Stéphanie Saxer

Effect of breathing oxygen-enriched air on exercise performance in patients with precapillary pulmonary hypertension: randomized, sham-controlled cross-over trial

Aims The purpose of the current trial was to test the hypothesis that breathing oxygen-enriched air increases exercise performance of patients with pulmonary arterial or chronic thrombo-embolic pulmonary hypertension (PAH/CTEPH) and to investigate involved mechanisms. Methods and results Twenty-two patients with PAH/CTEPH, eight women, means ± SD 61 ± 14 years, resting mPAP 35 ± 9mmHg, PaO2 ambient air >7.3 kPa, underwent four bicycle ergospirometries to exhaustion on different days, while breathing oxygen-enriched (FiO2 0.50, hyperoxia) or ambient air (FiO2 0.21, normoxia) using progressively increased or constant load protocols (with 75% maximal work rate under FiO2 0.21), according to a randomized, sham-controlled, single-blind, cross-over design. ECG, pulmonary gas-exchange, arterial blood gases, cerebral and quadriceps muscle tissue oxygenation (CTO and QMTO) by near-infrared spectroscopy were measured. In ramp exercise, maximal work rate increased from 113 ± 38 W with normoxia to 132 ± 48 W with hyperoxia, mean difference 19.7 (95% CI 10.5-28.9) W, P < 0.001. Constant load exercise endurance increased from 571 ± 443 to 1242 ± 514 s, mean difference 671 (95% CI 392-951) s, P < 0.001. At end-exercise with hyperoxia PaO2, CTO, QMTO, and PaCO2 were increased, and ventilatory equivalents for CO2 were reduced while the physiological dead space/tidal volume ratio remained unchanged. Conclusion In patients with PAH/CTEPH, breathing oxygen-enriched air provides major increases in exercise performance. This is related to an improved arterial oxygenation that promotes oxygen availability in muscles and brain and to a reduction of the excessive ventilatory response to exercise thereby enhancing ventilatory efficiency. Patients with PAH/CTEPH may therefore benefit from oxygen therapy during daily physical activities and training. Trial registration clinicaltrials.gov Identifier: NCT01748474.

Mechanisms of Improved Exercise Performance under Hyperoxia

Background: The impact of hyperoxia on exercise limitation is still incompletely understood. Objectives: We investigated to which extent breathing hyperoxia enhances the exercise performance of healthy subjects and which physiologic mechanisms are involved. Methods: A total of 32 healthy volunteers (43 ± 15 years, 12 women) performed 4 bicycle exercise tests to exhaustion with ramp and constant-load protocols (at 75% of the maximal workload [Wmax] on FiO2 0.21) on separate occasions while breathing ambient (FiO2 0.21) or oxygen-enriched air (FiO2 0.50) in a random, blinded order. Workload, endurance, gas exchange, pulse oximetry (SpO2), and cerebral (CTO) and quadriceps muscle tissue oxygenation (QMTO) were measured. Results: During the final 15 s of ramp exercising with FiO2 0.50, Wmax (mean ± SD 270 ± 80 W), SpO2 (99 ± 1%), and CTO (67 ± 9%) were higher and the Borg CR10 Scale dyspnea score was lower (4.8 ± 2.2) than the corresponding values with FiO2 0.21 (Wmax 257 ± 76 W, SpO2 96 ± 3%, CTO 61 ± 9%, and Borg CR10 Scale dyspnea score 5.7 ± 2.6, p < 0.05, all comparisons). In constant-load exercising with FiO2 0.50, endurance was longer than with FiO2 0.21 (16 min 22 s ± 7 min 39 s vs. 10 min 47 s ± 5 min 58 s). With FiO2 0.50, SpO2 (99 ± 0%) and QMTO (69 ± 8%) were higher than the corresponding isotime values to end-exercise with FiO2 0.21 (SpO2 96 ± 4%, QMTO 66 ± 9%), while minute ventilation was lower in hyperoxia (82 ± 18 vs. 93 ± 23 L/min, p < 0.05, all comparisons). Conclusion: In healthy subjects, hyperoxia increased maximal power output and endurance. It improved arterial, cerebral, and muscle tissue oxygenation, while minute ventilation and dyspnea perception were reduced. The findings suggest that hyperoxia enhanced cycling performance through a more efficient pulmonary gas exchange and a greater availability of oxygen to muscles and the brain (cerebral motor and sensory neurons).

