Breath‐Hold Diving

Fitz‐Clarke, John R.

doi:10.1002/cphy.c160008

Cited by 66 publications

(50 citation statements)

References 307 publications

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“…Surprisingly, in two subjects out of 6 (who had the same training and experience as the others), paO 2 was lower than predicted, 75 and 61 mmHg, respectively (Figure 3 ). We hypothesize that in these two subjects the lower than expected paO 2 was due to ventilation/perfusion mismatch and right-to-left intrapulmonary shunt due to atelectasis caused by the significant reduction in lung volume at 40 m (20% of the pre-dive volume), ( Fitz-Clarke, 2018 ). Blood flow through an atelectatic area would likely be augmented by pulmonary vasodilatation caused by the combination of immersion ( Cherry et al, 2009 ) and pulmonary vascular engorgement due to pressure differential between pulmonary blood vessels and alveolar gas as lung volume during descent approaches residual volume.…”

Section: Discussionmentioning

confidence: 85%

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Arterial Blood Gas Analysis in Breath-Hold Divers at Depth

et al. 2018

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The present study aimed to evaluate the partial pressure of arterial blood gases in breath-hold divers performing a submersion at 40 m. Eight breath-hold divers were enrolled for the trials held at “Y-40 THE DEEP JOY” pool (Montegrotto Terme, Padova, Italy). Prior to submersion, an arterial cannula in the radial artery of the non-dominant limb was positioned. All divers performed a sled-assisted breath-hold dive to 40 m. Three blood samplings occurred: at 10 min prior to submersion, at 40 m depth, and within 2 min after diver’s surfacing and after resuming normal ventilation. Blood samples were analyzed immediately on site. Six subjects completed the experiment, without diving-related problems. The theoretically predicted hyperoxia at the bottom was observed in 4 divers out of 6, while the other 2 experienced a reduction in the partial pressure of oxygen (paO2) at the bottom. There were no significant increases in arterial partial pressure of carbon dioxide (paCO2) at the end of descent in 4 of 6 divers, while in 2 divers paCO2 decreased. Arterial mean pH and mean bicarbonate (HCO3−) levels exhibited minor changes. There was a statistically significant increase in mean arterial lactate level after the exercise. Ours was the first attempt to verify real changes in blood gases at a depth of 40 m during a breath-hold descent in free-divers. We demonstrated that, at depth, relative hypoxemia can occur, presumably caused by lung compression. Also, hypercapnia exists at depth, to a lesser degree than would be expected from calculations, presumably because of pre-dive hyperventilation and carbon dioxide distribution in blood and tissues.

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Section: Discussionmentioning

confidence: 85%

“…Dynamic apnea: swimming a horizontal distance on a single breath of air while submerged, either with or without fins ( Fitz-Clarke, 2018 ).…”

Section: Introductionmentioning

confidence: 99%

Arterial Blood Gas Analysis in Breath-Hold Divers at Depth

et al. 2018

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“…The drop in HR during breath holding would be due to an oxygenconserving effect that aims at maintaining perfusion to the brain and at reducing cardiac work in order to lower the overall O 2 uptake [32,33]. This effect would be partly mediated by the degree of hypoxaemia through chemoreceptor stimulation [34].…”

Section: Discussionmentioning

confidence: 99%

Exercise with End-expiratory Breath Holding Induces Large Increase in Stroke Volume

et al. 2020

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Eight well-trained male cyclists participated in two testing sessions each including two sets of 10 cycle exercise bouts at 150% of maximal aerobic power. In the first session, subjects performed the exercise bouts with end-expiratory breath holding (EEBH) of maximal duration. Each exercise bout started at the onset of EEBH and ended at its release (mean duration: 9.6±0.9 s; range: 8.6–11.1 s). At the second testing session, subjects performed the exercise bouts (same duration as in the first session) with normal breathing. Heart rate, left ventricular stroke volume (LVSV), and cardiac output were continuously measured through bio-impedancemetry. Data were analysed for the 4 s preceding and following the end of each exercise bout. LVSV (peak values: 163±33 vs. 124±17 mL, p<0.01) was higher and heart rate lower both in the end phase and in the early recovery of the exercise bouts with EEBH as compared with exercise with normal breathing. Cardiac output was generally not different between exercise conditions. This study showed that performing maximal EEBH during high-intensity exercise led to a large increase in LVSV. This phenomenon is likely explained by greater left ventricular filling as a result of an augmented filling time and decreased right ventricular volume at peak EEBH.

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“…Increased vagal tone causes bradycardia, but increased sympathetic tone leads to ectopy. [16] Apart from static apnea, increased metabolic activity and oxygen consumption in muscles related to the use of extremities during dive performances such as dynamic apnea have been found to cause more hypoxemic stress in the body. The degree of hypoxemia is also associated with the development of arrhythmia.…”

Section: Discussionmentioning

confidence: 99%

Investigation of changes in electrocardiography before and after free diving

Kafes

Yüzbaşıoğlu²,

Demir

2020

Turkish Journal of Clinics and Laboratory

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Aim: To evaluate the electrocardiographic (ECG) parameters and hemodynamic parameters in predicting the development of arrhythmias after free diving static apnea performance and maximum breath hold. Material and Methods: Twenty-four volunteer athletes participating in the free diving competition in 2015 (19 males (79.2%) and 5 females (20.8%)) were included in the study. Peripheral O2 saturation (SpO2), heart rate (HR), ECG parameters (PR interval, QRS time, T wave amplitude, corrected QT time, presence of bandle branch block and new bandle branch block development, atrial premature beats, ventricular premature beats) were analyzed. Results: There was no statistically significant difference between before static apnea measurements (systolic blood pressure (SBP) 124.7 ± 10.8 mmHg, diastolic blood pressure (DBP) 76.5 ± 6.7 mmHg, heart rate (HR) 80.2 ± 13.4 beats / min, SpO2 97.1 ± 0.9%) and after performance (SBP 128.8 ± 13.6 mmHg DBP 78.0 ± 5.9 mmHg, HR 85.8, ± 16.5 beats / min and SpO2 96.7 ± 2.3%)(p = 0.175; p = 0.334; p = 0.104; p = 0.336, respectively). Conclusion: No significant changes were observed in ECG parameters, heart rate, saturation and blood pressure values evaluated after static apnea performance. These findings can be used to support that the risk of arrhythmia during static apnea does not persist after apnea has ended.

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Breath‐Hold Diving

Cited by 66 publications

References 307 publications

Arterial Blood Gas Analysis in Breath-Hold Divers at Depth

Arterial Blood Gas Analysis in Breath-Hold Divers at Depth

Exercise with End-expiratory Breath Holding Induces Large Increase in Stroke Volume

Investigation of changes in electrocardiography before and after free diving

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