Contribution of respiratory muscle blood flow to exercise‐induced diaphragmatic fatigue in trained cyclists

Vogiatzis, Ioannis; Athanasopoulos, Dimitris; Boushel, Robert; Guenette, Jordan A.; Koskolou, Maria; Vasilopoulou, Μaroula; Wagner, Harrieth; Roussos, Charis; Wagner, Peter D.; Zakynthinos, Spyros

doi:10.1113/jphysiol.2008.162768

Cited by 41 publications

(47 citation statements)

References 47 publications

(107 reference statements)

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“…3). Increased respiratory work, either by voluntarily increasing the tidal integral of transdiaphragmatic pressure or by hypoxiainduced hyperventilation, exacerbates diaphragm fatigue during exercise (Babcock et al, 1995;Vogiatzis et al, 2008). Diaphragm fatigue (and other respiratory muscle fatigue) is accompanied by metabolite accumulation and activation of unmyelinated group IV phrenic afferents (respiratory metaboreceptors) ; these in turn increase sympathetic nerve activity (St Croix et al, 2000) and activate the respiratory muscle metaboreflex (Hussain et al, 1991;Sheel et al, 2001Sheel et al, , 2002.…”

Section: Accelerated Peripheral Fatigue Development In Hypoxiamentioning

confidence: 99%

Fatigue and Exhaustion in Hypoxia: The Role of Cerebral Oxygenation

Fan

Kayser

2016

High Altitude Medicine & Biology

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Fan, Jui-Lin, and Bengt Kayser. Fatigue and exhaustion in hypoxia: the role of cerebral oxygenation. High Alt Med Biol. 17:72-84, 2016.-It is well established that ascent to high altitude is detrimental to one's aerobic capacity and exercise performance. However, despite more than a century of research on the effects of hypoxia on exercise performance, the underlying mechanisms remain incompletely understood. While the cessation of exercise, or the reduction of its intensity, at exhaustion, implies reduced motor recruitment by the central nervous system, the mechanisms leading up to this muscular derecruitment remain elusive. During exercise in normoxia and moderate hypoxia (∼1500-2500 m), peripheral fatigue and activation of muscle afferents probably play a major role in limiting exercise performance. Meanwhile, studies suggested that cerebral tissue deoxygenation may play a pivotal role in impairing aerobic capacity during exercise in more severe hypoxic conditions (∼4500-6000 m). However, recent studies using end-tidal CO2 clamping, to improve cerebral tissue oxygenation during exercise in hypoxia, failed to demonstrate an improvement in exercise performance. In light of these recent findings, which seem to contradict the hypothetical role of cerebral tissue deoxygenation as a performance limiting factor at high altitude, this short review aims to provide a critical reappraisal of the extant literature and ends exploring some potential avenues for further research in this field.

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Section: Accelerated Peripheral Fatigue Development In Hypoxiamentioning

confidence: 99%

Fatigue and Exhaustion in Hypoxia: The Role of Cerebral Oxygenation

Fan

Kayser

2016

High Altitude Medicine & Biology

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“…If the patient is breathing pure O 2 , real shunting is the only cause of hypoxaemia contributing to QS/QT. The value is normally zero, since significant shunting does not occur in normal lungs [1,26], but due to (random) errors, the calculation may reveal a value of perhaps 2-3%. Of interest, Thebesian venous drainage directly into the cavity of the left ventricle should add poorly saturated venous blood to arterial and act as a shunt.…”

Section: −1mentioning

confidence: 99%

The physiological basis of pulmonary gas exchange: implications for clinical interpretation of arterial blood gases

