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The oxygen cascade in patients treated with hemodialysis and native high-altitude dwellers: lessons from extreme physiology to benefit patients with end-stage renal disease

The oxygen cascade in patients treated with hemodialysis and native high-altitude dwellers: lessons from extreme physiology to benefit patients with end-stage renal disease
The oxygen cascade in patients treated with hemodialysis and native high-altitude dwellers: lessons from extreme physiology to benefit patients with end-stage renal disease

Patients treated with hemodialysis (HD) repeatedly undergo intradialytic low arterial oxygen saturation and low central venous oxygen saturation, reflecting an imbalance between upper body systemic oxygen supply and demand, which are associated with increased mortality. Abnormalities along the entire oxygen cascade, with impaired diffusive and convective oxygen transport, contribute to the reduced tissue oxygen supply. HD treatment impairs pulmonary gas exchange and reduces ventilatory drive, whereas ultrafiltration can reduce tissue perfusion due to a decline in cardiac output. In addition to these factors, capillary rarefaction and reduced mitochondrial efficacy can further affect the balance between cellular oxygen supply and demand. Whereas it has been convincingly demonstrated that a reduced perfusion of heart and brain during HD contributes to organ damage, the significance of systemic hypoxia remains uncertain, although it may contribute to oxidative stress, systemic inflammation, and accelerated senescence. These abnormalities along the oxygen cascade of patients treated with HD appear to be diametrically opposite to the situation in Tibetan highlanders and Sherpa, whose physiology adapted to the inescapable hypobaric hypoxia of their living environment over many generations. Their adaptation includes pulmonary, vascular, and metabolic alterations with enhanced capillary density, nitric oxide production, and mitochondrial efficacy without oxidative stress. Improving the tissue oxygen supply in patients treated with HD depends primarily on preventing hemodynamic instability by increasing dialysis time/frequency or prescribing cool dialysis. Whether dietary or pharmacological interventions, such as the administration of L-arginine, fermented food, nitrate, nuclear factor erythroid 2-related factor 2 agonists, or prolyl hydroxylase 2 inhibitors, improve clinical outcome in patients treated with HD warrants future research.

Acclimatization, Altitude, Animals, Biomarkers/blood, Hemodynamics, Humans, Hypoxia/blood, Kidney/metabolism, Kidney Failure, Chronic/blood, Oxygen/blood, Oxygen Consumption, Renal Dialysis/adverse effects, Risk Factors, Treatment Outcome
0363-6127
F249-F261
Kooman, Jeroen P
62ef4ff8-e51a-4723-9ae7-5b49c06a8882
Stenvinkel, Peter
2dc04f7f-fbe3-476e-9bb0-404ca75435b8
Shiels, Paul G
d08bdc90-2c36-4227-b244-5514bbf9d38e
Feelisch, Martin
8c1b9965-8614-4e85-b2c6-458a2e17eafd
Canaud, Bernard
8e72cbf1-ad81-4304-9a20-2f39a0682b5c
Kotanko, Peter
75ab6dc6-b38c-4618-8cb2-0cb61f1e75f3
Kooman, Jeroen P
62ef4ff8-e51a-4723-9ae7-5b49c06a8882
Stenvinkel, Peter
2dc04f7f-fbe3-476e-9bb0-404ca75435b8
Shiels, Paul G
d08bdc90-2c36-4227-b244-5514bbf9d38e
Feelisch, Martin
8c1b9965-8614-4e85-b2c6-458a2e17eafd
Canaud, Bernard
8e72cbf1-ad81-4304-9a20-2f39a0682b5c
Kotanko, Peter
75ab6dc6-b38c-4618-8cb2-0cb61f1e75f3

Kooman, Jeroen P, Stenvinkel, Peter, Shiels, Paul G, Feelisch, Martin, Canaud, Bernard and Kotanko, Peter (2021) The oxygen cascade in patients treated with hemodialysis and native high-altitude dwellers: lessons from extreme physiology to benefit patients with end-stage renal disease. American Journal of Physiology: Renal Physiology, 320 (3), F249-F261. (doi:10.1152/ajprenal.00540.2020).

Record type: Review

Abstract

Patients treated with hemodialysis (HD) repeatedly undergo intradialytic low arterial oxygen saturation and low central venous oxygen saturation, reflecting an imbalance between upper body systemic oxygen supply and demand, which are associated with increased mortality. Abnormalities along the entire oxygen cascade, with impaired diffusive and convective oxygen transport, contribute to the reduced tissue oxygen supply. HD treatment impairs pulmonary gas exchange and reduces ventilatory drive, whereas ultrafiltration can reduce tissue perfusion due to a decline in cardiac output. In addition to these factors, capillary rarefaction and reduced mitochondrial efficacy can further affect the balance between cellular oxygen supply and demand. Whereas it has been convincingly demonstrated that a reduced perfusion of heart and brain during HD contributes to organ damage, the significance of systemic hypoxia remains uncertain, although it may contribute to oxidative stress, systemic inflammation, and accelerated senescence. These abnormalities along the oxygen cascade of patients treated with HD appear to be diametrically opposite to the situation in Tibetan highlanders and Sherpa, whose physiology adapted to the inescapable hypobaric hypoxia of their living environment over many generations. Their adaptation includes pulmonary, vascular, and metabolic alterations with enhanced capillary density, nitric oxide production, and mitochondrial efficacy without oxidative stress. Improving the tissue oxygen supply in patients treated with HD depends primarily on preventing hemodynamic instability by increasing dialysis time/frequency or prescribing cool dialysis. Whether dietary or pharmacological interventions, such as the administration of L-arginine, fermented food, nitrate, nuclear factor erythroid 2-related factor 2 agonists, or prolyl hydroxylase 2 inhibitors, improve clinical outcome in patients treated with HD warrants future research.

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More information

Accepted/In Press date: 16 December 2020
Published date: 1 March 2021
Keywords: Acclimatization, Altitude, Animals, Biomarkers/blood, Hemodynamics, Humans, Hypoxia/blood, Kidney/metabolism, Kidney Failure, Chronic/blood, Oxygen/blood, Oxygen Consumption, Renal Dialysis/adverse effects, Risk Factors, Treatment Outcome

Identifiers

Local EPrints ID: 456299
URI: http://eprints.soton.ac.uk/id/eprint/456299
DOI: doi:10.1152/ajprenal.00540.2020
ISSN: 0363-6127
PURE UUID: b624b00d-3b29-4d74-8c24-e3490afcaf77
ORCID for Martin Feelisch: ORCID iD orcid.org/0000-0003-2320-1158

Catalogue record

Date deposited: 27 Apr 2022 02:07
Last modified: 17 Mar 2024 03:27

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Contributors

Author: Jeroen P Kooman
Author: Peter Stenvinkel
Author: Paul G Shiels
Author: Martin Feelisch ORCID iD
Author: Bernard Canaud
Author: Peter Kotanko

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