciences. Behav Res Methods. 2007;39(2):175–91.

    Article  Google Scholar 

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Acknowledgements

We thank Carla Ramirez for her technical assistance during recording procedures.

Funding

This work was supported by FONDECYT 1180172 and the Basal Centre of Excellence in Aging and Regeneration (AFB 170005) and the special grant ‘Lithium in Health and Disease’ from the Sociedad Química y Minera de Chile (SQM).

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Authors

Contributions

DCA and CM, collected data, performed data analysis and contributed to the preparation of the manuscript. DCA, CM, CT, APR-G, NJM, FO, GM and PM performed data interpretation and contributed to the preparation of the manuscript. RDR contributed to the concept of the project, experimental design, data interpretation, and preparation of the manuscript. All authors approved the final version of the manuscript.

Corresponding author

Correspondence to Rodrigo Del Rio.

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Ethics approval and consent to participate

This study was approved by the ethics committee of the corporation of rehabilitation Club de Leones Cruz del Sur (Punta Arenas, Chile) (#20190719). Participants were carefully informed about the experimental procedures and the possible risks and benefits associated with their participation in the study. An appropriate signed informed consent document was obtained from all participants in accordance with the Declaration of Helsinki.

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The authors declare that they have no competing interests.

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Andrade, D.C., Melipillan, C., Toledo, C. et al. Heart rate and cardiac autonomic responses to concomitant deep breathing, hand grip exercise, and circulatory occlusion in healthy young adult men and women. Biol Res 54, 32 (2021). https://0-doi-org.brum.beds.ac.uk/10.1186/s40659-021-00355-1

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