Clinical Trials Directory

Trials / Completed

CompletedNCT04915378

Hypoxia-altitude Testing to Predict Altitude Related Adverse Health Effects in Chronic Obstructive Pulmonary Disease (COPD) Patients

Does Hypoxia-altitude Testing at Lowland Predict Altitude Related Adverse Health Effects in COPD Patients Traveling to 3100m?

Status
Completed
Phase
Study type
Observational
Enrollment
75 (actual)
Sponsor
University of Zurich · Academic / Other
Sex
All
Age
35 Years – 75 Years
Healthy volunteers
Not accepted

Summary

The predictive value of the hypoxia altitude simulation test (HAST) or other baseline values to predict altitude-related adverse health effects (ARAHE) is not established. To address this gap, the main goals of this investigation will be 1) to evaluate the diagnostic accuracy of the HAST in identifying individuals that will experience ARAHE during altitude travel and 2) to establish prediction models incorporating other commonly assessed clinical characteristics either alone or in combination with the HAST as predictors of ARAHE in altitude travelers. Hypotheses: In lowlanders with COPD, a PaO2 \<6.6 kPa or another cutoff of PaO2 or SpO2 at the end of the HAST, at rest or during exertion and/or clinical variables including symptoms, pulmonary function indices, 6-min walk distance (6MWD), either alone or combined to a multivariable model, will predict ARAHE during a sojourn of 2 days at 3100m with accuracy greater than chance

Detailed description

Altitude or air travel has become increasingly popular for recreational and professional reasons. Chronic obstructive pulmonary disease (COPD) affects up to 12% of adults worldwide and is associated with progressive hypoxemia, especially during exercise, due to respiratory mechanical constraints, airway obstruction and increasing pulmonary hypertension (PH). COPD patients are at increased risk of ARAHE including acute mountain sickness (AMS) and severe hypoxemia. Factors assessed at lowland that would predict ARAHE of COPD patients exposed to a hypobaric hypoxic environment at altitude or during air travel would be highly warranted. During the HAST COPD-patients are exposed to an inspiratory oxygen fraction (FiO2) of 15.1% corresponding to an altitude of ≈ 2500m and this test was designed to predict deoxygenation at altitude. The predictive value of the HAST or other baseline values to predict ARAHE is not established. To address this gap, the main goals of this investigation will be 1) to evaluate the diagnostic accuracy of the HAST in identifying individuals that will experience ARAHE during altitude travel and 2) to establish prediction models incorporating other commonly assessed clinical characteristics either alone or in combination with the HAST as predictors of ARAHE in altitude travelers. For this diagnostic accuracy study, COPD-patients with an FEV1 40-80% predicted living \< 1000 m without severe hypoxemia (SpO2, \<92%), hypercapnia (PaCO2 \>6 kPa) or comorbidities will be recruited to traveling to and staying for two nights at 3100 m. At 760 m, the HAST will be performed, at 760 m and 3100 m symptoms, vital signs, SpO2, pulmonary function tests, 6MWD, sleep studies will be repetitively assessed. ARAHE will be defined if one of the following present: AMS with a Lake Louise questionnaire score \>4 including headache, or AMSc score ≥0.7, resting SpO2 \<80% \>30 min or \<75% for \>15 min; or exercise SpO2 \<75% for \>5 min accompanied by symptoms, any intercurrent illness including infections, hypertension, neurologic impairments, dyspnea or discomfort at rest requiring oxygen treatment, chest pain and/or ECG signs of cardiac ischemia.

Conditions

Interventions

TypeNameDescription
OTHERhypoxia altitude simulation test (HAST) at 760mNormobaric hypoxia at a FiO2 of 15.1% will be generated by the Everest Summit II altitude generator (Hypoxico Altitude Training Systems, Bickenbach, Germany) and delivered to the patients face via tubes and a tightly fitted mask. Patients will be seated comfortably in a chair and fitted with a full-face mask equipped with a one-way valve. After a baseline period of quiet rest of 5-10 min with ambient air breathing and installation of equipment, patients will breath the hypoxic air mixture via a tightly fitted facial mask. They will be monitored with a finger-tip pulseoximetry to continuously assess SpO2 and heart rate. After at least 15' and steady-state values of the SpO2 (±1%) for at least 5' arterial blood gases will be drawn from a radial artery and immediately analyzed (RapidPoint 500, Siemens, Zürich, Switzerland).
PROCEDUREHigh Altitude (3100m)High Altitude (3100m) exposure for 2 days

Timeline

Start date
2021-06-01
Primary completion
2021-09-01
Completion
2022-05-31
First posted
2021-06-07
Last updated
2022-06-27

Locations

1 site across 1 country: Kyrgyzstan

Source: ClinicalTrials.gov record NCT04915378. Inclusion in this directory is not an endorsement.