Extreme hypoxia causing brady-arrythmias during apnea in elite breath-hold divers

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Extreme hypoxia causing brady-arrythmias during apnea in elite breath-hold divers. / Kjeld, Thomas; Isbrand, Anders Brenøe; Linnet, Katrine; Zerahn, Bo; Højberg, Jens; Hansen, Egon Godthaab; Gormsen, Lars Christian; Bejder, Jacob; Krag, Thomas; Vissing, John; Bøtker, Hans Erik; Arendrup, Henrik Christian.

In: Frontiers in Physiology, Vol. 12, 712573, 2021.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Kjeld, T, Isbrand, AB, Linnet, K, Zerahn, B, Højberg, J, Hansen, EG, Gormsen, LC, Bejder, J, Krag, T, Vissing, J, Bøtker, HE & Arendrup, HC 2021, 'Extreme hypoxia causing brady-arrythmias during apnea in elite breath-hold divers', Frontiers in Physiology, vol. 12, 712573. https://doi.org/10.3389/fphys.2021.712573

APA

Kjeld, T., Isbrand, A. B., Linnet, K., Zerahn, B., Højberg, J., Hansen, E. G., Gormsen, L. C., Bejder, J., Krag, T., Vissing, J., Bøtker, H. E., & Arendrup, H. C. (2021). Extreme hypoxia causing brady-arrythmias during apnea in elite breath-hold divers. Frontiers in Physiology, 12, [712573]. https://doi.org/10.3389/fphys.2021.712573

Vancouver

Kjeld T, Isbrand AB, Linnet K, Zerahn B, Højberg J, Hansen EG et al. Extreme hypoxia causing brady-arrythmias during apnea in elite breath-hold divers. Frontiers in Physiology. 2021;12. 712573. https://doi.org/10.3389/fphys.2021.712573

Author

Kjeld, Thomas ; Isbrand, Anders Brenøe ; Linnet, Katrine ; Zerahn, Bo ; Højberg, Jens ; Hansen, Egon Godthaab ; Gormsen, Lars Christian ; Bejder, Jacob ; Krag, Thomas ; Vissing, John ; Bøtker, Hans Erik ; Arendrup, Henrik Christian. / Extreme hypoxia causing brady-arrythmias during apnea in elite breath-hold divers. In: Frontiers in Physiology. 2021 ; Vol. 12.

Bibtex

@article{ae05c8994d4b4475a98176c1ff2da888,
title = "Extreme hypoxia causing brady-arrythmias during apnea in elite breath-hold divers",
abstract = "Introduction: The cardiac electrical conduction system is very sensitive to hypoglycemia and hypoxia, and the consequence may be brady-arrythmias. Weddell seals endure brady-arrythmias during their dives when desaturating to 3.2 kPa and elite breath-hold-divers (BHD), who share metabolic and cardiovascular adaptions including bradycardia with diving mammals, endure similar desaturation during maximum apnea. We hypothesized that hypoxia causes brady-arrythmias during maximum apnea in elite BHD. Hence, this study aimed to define the arterial blood glucose (Glu), peripheral saturation (SAT), heart rhythm (HR), and mean arterial blood pressure (MAP) of elite BHD during maximum apneas. Methods: HR was monitored with Direct-Current-Pads/ECG-lead-II and MAP and Glu from a radial arterial-catheter in nine BHD performing an immersed and head-down maximal static pool apnea after three warm-up apneas. SAT was monitored with a sensor on the neck of the subjects. On a separate day, a 12-lead-ECG-monitored maximum static apnea was repeated dry (n = 6). Results: During pool apnea of maximum duration (385 ± 70 s), SAT decreased from 99.6 ± 0.5 to 58.5 ± 5.5% (∼PaO2 4.8 ± 1.5 kPa, P < 0.001), while Glu increased from 5.8 ± 0.2 to 6.2 ± 0.2 mmol/l (P = 0.009). MAP increased from 103 ± 4 to 155 ± 6 mm Hg (P < 0.005). HR decreased to 46 ± 10 from 86 ± 14 beats/minute (P < 0.001). HR and MAP were unchanged after 3-4 min of apnea. During dry apnea (378 ± 31 s), HR decreased from 55 ± 4 to 40 ± 3 beats/minute (P = 0.031). Atrioventricular dissociation and junctional rhythm were observed both during pool and dry apneas. Conclusion: Our findings contrast with previous studies concluding that Glu decreases during apnea diving. We conclude during maximum apnea in elite BHD that (1) the diving reflex is maximized after 3-4 min, (2) increasing Glu may indicate lactate metabolism in accordance with our previous results, and (3) extreme hypoxia rather than hypoglycemia causes brady-arrythmias in elite BHD similar to diving mammals.",
keywords = "Faculty of Science, Junctional rhythm, Brady-arrythmia, Free-diving, Invasive blood pressure, hypoxia induced factor-1 (HIF-1), Atrioventricular block, Apnea and face immersion, Bradycardia",
author = "Thomas Kjeld and Isbrand, {Anders Bren{\o}e} and Katrine Linnet and Bo Zerahn and Jens H{\o}jberg and Hansen, {Egon Godthaab} and Gormsen, {Lars Christian} and Jacob Bejder and Thomas Krag and John Vissing and B{\o}tker, {Hans Erik} and Arendrup, {Henrik Christian}",
note = "Copyright {\textcopyright} 2021 Kjeld, Isbrand, Linnet, Zerahn, H{\o}jberg, Hansen, Gormsen, Bejder, Krag, Vissing, B{\o}tker and Arendrup.",
year = "2021",
doi = "10.3389/fphys.2021.712573",
language = "English",
volume = "12",
journal = "Frontiers in Physiology",
issn = "1664-042X",
publisher = "Frontiers Media S.A.",

}

RIS

TY - JOUR

T1 - Extreme hypoxia causing brady-arrythmias during apnea in elite breath-hold divers

AU - Kjeld, Thomas

AU - Isbrand, Anders Brenøe

AU - Linnet, Katrine

AU - Zerahn, Bo

AU - Højberg, Jens

AU - Hansen, Egon Godthaab

AU - Gormsen, Lars Christian

AU - Bejder, Jacob

AU - Krag, Thomas

AU - Vissing, John

AU - Bøtker, Hans Erik

AU - Arendrup, Henrik Christian

N1 - Copyright © 2021 Kjeld, Isbrand, Linnet, Zerahn, Højberg, Hansen, Gormsen, Bejder, Krag, Vissing, Bøtker and Arendrup.