Prevalence of Anxiety and Depression in Pulmonary Hypertension and Changes during Therapy

Background: Pulmonary hypertension (PH) leads to reduced health-related quality of life (HRQoL). Objective: To investigate the prevalence and course of anxiety and depression and their association with HRQoL, disease severity and survival in PH. Methods: 131 PH patients (91 pulmonary arterial, 30 chronic thromboembolic, 10 due to lung disease; 84 female, 47 male) had repeated assessments with the Hospital Anxiety and Depression Scale (HADS), HRQoL, six-minute walk distance and WHO functional class during a mean course of 16 ± 12 months. Results: Among the 49 incident and 82 prevalent PH patients, the HADS score was positive in 53%/21% (depression), 51%/24% (anxiety) and 63%/26% (total score) (all p < 0.05). The HADS score was improved at the second assessment in incident patients. The HADS score correlated with HRQoL at all consecutive assessments and with functional class until the third assessment, but not with baseline hemodynamics, age or gender. Conclusion: Mood disorders remain underdiagnosed in PH. The higher prevalence of anxiety/depression in incident versus prevalent patients and the improvement over time may indicate an amelioration of mood disorders after PH diagnosis and treatment.

Rehabilitation in patients with pulmonary arterial hypertension

Exertional dyspnoea is a leading symptom in patients with pulmonary arterial hypertension (PAH). Patients suffering from PAH report poor quality of life, have skeletal muscle dysfunction and in the absence of advanced medical therapy deteriorate progressively due to right heart failure which can lead to death. For decades, patients with PAH were advised to avoid exercise in fear of exacerbated right heart failure. Recently, it has been shown that a highly supervised rehabilitation programme in expert centres leads to significant improvements in symptoms, quality of life, exercise capacity and may even enhance haemodynamics in selected stable patients treated with advanced regimens of PAH-targeted drugs. As a consequence of these promising results, pulmonary rehabilitation performed in an expert centre has been included in recent guidelines. The underlying mechanisms are not completely understood, but positive effects can be measured in different organ systems such as skeletal muscles, the cardiopulmonary system and immune system (inflammation), and also on the psychological level. Thus, improvements in 6-minute walking distance (6MWD), peak oxygen uptake (VO2 peak), muscle strength and muscle endurance, as well as physical and mental quality of life scores (SF-36 questionnaire) have been shown. Different training protocols have been used. Essential are qualified patient selection in expert centres, a low workload endurance and dumbbell (weight lifting) training avoiding strenuous exercise and exhaustion, thorough patient education and close supervision by experts especially during the first weeks. Adverse events may occur (e.g., pre-/syncope, arrhythmia, respiratory infections). PAH patients tend to overestimate their physical capacity, not perceiving their own limits properly, which makes education and expert advice even more important as exercise training can also worsen the right heart failure. Therefore, a core issue of the multidisciplinary rehabilitation is the close cooperation between the experienced rehabilitation clinic offering a specialised programme for PAH patients and the PAH expert centre, which takes care of the patient and is thoroughly involved in the training programme. Further multicentre international randomised trials are needed to evaluate whether this specialised programme is feasible within different healthcare systems and to assess long term effects and survival.

