Clinical recommendations for high altitude exposure of individuals with pre-existing cardiovascular conditions

Parati, Gianfranco; Agostoni, Piergiuseppe; Basnyat, Buddha; Bilo, Grzegorz; Brugger, Hermann; Coca, António; Festi, Luigi; Giardini, Guido; Lironcurti, Alessandra; Luks, Andrew M.; Maggiorini, Marco; Modesti, Pietro Amedeo; Swenson, Erik R.; Williams, Bryan; Bärtsch, Peter; Torlasco, Camilla

doi:10.1093/eurheartj/ehx720

Cited by 135 publications

(82 citation statements)

References 47 publications

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“…However, the foremost factor underlying physiological responses to HA is the low atmospheric pressure and the consequent proportional reduction of oxygen partial pressure in the inspired air (hypobaric hypoxia; FIGURE 1). 1,2 This occurs even though the relative air composition remains the same as at sea level, with oxygen content being about 21%. The ensuing hypoxemia and tissue hypoxia trigger numerous regulatory mechanisms, which in most cases favor adaptation but may sometimes evolve into pathological conditions such as acute mountain sickness (AMS) or chronic mountain sickness (Monge disease).…”

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confidence: 97%

“…This raises several questions such as: 1) whether the effect of altitude exposure is the same as in healthy young people; 2) whether the extra burden imposed on the cardiovascular system to achieve acclimatization may be detrimental in these patients; and 3) whether treated hypertensive individuals should modify antihypertensive therapy to prevent excessive BP increase and, if yes, how. 2 Focusing on elderly individuals, it is widely accepted that BP increases with age because of the combined effect of atherosclerotic changes, large artery stiffening, renal function impairment, and arterial baroreflex dysfunction, with older people having on average higher systolic BP values than younger ones. 41,42 Few studies evaluated the effects of altitude exposure in the elderly, sometimes with conflicting results, and most of them focused on moderate altitude instead of HA.…”

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confidence: 99%

“…The topic of patients with preexisting cardiovascular conditions who wish to reach HA locations has been extensively discussed in a recent consensus statement of experts and scientific societies. 2 In fact, even if the increase in BP observed during HA exposure, although important, should not, per se, represent a risk for a healthy person, this may not necessarily be true for diseased individuals. For example, hypertensive patients may be more susceptible to normalizing BP increase at altitude for the metabolic demands imposed by exercise, BP trajectories of hypertensive lowlanders exercising at altitude are shifted upwards and become steeper compared with those observed at sea level.…”

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confidence: 99%

“…39,49 A summary of recently published practical recommendations for patients with hypertension who are planning an HA stay is presented in TABLE 1. 2 Conclusions The cardiovascular system responds to the challenge of HA exposure in a complex manner, usually leading to adaptation, but in some cases contributing to acute and chronic altitude -related pathological conditions. The responses of BP and of its regulatory mechanisms to HA are significantly modified by the duration of the exposure.…”

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confidence: 99%

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Blood pressure at high altitude: physiology and clinical implications

Bilo¹,

Caravita²,

Torlasco³

et al. 2019

Kardiologia Polska

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High altitude is a fascinating model of hypoxia effects on the human body, but it is also an extreme environment that directly influences millions of people who either travel to high altitude locations or live there permanently. A significant progress has been made over the past decades in the understanding of physiological background of responses to altitude, and recently, a number of studies regarding clinical aspects of high-altitude exposure have been published. In particular, more is known about the changes in systemic blood pressure (BP) in individuals exposed to high altitude as well as on the effects of antihypertensive drugs in this setting. The present article provides an overview of principal physiological and clinical aspects related to systemic BP control and its changes at high altitude, mainly during the acute exposure. The evidence on BP changes at rest and during exercise is discussed, as well as the underlying mechanisms and possible clinical implications.

