Introduction
Chronic mountain sickness (CMS) or Monge's disease,
first described by Carlos Monge Medrano in Peru in 1925 (1), is characterized by excessive
erythrocytosis (a hemoglobin level of ≥19 g/dl in females or ≥21
g/dl in males) in combination with chronic hypoxemia; in certain
cases pulmonary hypertension is also apparent (2–4).
Severe pulmonary hypertension may evolve to cor pulmonale,
resulting in congestive heart failure. Therefore, CMS frequently
leads to right cardiac failure and/or neurological disorders
(3–5). The clinical signs in patients with
CMS include breathlessness and/or palpitations, sleep disturbance,
cyanosis, dilatation of veins, paresthesia, headache and tinnitus
(2,4). On the Qinghai-Tibetan plateau, the
incidence of CMS is 2.43–37.5% (3,000–4,700 m) and increases with
elevation (4,6). Furthermore, the prevalence of CMS is
significantly increased in migrants compared with that in the
native population of high altitudes, and the disease occurs more
frequently in males than in females (7–9). CMS
is a severe public health problem for the Qinghai-Tibetan plateau,
which has >60 million people in residence (4).
Despite a number of trials with medroxyprogesterone,
enalapril and almitrine, no pharmacological treatment is currently
widely used to impede the progressive loss of adaptation to chronic
hypoxia (10–13). Acetazolamide (Acz) is useful for
reducing hematocrit and improving pulmonary circulation in CMS.
However, Acz has adverse effects, including paresthesia and
diuresis (14). Therefore, the
only management for CMS, at present, is repetitive bloodletting or
the displacement of dwellers to lower altitudes. The latter option
has an important negative social and economic impact on the
development of high-altitude regions.
Excessive erythropoiesis in CMS is a process that is
hormonally regulated (15,16). High serum testosterone levels are
correlated with excessive erythrocytosis in males at high altitude,
and female sex hormones suppress polycythemic and cardiopulmonary
responses in vivo during chronic hypoxic exposure (16,17).
It is generally accepted that an excessive number of red blood
cells in the vessels is likely to increase blood viscosity, thereby
inducing pulmonary hypertension and even cardiac failure. However,
the underlying mechanism of pulmonary hypertension in CMS is only
partially understood. Data from Bailey et al(18) indicated that increased pulmonary
arterial systolic pressure at high altitude was correlated with a
reduction in pulmonary nitric oxide (NO) bioavailability (18). Therefore, the inhibition of
erythropoiesis and the increase of circulating NO levels are likely
to alleviate the clinical signs of patients with CMS.
Soy isoflavones (Ifs) are the most studied and most
potent phytoestrogens, and are predominantly present in soy-based
foods (19). Genistein and
daidzein, the two most abundant Ifs (19), have chemical structures similar to
that of estradiol (E2) and exert estrogen-like effects (20), which are able to inhibit excessive
erythropoiesis. Experimental studies have shown the beneficial
effects of Ifs on the production of NO in endothelial cells, which
include inhibition of the proliferation of vascular smooth muscle
and reduction of the tissue damage caused by reactive oxygen
species (ROS) (21,22). Animal studies have also indicated
that genistein and daidzein, through estrogen receptor
(ER)-independent mechanisms, restore endothelial cell function by
increasing NO production and the protection of NO from
O2•−driven inactivation (23). In addition, our previous studies
showed that treatment with genistein inhibited pulmonary vascular
structural remodeling and right ventricular hypertrophy induced by
chronic hypoxia (5,000 m, 21 days) in male Wistar rats without
adverse effects, such as feminizing and oncogenic effects (24–26).
Therefore, in the present study it was hypothesized
that Ifs may reduce excessive erythropoiesis and ameliorate right
ventricular index and pulmonary hemodynamics in CMS. The study
aimed to observe the effects of Ifs in patients with CMS and to
evaluate the treatment of CMS.
Materials and methods
Subjects and procedure
Twenty-eight male patients suffering from CMS, who
were living on the Qinghai-Tibetan plateau (5,200 m), gave their
informed written consent for this study, which was approved by the
Ethics Committee of the Third Military Medical University
(Chongqing, China). The Ethics Committee of the Third Military
Medical University refused to permit a study design where no
treatment was administered to patients who had been diagnosed with
CMS with malaise. Therefore, placebo treatment was not given to the
patients with CMS. This study was only designed to observe the
effects of Ifs on patients with CMS by comparing various parameters
prior to and following treatment. All subjects, who were born and
previously lived in a low-altitude area, were migrants of the
Qinghai-Tibetan plateau (5,200 m), had been residing at the plateau
>10 months and did not travel to lower altitudes (<5,000 m).
All patients had a hemoglobin concentration ≥21 g/dl and were
working at the same labor intensity. A complete clinical
evaluation, including an evaluation of ventilatory function and
cardiac ultrasonography, was performed prior to inclusion in the
study to exclude subjects with cardiac or pulmonary diseases. The
age, weight and height of the subjects were 20.86±1.53 years,
66.36±6.59 kg and 1.76±0.35 m, respectively. The CMS clinical score
was calculated according to a consensus statement on chronic
high-altitude diseases (2) and was
based on the following symptoms: breathlessness and/or palpitation,
sleep disturbance, cyanosis, dilatation of veins, paresthesia,
headache and tinnitus. Finger blood oxygen saturation
(SaO2) and heart rate (HR) were measured using a TuffSat
handheld oximeter (GE Healthcare, Fairfield, CT, USA) following a
15-min rest in the sitting position. Subjects were treated orally
with Ifs capsules (containing 20 mg mixed Ifs, twice daily;
Department of Traditional Chinese Medicine Preparation, Xinqiao
Hospital, Third Military Medical University, Chongqing, China) for
45 days. All measurements were obtained at low altitude on two
occasions, prior to and following treatment with Ifs.