Wagner

2014

Eur Respir J

Self Cite

116

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Number 8 in the series "Physiology in respiratory medicine" Edited by R. Naeije, D. Chemla, A. Vonk-Noordegraaf and A.T. Dinh-Xuan Affiliation: Dept of Medicine, University of California, San Diego, La Jolla, CA, USA.Correspondence: Peter D. Wagner, Dept of Medicine, University of California, San Diego, 9500 Gilman Drive, La Jolla, CA 92093, USA. E-mail: pdwagner@ucsd.edu ABSTRACT The field of pulmonary gas exchange is mature, with the basic principles developed more than 60 years ago. Arterial blood gas measurements (tensions and concentrations of O 2 and CO 2 ) constitute a mainstay of clinical care to assess the degree of pulmonary gas exchange abnormality. However, the factors that dictate arterial blood gas values are often multifactorial and complex, with six different causes of hypoxaemia (inspiratory hypoxia, hypoventilation, ventilation/perfusion inequality, diffusion limitation, shunting and reduced mixed venous oxygenation) contributing variably to the arterial O 2 and CO 2 tension in any given patient. Blood gas values are then usually further affected by the body's abilities to compensate for gas exchange disturbances by three tactics (greater O 2 extraction, increasing ventilation and increasing cardiac output). This article explains the basic principles of gas exchange in health, mechanisms of altered gas exchange in disease, how the body compensates for abnormal gas exchange, and based on these principles, the tools available to interpret blood gas data and, quantitatively, to best understand the physiological state of each patient. This understanding is important because therapeutic intervention to improve abnormal gas exchange in any given patient needs to be based on the particular physiological mechanisms affecting gas exchange in that patient. @ERSpublications Understanding the physiological basis of pulmonary gas exchange can help guide therapeutic approaches to patients

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“…erector spinae, intercostal, multifidus, paravertebral, serratus anterior) were also investigated during cycling, back extension and bending forward. So far, NIRS has been applied for studying exercise-induced muscle damage [11,20], ergonomics/biomechanics [21], heterogeneity of muscle O 2 supply/demand [12,22], muscle activation [11,23], priming exercise [19,24], respiratory muscle blood flow/fatigue [25,26], the role of the brain in muscle fatigue [27,28], the time course of oxidative metabolism [6,29] and the effect of exercise training [30]. Owing to the restriction of the allocated space, this review article neglects an in-depth discussion of the 160 studies published in the last four years.…”

Section: Main Fields Of Near-infrared Spectroscopy Applications For Smentioning

confidence: 99%

The use of near-infrared spectroscopy in understanding skeletal muscle physiology: recent developments

Ferrari

Muthalib

Quaresima

2011

Phil. Trans. R. Soc. A.

339

347

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This article provides a snapshot of muscle near-infrared spectroscopy (NIRS) at the end of 2010 summarizing the recent literature, offering the present status and perspectives of the NIRS instrumentation and methods, describing the main NIRS studies on skeletal muscle physiology, posing open questions and outlining future directions. So far, different NIRS techniques (e.g. continuous-wave (CW) and spatially, time-and frequency-resolved spectroscopy) have been used for measuring muscle oxygenation during exercise. In the last four years, approximately 160 muscle NIRS articles have been published on different physiological aspects (primarily muscle oxygenation and haemodynamics) of several upper-and lower-limb muscle groups investigated by using mainly two-channel CW and spatially resolved spectroscopy commercial instruments. Unfortunately, in only 15 of these studies were the advantages of using multi-channel instruments exploited. There are still several open questions in the application of NIRS in muscle studies: (i) whether NIRS can be used in subjects with a large fat layer; (ii) the contribution of myoglobin desaturation to the NIRS signal during exercise; (iii) the effect of scattering changes during exercise; and (iv) the effect of changes in skin perfusion, particularly during prolonged exercise. Recommendations for instrumentation advancements and future muscle NIRS studies are provided.

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Contribution of respiratory muscle blood flow to exercise‐induced diaphragmatic fatigue in trained cyclists

Cited by 41 publications

References 47 publications

Fatigue and Exhaustion in Hypoxia: The Role of Cerebral Oxygenation

Fatigue and Exhaustion in Hypoxia: The Role of Cerebral Oxygenation

The physiological basis of pulmonary gas exchange: implications for clinical interpretation of arterial blood gases

The use of near-infrared spectroscopy in understanding skeletal muscle physiology: recent developments

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