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confidence: 97%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Blood pressure at high altitude: physiology and clinical implications

Bilo¹,

Caravita²,

Torlasco³

et al. 2019

Kardiologia Polska

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“…However, after a few days of acclimatization (3-5 days), the CO begins to decrease and returns to baseline level with a higher HR and a lower SV [7]. The increase in HR is mainly due to sympathetic activation [8], whereas the decrease in SV is attributed to a decrease in blood volume, an increase in mPAP, the impairment of myocardial relaxation and an increase in HR, all of which contribute to the altered filling patterns of both ventricles [9]. During these physiological processes, the change in HR seems to be a critical determinant of cardiac performance at HA.…”

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confidence: 99%

Effects of baseline heart rate at sea level on cardiac responses to high-altitude exposure

Tian

Liu

Yang

et al. 2020

Int J Cardiovasc Imaging

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High-altitude (HA) exposure has been widely considered as a cardiac stress, and associated with altered cardiac function. However, the characteristics of cardiac responses to HA exposure are unclear. In total, 240 healthy men were enrolled and ascended to 4100 m by bus within 7 days. Standard echocardiography and color tissue Doppler imaging were performed at sea level and at 4100 m. In all subjects, HA exposure increased HR [65 (59, 71) vs. 72 (63, 80) beats/min, p < 0.001] but decreased the stroke volume index (SVi) [35.5 (30.5, 42.3) vs. 32.9 (27.4, 39.5) ml/m 2 , p < 0.001], leading to an unchanged cardiac index (CI). Moreover, baseline HR was negatively correlated with HA exposure-induced changes in HR (r = − 0.410, p < 0.001) and CI (r = − 0.314, p < 0.001). Following HA exposure, subjects with lowest tertile of baseline HR showed an increased HR [56 (53, 58) vs. 65 (58, 73) beats/min, p < 0.001], left ventricular ejection fraction (LVEF) [61.7 (56.5, 68.0) vs. 66.1 (60.7, 71.5) %, p = 0.004] and mitral S′ velocity [5.8 ± 1.4 vs. 6.5 ± 1.9 cm/s, p = 0.040]. However, subjects with highest tertile of baseline HR showed an unchanged HR, LVEF and mitral S′ velocity, but a decreased E′ velocity [9.2 ± 2.0 vs. 8.4 ± 1.8 cm/s, p = 0.003]. Our findings indicate that baseline HR at sea level could determine cardiac responses to HA exposure; these responses were characterized by enhanced LV function in subjects with a low baseline HR and by reduced LV myocardial velocity in early diastole in subjects with a high baseline HR.

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Self‐care of heart failure patients: practical management recommendations from the Heart Failure Association of the European Society of Cardiology

Jaarsma

Hill

Bayés‐Genís

et al. 2020

European J of Heart Fail

206

178

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Self‐care is essential in the long‐term management of chronic heart failure. Heart failure guidelines stress the importance of patient education on treatment adherence, lifestyle changes, symptom monitoring and adequate response to possible deterioration. Self‐care is related to medical and person‐centred outcomes in patients with heart failure such as better quality of life as well as lower mortality and readmission rates. Although guidelines give general direction for self‐care advice, health care professionals working with patients with heart failure need more specific recommendations. The aim of the management recommendations in this paper is to provide practical advice for health professionals delivering care to patients with heart failure. Recommendations for nutrition, physical activity, medication adherence, psychological status, sleep, leisure and travel, smoking, immunization and preventing infections, symptom monitoring, and symptom management are consistent with information from guidelines, expert consensus documents, recent evidence and expert opinion.

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Clinical recommendations for high altitude exposure of individuals with pre-existing cardiovascular conditions

Cited by 135 publications

References 47 publications

Blood pressure at high altitude: physiology and clinical implications

Blood pressure at high altitude: physiology and clinical implications

Effects of baseline heart rate at sea level on cardiac responses to high-altitude exposure

Self‐care of heart failure patients: practical management recommendations from the Heart Failure Association of the European Society of Cardiology

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