Respiratory muscle mechanics during inspiratory resistive breathing (IRB) assessed by optoelectronic plethysmography (OEP) Source: Annual Congress 2008 - Respiratory muscles in disease Year: 2008
Assessment of ventilatory mechanics in respiratory muscle weakness using structured light plethysmography Source: International Congress 2018 – New methods and concepts in tests of lung and respiratory muscle function Year: 2018
Respiratory muscles training with isocapnic hyperpnoea (hy) method improves ventilatory parameters and exercise capacity Source: Annual Congress 2009 - Gas exchange and exercise in respiratory diseases Year: 2009
Respiratory muscle activation, breathing pattern and respiratory muscle oxygen availability during Tapered Flow Resistive Loading and Normocapnic Hyperpnea in COPD. Source: International Congress 2019 – Assessment and training of respiratory muscles Year: 2019
Respiratory muscle training with normocapnic hyperpnoea (RMNH) improves ventilatory pattern, thoraco-abdominal coordination and reduces oxygen desaturation during exercise in COPD patients Source: International Congress 2014 – Mechanisms of exercise limitation in disease Year: 2014
Effects of rehabilitation on ventilatory mechanics in COPD patients measured by optoelectronic plethysmography Source: Eur Respir J 2005; 26: Suppl. 49, 720s Year: 2005
Blood flow does not redistribute from respiratory to leg muscles during exercise breathing heliox or oxygen in COPD Source: International Congress 2014 – Mechanisms of exercise limitation in disease Year: 2014
Respiratory muscle training (REMT) with normocapnic hyperpnoea (NH) improves respiratory muscle strength, exercise performance and ventilatory pattern in COPD patients Source: Annual Congress 2012 - Limiting factors in exercise 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
Inspiratory muscle training (IMT) with normocapnic hyperventilation (NH) improves respiratory muscle strength, exercise performance and ventilatory pattern in COPD patients Source: Annual Congress 2011 - Exercise assessment in different diseases Year: 2011
Circulatory effects of expiratory flow-limited exercise, dynamic hyperinflation and expiratory muscle pressure Source: Eur Respir Rev 2006; 15: 80-84 Year: 2006
Inspiratory muscle effort, perfusion and oxygenation responses to inspiratory muscle training (IMT) with Tapered Flow Resistive Loading (TFRL) and Normocapnic Hyperpnea (NH) in COPD. Source: International Congress 2018 – Muscle adaptations in response to physiotherapeutic interventions in acute and chronic settings Year: 2018
Different patterns of diaphragm breathing in COPD and healthy subjects assessed by optoelectronic plethysmography Source: Eur Respir J 2007; 30: Suppl. 51, 186s Year: 2007
Regional pulmonary ventilation during inspiratory muscles endurance test Source: Eur Respir J 2002; 20: Suppl. 38, 181s Year: 2002
Suprasternal pressure recording and respiratory inductance plethysmography for respiratory effort evaluation in patients with sleep-disordered breathing Source: International Congress 2018 – Diagnostics including questionnaires Year: 2018
The voluntary drive to breathe is not decreased in hypercapnic patients with severe COPD Source: Eur Respir J 2001; 18: 53-60 Year: 2001
Chest wall kinematics measured during inspiratory threshold loading, deep breathing maneuvers and CO2 rebreathing in individuals post-stroke. Source: International Congress 2018 – Respiratory muscles and lung function: from healthy subjects to patients Year: 2018
Anesthesia induced changes of respiratory mechanics in rats measured by impulse oscillometry Source: Annual Congress 2012 - Mechanics, muscles and movement: aspects of airway mechanics, repiratory muscle assessment and field exercise tests Year: 2012
Non-invasive measurements of dynamic hyperinflation and breathing pattern during exercise Source: Eur Respir J 2004; 24: Suppl. 48, 217s Year: 2004
Respiratory comfort in voluntary controllable mechanical lung ventilation is achieved with lower PETCO2 levels than in natural breathing, both in rest and in exercise Source: Annual Congress 2006 - Assessing the lungs in obstruction: technological advances in lung function testing Year: 2006