Acute hemodynamic changes by breathing hypoxic and hyperoxic gas mixtures in pulmonary arterial and chronic thromboembolic pulmonary hypertension

BACKGROUND There is insufficient evidence to counsel patients with pulmonary hypertension undergoing altitude or air travel. We thus aimed to study hemodynamic response of patients with pulmonary arterial or chronic thromboembolic pulmonary hypertension (PAH/CTEPH) during changes in inspiratory oxygen partial pressure. METHODS AND RESULTS Consecutive patients undergoing right heart catheterization had hemodynamic assessments whilst breathing ambient air (normoxia, FiO2 0.21, at altitude 490 m), nitrogen-enriched air (hypoxia, FiO2 0.16, simulated altitude 2600 m) and oxygen (hyperoxia, FiO2 1.0), each for 10 min. Data from patients with PAH/CTEPH with mean pulmonary artery pressure (mPAP) ≥25 mmHg, pulmonary artery wedge pressure ≤15 mmHg, were compared to data from controls, mPAP <20 mmHg. 28 PAH/CTEPH-patients, 15 women, median age (quartiles) 62y (49;73), mPAP 35 mmHg (31;44), PaO2 7.1 kPa (6.8;9.3) and 16 controls, 12 women, 60y (52;69), mPAP 18 mmHg (16;18), PaO2 9.5 kPa (8.5;10.6) were included. Hypoxia reduced the PaO2 in PAH/CTEPH-patients by median of 2.3 kPa, in controls by 3.3 kPa, difference (95%CI) in change 1.0 (0.02 to 1.9), p < 0.05. Corresponding changes in pulmonary vascular resistance, mPAP and cardiac output were nonsignificant in both groups. Hyperoxia decreased mPAP in PAH/CTEPH-patients by 4 mmHg (2 to 6), in controls by 2 mmHg (0 to 3), difference in change 3 mmHg (0 to 5), p < 0.05. CONCLUSIONS In patients with PAH/CTEPH, very short-term exposure to moderate hypoxia similar to 2600 m altitude or during commercial air travel did not deteriorate hemodynamics. These results encourage studying the response of PAH/CTEPH during daytrips to the mountain or air travel.

Circulating MicroRNA Markers for Pulmonary Hypertension in Supervised Exercise Intervention and Nightly Oxygen Intervention

Rationale: Therapeutic exercise training has been shown to significantly improve pulmonary hypertension (PH), including 6-min walking distance and right heart function. Supplemental nightly oxygen also has therapeutic effects. A biomarker tool that could query critical gene networks would aid in understanding the molecular effects of the interventions. Methods: Paired bio-banked serum (n = 31) or plasma (n = 21) samples from the exercise or oxygen intervention studies, respectively, and bio-banked plasma samples (n = 20) from high altitude induced PH in cattle were tested. MicroRNAs (miRNAs) markers were chosen for study because they regulate gene expression, control the function of specific gene networks, and are conserved across species. Results: miRNAs that control muscle (miR-22-3p, miR-21-5p) or erythrocyte function (miR-451a) were chosen based on pilot experiments. Plasma samples from cattle that developed PH in high altitude had significantly higher miR-22-3p/(relative to) miR-451a values when compared to control cattle tolerant to high altitude. Measurements of miR-22-3p/miR-451a values in serum from patients receiving exercise training showed that the values were significantly decreased in 74.2% of the samples following intervention and significantly increased in the remainder (25.8%). In samples obtained after exercise intervention, a higher composite miRNA value, made of miR-22-3p and miR-21-5p/miR-451a and spike RNA, was significantly decreased in 65% of the samples and significantly increased in 35% of the samples. In the study of nightly oxygen intervention, when comparing placebo and oxygen, half of the samples showed a significant down-ward change and the other half a significant up-ward change measuring either of the miRNA markers. Samples that had a downward change in the miRNA marker following either intervention originated from patients who had a significantly higher 6-min-walking-distance at baseline (mean difference of 90 m or 80 m following exercise or oxygen intervention, respectively) when compared to samples that had an upward change in the miRNA marker. Conclusion: These natural animal model and human sample studies further highlight the utility of miRNAs as future biomarkers. The different directional changes of the miRNA markers following supervised exercise training or nightly oxygen intervention could indicate different PAH molecular pathomechanisms (endotypes). Further studies are needed to test this idea.