PY - 2021

Y1 - 2021

N2 - Introduction: The cardiac electrical conduction system is very sensitive to hypoglycemia and hypoxia, and the consequence may be brady-arrythmias. Weddell seals endure brady-arrythmias during their dives when desaturating to 3.2 kPa and elite breath-hold-divers (BHD), who share metabolic and cardiovascular adaptions including bradycardia with diving mammals, endure similar desaturation during maximum apnea. We hypothesized that hypoxia causes brady-arrythmias during maximum apnea in elite BHD. Hence, this study aimed to define the arterial blood glucose (Glu), peripheral saturation (SAT), heart rhythm (HR), and mean arterial blood pressure (MAP) of elite BHD during maximum apneas. Methods: HR was monitored with Direct-Current-Pads/ECG-lead-II and MAP and Glu from a radial arterial-catheter in nine BHD performing an immersed and head-down maximal static pool apnea after three warm-up apneas. SAT was monitored with a sensor on the neck of the subjects. On a separate day, a 12-lead-ECG-monitored maximum static apnea was repeated dry (n = 6). Results: During pool apnea of maximum duration (385 ± 70 s), SAT decreased from 99.6 ± 0.5 to 58.5 ± 5.5% (∼PaO2 4.8 ± 1.5 kPa, P < 0.001), while Glu increased from 5.8 ± 0.2 to 6.2 ± 0.2 mmol/l (P = 0.009). MAP increased from 103 ± 4 to 155 ± 6 mm Hg (P < 0.005). HR decreased to 46 ± 10 from 86 ± 14 beats/minute (P < 0.001). HR and MAP were unchanged after 3-4 min of apnea. During dry apnea (378 ± 31 s), HR decreased from 55 ± 4 to 40 ± 3 beats/minute (P = 0.031). Atrioventricular dissociation and junctional rhythm were observed both during pool and dry apneas. Conclusion: Our findings contrast with previous studies concluding that Glu decreases during apnea diving. We conclude during maximum apnea in elite BHD that (1) the diving reflex is maximized after 3-4 min, (2) increasing Glu may indicate lactate metabolism in accordance with our previous results, and (3) extreme hypoxia rather than hypoglycemia causes brady-arrythmias in elite BHD similar to diving mammals.

AB - Introduction: The cardiac electrical conduction system is very sensitive to hypoglycemia and hypoxia, and the consequence may be brady-arrythmias. Weddell seals endure brady-arrythmias during their dives when desaturating to 3.2 kPa and elite breath-hold-divers (BHD), who share metabolic and cardiovascular adaptions including bradycardia with diving mammals, endure similar desaturation during maximum apnea. We hypothesized that hypoxia causes brady-arrythmias during maximum apnea in elite BHD. Hence, this study aimed to define the arterial blood glucose (Glu), peripheral saturation (SAT), heart rhythm (HR), and mean arterial blood pressure (MAP) of elite BHD during maximum apneas. Methods: HR was monitored with Direct-Current-Pads/ECG-lead-II and MAP and Glu from a radial arterial-catheter in nine BHD performing an immersed and head-down maximal static pool apnea after three warm-up apneas. SAT was monitored with a sensor on the neck of the subjects. On a separate day, a 12-lead-ECG-monitored maximum static apnea was repeated dry (n = 6). Results: During pool apnea of maximum duration (385 ± 70 s), SAT decreased from 99.6 ± 0.5 to 58.5 ± 5.5% (∼PaO2 4.8 ± 1.5 kPa, P < 0.001), while Glu increased from 5.8 ± 0.2 to 6.2 ± 0.2 mmol/l (P = 0.009). MAP increased from 103 ± 4 to 155 ± 6 mm Hg (P < 0.005). HR decreased to 46 ± 10 from 86 ± 14 beats/minute (P < 0.001). HR and MAP were unchanged after 3-4 min of apnea. During dry apnea (378 ± 31 s), HR decreased from 55 ± 4 to 40 ± 3 beats/minute (P = 0.031). Atrioventricular dissociation and junctional rhythm were observed both during pool and dry apneas. Conclusion: Our findings contrast with previous studies concluding that Glu decreases during apnea diving. We conclude during maximum apnea in elite BHD that (1) the diving reflex is maximized after 3-4 min, (2) increasing Glu may indicate lactate metabolism in accordance with our previous results, and (3) extreme hypoxia rather than hypoglycemia causes brady-arrythmias in elite BHD similar to diving mammals.

KW - Faculty of Science

KW - Junctional rhythm

KW - Brady-arrythmia

KW - Free-diving

KW - Invasive blood pressure

KW - hypoxia induced factor-1 (HIF-1)

KW - Atrioventricular block

KW - Apnea and face immersion

KW - Bradycardia

U2 - 10.3389/fphys.2021.712573

DO - 10.3389/fphys.2021.712573

M3 - Journal article

C2 - 34925050

VL - 12

JO - Frontiers in Physiology

JF - Frontiers in Physiology

SN - 1664-042X

M1 - 712573

ER -

ID: 287692198