Emma Mason, European Society of Cardiology
Cardiovascular patients should be cautious when exposed to high altitudes for leisure or work
An expedition to Mount Everest by Italian researchers has shown for the first time that blood pressure monitored over a 24-hour period rises progressively as people climb to higher altitudes. The researchers also found that while a drug used for lowering blood pressure, called telmisartan, was effective in counteracting the effects of altitude up to 3400 meters, it was not effective at 5400 meters above sea level – the height of the Everest base camp.
The study is published online Aug. 27 in the European Heart Journal, and its findings have implications not just for people who live, work or undertake recreational activities such as skiing and trekking at high altitudes, but also for people at lower altitudes who may be temporarily deprived of an adequate oxygen supply – a condition known as hypoxia. Hypoxia can lead to altitude sickness at high altitudes, but is also seen at sea level in people who suffer from sleep apnea when their breathing is temporarily interrupted by a blocked airway.
For the study, 13 of the 15 authors of the EHJ paper joined an expedition of 47 volunteers to the Mount Everest south base camp (altitude 5400 meters). They flew from Milan, Italy (altitude 120 meters) to Kathmandu, Nepal (1355 meters) where they stayed for three days. Then they went to Namche Bazaar (3400 meters) where they stayed for another three days before spending the next five days climbing to the Everest base camp where they stayed for 12 days.
During the expedition, the volunteers had their blood pressure taken in the conventional way over a five-minute period in the morning, but they also wore a device that measured their blood pressure every 15-20 minutes over a 24-hour period – giving readings for ambulatory blood pressure, which is a much more accurate measure of a person’s true blood pressure. It also has the advantage of being able to measure night-time blood pressure, which is normally 10-20% lower than daytime blood pressure, and which is a better predictor of outcome than other blood pressure measurements. When the blood pressure does not “dip” at night despite the person being asleep, this may indicate a problem in the regulation of the heart and blood vessels.
The participants were randomized to receive either 80 mg of a blood pressure lowering drug, telmisartan, or placebo. Telmisartan is known as an “angiotensin receptor blocker” (ARB) because it blocks the effects of a peptide called angiotensin II, which causes blood vessels to narrow. The researchers collected blood samples as well.
The researchers found that exposure to the very high altitude of 5400 meters was responsible for an increase of 14 mmHg in ambulatory systolic blood pressure and 10 mmHg in ambulatory diastolic blood pressure, averaged over a 24-hour period. They also found that telmisartan significantly reduced ambulatory blood pressure at sea level and at 3400 meters, while no effects could be seen soon after arriving at 5400 meters.
Professor Gianfranco Parati, professor of cardiovascular medicine at the University of Milano-Bicocca and Director of the Cardiology Research Laboratory at the Istituto Auxologico Italiano (Milan, Italy), who led the research, said:
“Our study provides the first systematic demonstration that exposure to progressively higher altitudes is associated with a progressive and marked increase in ambulatory blood pressure. The increase occurred immediately after the high altitude was reached, persisted during prolonged altitude exposure, was seen throughout the 24-hour period but was particularly pronounced at night when there was a reduction in the night-time ‘dip’, and disappeared after return to sea level. After reaching Everest base camp, the effect of high altitude was greater on systolic blood pressure in people aged 50 and over compared with younger people.
“The blood pressure increase seen with exposure to progressively more severe oxygen deprivation at higher altitude among volunteers in the placebo group and in both groups at 5400 meters may have implications for the management of patients with chronic diseases, including chronic heart failure in which breathing is interrupted periodically, acute worsening of chronic obstructive pulmonary disease, obstructive sleep apnea, and severe obesity. Together, these conditions affect more than 600 million people worldwide, making our results highly significant from a clinical perspective.
“This blood pressure increase is due to several factors, the most important being the effects of oxygen deprivation in increasing activity in the body’s sympathetic nervous system. This leads to the heart working harder and the peripheral blood vessels constricting.
“Our paper also provides the first demonstration of the efficacy at high altitude of one of the most common drugs used to treat high blood pressure. The ability of telmisartan in blocking the angiotensin II receptors is preserved during acute exposure to moderately high altitudes up to 3400 meters, but is impaired when people move to the very high altitudes of 5400 meters.
“At a practical level this implies that for people already being treated with angiotensin II receptor blockers such as telmisartan, the treatment will remain effective at altitudes reached by trekkers, climbers, skiers and workers, but will not work at very high altitudes where their blood pressure will probably become uncontrolled more easily.
“Our findings will also enable us to take appropriate action to warn cardiovascular patients of the need for caution whenever they are going to be exposed to high altitudes for leisure or work. In addition, this study emphasizes the importance of ambulatory blood pressure monitoring as compared to conventional blood pressure measurements in characterizing blood pressure levels in people’s real lives; this is particularly important when focusing on the effects of hypoxia, which can be much less evident at rest than during daily life activities.”