The effects of inspiratory muscle training on the interleukin-6 response to intense volitional hyperpnoea Source: Annual Congress 2012 - Clinical aspects and treatment of asthma and allergic respiratory diseases Year: 2012
The effects of inspiratory muscle training on breathing mechanics during fixed load cycling exercise Source: Annual Congress 2011 - Respiratory and skeletal muscle assessment in health and disease Year: 2011
Effects of maximal volitional hyperpnoea on exercise tolerance and locomotor muscle fatigue Source: International Congress 2018 – Mechanisms that underlie exercise limitation in various respiratory diseases Year: 2018
Effects of maximal volitional hyperpnoea on single-leg knee-extensor exercise tolerance Source: International Congress 2017 – Respiratory muscles: evaluation and pathophysiology Year: 2017
Respiratory muscle endurance training increases fatigue-resistance of expiratory muscles during exercise Source: Eur Respir J 2001; 18: Suppl. 33, 177s Year: 2001
The effects of pressure-threshold inspiratory load on lactate clearance after maximal exercise Source: Annual Congress 2011 - Innovative methods in exercise testing Year: 2011
Effects of combined tiotropium/olodaterol on inspiratory capacity and exercise endurance in COPD Source: Eur Respir J , 49 (4) 1601348; DOI: 10.1183/13993003.01348-2016 Year: 2017
A treadmill training following a cycloergometer training results in a further improvement of inspiratory muscle strenght in COPD patients Source: Eur Respir J 2003; 22: Suppl. 45, 55s Year: 2003
The effects of inspiratory muscle warm-up prior to inspiratory muscle training during pulmonary rehabilitation in subjects with COPD Source: Virtual Congress 2021 – Pulmonary rehabilitation in asthma and COPD Year: 2021
Respiratory muscle endurance training (RMET) with normocapnic hyperpnea (NH) improves ventilatory function and exercise performance in triathletes Source: Annual Congress 2012 - Exercise capacity: from elite athletes to severe impairment Year: 2012
Inspiratory muscle training (IMT) with normocapnic hyperpnea improves respiratory muscle strenght and exercise performance in COPD patients Source: Annual Congress 2010 - Exercise in COPD Year: 2010
Voluntary phasic activation-relaxation of expiratory muscles improves exercise endurance in patients with diaphragm dysfunction Source: Eur Respir J 2004; 24: Suppl. 48, 242s Year: 2004
The predictive validity of maximal inspiratory pressure for instantaneous improvements of exercise endurance resulting from inspiratory pressure support during exercise Source: Eur Respir J 2001; 18: Suppl. 33, 22s Year: 2001
Inspiratory muscle training increases elevated arm exercise endurance but not 6 minutes walk distance in the elderly Source: Eur Respir J 2006; 28: Suppl. 50, 284s Year: 2006
Comparison of controlled breathing and free breathing submaximal inspiratory endurance test in health individuals Source: Annual Congress 2008 - Respiratory mechanics, muscles and breathing; functional status measures and coping styles Year: 2008
Reproducibility of inspiratory capacity on healthy subjects during rest and submaximal exercise Source: Eur Respir J 2005; 26: Suppl. 49, 571s Year: 2005
Effects of prior self-control exertion on inspiratory muscle endurance, fatigue and dyspnoea Source: International Congress 2019 – Lung function and respiratory muscle testing Year: 2019
Hyperoxic effects on inspiratory muscle fatigue in cycling healthy humans Source: Annual Congress 2008 - Pulmonary mechanics and gas exchange Year: 2008
Eucapnic voluntary hyperpnea versus exercise challenge in identifying exercise induced bronchoconstriction in elite athletes Source: Eur Respir J 2005; 26: Suppl. 49, 371s Year: 2005
Inspiratory muscle warm-up does not improve cycling time trial performance Source: Annual Congress 2012 - Exercise capacity: from elite athletes to severe impairment Year: 2012