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Physiopathology of High-Altitude Pulmonary Edema

Giuseppe Miserocchi

2024High Altitude Medicine & Biology8 citationsDOIOpen Access PDF

Abstract

26:1-12, 2025.-The air-blood barrier is well designed to accomplish the matching of gas diffusion with blood flow. This function is achieved by maintaining its thickness at ∼0.5 µm, a feature implying to keep extravascular lung water to the minimum. Exposure to hypobaric hypoxia, especially when associated with exercise, is a condition potentially leading to the development of the so-called high-altitude pulmonary edema (HAPE). This article presents a view of the physiopathology of HAPE by merging available data in humans exposed to high altitude with data from animal experimental approaches. A model is also presented to characterize HAPE nonsusceptible versus susceptible individuals based on the efficiency of alveolar-capillary oxygen uptake and estimated morphology of the air-blood barrier.

Topics & Concepts

High-altitude pulmonary edemaPathophysiologyPulmonary edemaMedicineAltitude (triangle)Altitude sicknessEffects of high altitude on humansCardiologyInternal medicineEdemaIntensive care medicineAnesthesiaLungAnatomyGeometryMathematicsHigh Altitude and HypoxiaNeuroscience of respiration and sleepTravel-related health issues
Physiopathology of High-Altitude Pulmonary Edema | Litcius