Resonances in the cardiovascular system caused by rhythmical muscle tension

Vaschillo, Evgeny; Vaschillo, Bronya; Pandina, Robert J.; Bates, Marsha E.

doi:10.1111/j.1469-8986.2010.01156.x

Cited by 46 publications

(43 citation statements)

References 55 publications

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“…Resonance is an occurrence in which an oscillation at a specific frequency appears in a system in response to perturbation (Vaschillo, Vaschillo, Pandina, & Bates, ). This principle has been applied to the cardiovascular (CV) system through the use of paced respiration at 6 breaths per min (i.e., 0.1 Hz, a dominant resonant frequency in the CV system), which produces cardiovascular resonance (i.e., large fluctuations in heart rate and blood pressure).…”

Section: Cardiovascular Resonancementioning

confidence: 99%

“…The 0.1 Hz resonant frequency of the CV system is thought to be due to the mechanisms of the arterial baroreflex (Vaschillo, Lehrer, Rishe, & Konstantinov, ; Vaschillo et al., ). Treatments that utilize paced breathing to amplify 0.1 Hz oscillations in heart rate and blood pressure have been shown to strengthen the baroreflex system (Lehrer et al., ).…”

Section: Cardiovascular Resonancementioning

confidence: 99%

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Positive emotion reduces dyspnea during slow paced breathing

Allen

Friedman

2012

Psychophysiology

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Slow breathing is used to induce cardiovascular resonance, a state associated with health benefits, but it can also increase tidal volume and associated dyspnea (respiratory discomfort). Dyspnea may be decreased by induced positive affect. In this study, 71 subjects (36 men, M = 20 years) breathed at 6 breaths per min. In condition one, subjects paced their breathing by inhaling and exhaling as a vertical bar moved up and down. In condition two, breathing was paced by a timed slideshow of positive images; subjects inhaled during a black screen and exhaled as the image appeared. Cardiac, respiratory, and self-reported dyspnea and emotional indices were recorded. Tidal volume and the intensity and unpleasantness of dyspnea were reduced when paced breathing was combined with pleasant images. These results show that positive affect can reduce dyspnea during slow paced breathing, and may have applications for induced cardiovascular resonance.

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Section: Cardiovascular Resonancementioning

confidence: 99%

Section: Cardiovascular Resonancementioning

confidence: 99%

Positive emotion reduces dyspnea during slow paced breathing

Allen

Friedman

2012

Psychophysiology

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“…Less recognized and understood, concurrent evidence also suggests that voluntary rhythmic muscle contraction alone could be an alternative way of stimulating the parasympathetic nervous system. In a study on rhythmic contraction alone, Lehrer et al demonstrated that when large muscle groups alternated rhythmically between contraction and relaxation, subjects experienced a similar parasympathetic entrainment effect observed in the earlier paced breathing studies (Lehrer, Vaschillo, Trost, & France, ; Vaschillo, Vaschillo, Pandina, & Bates, ). However, the autonomic effects of performing rhythmic synchronized breathing and muscle contraction tasks simultaneously have not been studied systematically.…”

Section: Introductionmentioning

confidence: 72%

Understanding mind–body disciplines: A pilot study of paced breathing and dynamic muscle contraction on autonomic nervous system reactivity

Chin

Kales

2019

Stress and Health

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Mind-body disciplines such as yoga, Tai Chi, and Qigong have been demonstrated to activate the parasympathetic nervous system, but it remains unclear how these practices achieve these results, whether by breathing, movement, or some combination.This pilot study establishes a model to examine the individual and combined effects of paced breathing and rhythmic skeletal muscle contraction on the activation of the parasympathetic system during a cognitive stressor. Male participants were randomly assigned to one of four preconditioning groups: (a) paced breathing alone, (b) alternating upper extremity muscle contractions, (c) paced breathing synchronized with alternating contractions, or (d) a neutral control task. Autonomic response was assessed by heart rate variability during a standardized cognitive stressor. The alternating contraction group had 71.7% higher activation of parasympathetic signal over respiration alone (p < .001). Alternating contractions synchronized with breathing demonstrated 150% higher parasympathetic activation than control (p < .0001).Comparing the contraction alone and synchronized groups, the synchronized group demonstrated 45.9% higher parasympathetic response during a cognitive stressor (p < .001). In conclusion, paced breathing synchronized with rhythmic muscle contraction leads to more resilient activation of the parasympathetic response than either alternating contractions or breathing alone, which may help explain the stress reducing benefits of mind-body disciplines. K E Y W O R D Sbiological mechanisms of stress, cardiovascular reactivity, psychophysiology, respite/recovery resilience, stress, mindfulness, stress management

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“…In this type of modeling, although relatively good matching between modeled and measured output heart rate values was achieved, it is difficult to relate transfer function parameters to actual physiological mechanisms underlying the phenomenon. Moreover, by calculating transfer functions between respiratory and heart rate signals, one can obtain useful information about resonance effects (Ahmed et al, 1986;Vaschillo et al, 2002Vaschillo et al, , 2011. In fact, transfer functions can be formally calculated for a wide variety of physiological or other type of signals, allowing the reconstruction of the output based on previous samples of input as well as of output.…”

Section: Discussionmentioning

confidence: 98%