Risk Factor Profiles Achieved with Medical Therapy in Prevalent Patients with Pulmonary Arterial and Distal Chronic Thromboembolic Pulmonary Hypertension

Background: The latest pulmonary hypertension (PH) guidelines define therapeutic goals in terms of symptoms, exercise capacity, and haemodynamics for patients with pulmonary arterial hypertension (PAH) and recommend advanced combined medical therapy. For inoperable or post-surgical residual distal chronic thromboembolic PH (CTEPH) medical treatment is similarly advised. Objectives: We analysed whether risk factor goals are achieved and combination therapy is used in prevalent patients with PAH or distal CTEPH. Methods: PAH or distal CTEPH patients who were seen at the University Hospital Zurich during the last year were analysed in terms of demography, clinical data, medication, and therapeutic goals. Achievement of therapeutic goals was defined as New York Heart Association (NYHA) class ≤II, N-terminal pro-brain natriuretic peptide (NTproBNP) < 300 ng/L, and 6-min walking distance (6MWD) > 440 m. Results: A total of 108 PAH patients (age 59 ± 18 years, 62% female, 64% idiopathic, 36% associated) and 38 distal CTEPH patients (age 69 ± 14 years, 55% female) were included. They had been diagnosed on average 66 ± 48 months (±SD) previously. The percentage of PAH/CTEPH patients with NYHA ≤II was 52/53, respectfully, the percentage of those with NTproBNP < 300 ng/L was 61/52, and with 6MWD > 440 m 63/50. Overall, 33/31% fulfilled 3 and 29/35% fulfilled 2 of these goals. Regarding therapy, 43% of PAH patients were on double and 10% on triple combination therapy, whereas 16% of distal CTEPH patients were on double and 3% on triple combination therapy. Conclusions: In this real-life cohort of prevalent patients with PAH or distal CTEPH, targeted drug therapy resulted in an achievement of ≥2/3 predefined therapeutic goals in 2/3 of patients. Patients with PAH were more likely to receive combination therapy compared to CTEPH patients.

Right heart function and pulmonary pressure in asthma patients during 17 days at high-altitude

Objectives: Asthmatics may benefit from the climate at altitude. But the hypoxic environment may also be associated with adverse effects, e.g. right heart strain due to increased pulmonary artery pressure (PAP). We studied the right ventricular function (RVF) and SpO2 at lowland, after arrival at 3200m and after 17 days at that altitude in asthmatics. Methods: 22 asthmatics (living Results: The mPAP (mean±SD) was 13.5±5.4mmHg at 760m, 18.5±5.5mmHg after one and 18.2±5.5mmHg after 17 nights at 3200m (p Conclusions: In otherwise healthy asthmatics exposure to high altitude induces a significant increase in mPAP and heart rate with a decrease in SI resulting in an unchanged CI. During the 17 days at 3200m there is no further change in the indices of RVF despite increasing SpO2. Thus, respiratory acclimatization is more rapid than the one of the pulmonary circulation.

Asthma rehabilitation at high vs. low altitude: randomized controlled parallel-group trial

Allergens and pollution are reduced at altitude. We investigated the additive effect of asthma rehabilitation at high altitude (Tuja Ashu, 3200m, HA) compared to the same rehabilitation at low altitude (Bishkek, 760m, LA) on asthma control. For this randomized controlled trial adult asthmatics diagnosed according to GINA living in the Bishkek area ( .05), difference ‑5(‑13.6 to 5.0)%. ACQ was reduced at HA vs. LA by -1.1(-1.3 to -0.7, p .05) vs. -0.9(-1.3 to -0.3, p Asthma rehabilitation is highly effective in improving asthma control in terms of PEF-variability and symptoms, both at LA and HA to a similar degree.