Hematological status
Anticoagulated peripheral venous blood samples were
obtained from subjects at 5,200 m in the sitting position,
immediately subsequent to the subjects waking up in the morning.
Hemoglobin concentration was obtained using cyanide measurements
and a duplication was performed for each sample. The measurements
for hematocrit were obtained using Symex pocH-80i automatic blood
cell analyzer (Sysmex, Kobe, Japan). Following centrifugation at
1,000 × g for 10 min, the plasma was collected and stored at −20ºC.
The levels of plasma NO, nitric oxide synthase (NOS), superoxide
dismutase (SOD) and malondialdehyde (MDA) were measured using
corresponding chemical colorimetry reagent kits (Nanjing Jiancheng
Bioengineering Institute, Nanjing, China), in accordance with the
manufacturer's instructions.
Echocardiographic measurements
Echocardiography was performed with a 2.5-MHz
transducer (Logiq Book XP, GE Healthcare) to evaluate the main
pulmonary artery diameter (MPA), right ventricular end-diastolic
anteroposterior diameter (RVEAD), right ventricular end-diastolic
trans diameter (RVETD), right ventricular anterior wall (RVAW) and
right ventricular outflow tract (RVOT) by a single experienced
echocardiographer, as previously described (27).
Statistical analysis
Data are expressed as the mean ± standard deviation.
The analyses were performed using a Student's t-test. P<0.05 was
considered to indicate a statistically significant difference.
Results
Effects of treatment with Ifs on
physiological outcomes
Following 45 days of treatment with Ifs,
SaO2 was significantly increased by 2.04% (P<0.05),
the CMS score was decreased by 1.07 points (P<0.01) and HR was
decreased by 4.17 beats/min (P<0.05) compared with the values
prior to treatment (Table I).
These changes clearly indicated an improvement in hypoxemia and a
reduction of clinical malaise in patients with CMS.
 | Table IEffects of treatment with isoflavones
on the physiological parameters of patients with CMS (n=28). |
Table I
Effects of treatment with isoflavones
on the physiological parameters of patients with CMS (n=28).
| Time-point | CMS score
(points) | Heart rate
(beats/min) | SaO2
(%) |
|---|
| Prior to
treatment | 4.68±1.47 | 92.46±10.97 | 81.07±3.39 |
| Following
treatment | 3.61±2.18 | 88.29±10.46 | 83.11±3.97 |
| P-value | 0.007 | 0.042 | 0.028 |
Effects of treatment with Ifs on
hematological outcomes
The number of polycythemic individuals (hemoglobin
≥21 g/dl) decreased from 28 to 17 following treatment with Ifs. In
addition, treatment with Ifs significantly decreased the hematocrit
by 4% (P<0.05), hemoglobin concentration by 1.06 g/dl
(P<0.01) and plasma levels of MDA by 1.16 nmol/ml (P<0.05),
and markedly increased the plasma levels of NO by 7.70 μmol/l
(P<0.01) and the activities of NOS and SOD by 7.19 and 10.63
U/ml, respectively (P<0.01 for each; Table II). These changes indicated that
Ifs reduced the hemoglobin concentration and increased the plasma
NO levels and antioxidant capacity in patients with CMS.
| Table IIEffects of treatment with isoflavones
on the hematological outcomes of patients with CMS (n=28). |
Table II
Effects of treatment with isoflavones
on the hematological outcomes of patients with CMS (n=28).
| Time-point | Hematocrit | Hemoglobin
(g/dl) | MDA (nmol/ml) | SOD (U/ml) | NOS (U/ml) | NO (μmol/l) |
|---|
| Prior to
treatment | 0.71±0.08 | 22.24±0.78 | 4.81±2.09 | 68.10±18.56 | 40.43±13.61 | 47.50±14.29 |
| Following
treatment | 0.67±0.05 | 21.18±1.05 | 3.65±2.11 | 78.73±14.64 | 47.62±10.87 | 55.20±14.10 |
| P-value | 0.012 | <0.001 | 0.012 | <0.001 | 0.002 | 0.004 |
Effects of treatment with Ifs on the
cardiac and pulmonary circulation
Table III shows
the echocardiographic measurements of the patients with CMS.
Forty-five days of treatment with Ifs significantly decreased MPA
by 1.38 mm (P<0.05), RVEAD by 1.73 mm, RVETD by 3.00 mm, RVAW by
0.50 mm and RVOT by 2.19 mm compared with the values prior to
treatment (all P<0.01). These results suggested an amelioration
in the pulmonary hemodynamics and right ventricular index in
patients with CMS.
| Table IIIEffects of treatment with isoflavones
on the cardiac and pulmonary circulation of patients with CMS
(n=28). |
Table III
Effects of treatment with isoflavones
on the cardiac and pulmonary circulation of patients with CMS
(n=28).
| Time-point | MPA (mm) | RVEAD (mm) | RVETD (mm) | RVAW (mm) | RVOT (mm) |
|---|
| Prior to
treatment | 23.38±2.70 | 23.39±3.12 | 30.71±3.75 | 5.89±1.22 | 33.89±3.59 |
| Following
treatment | 22.00±2.31 | 21.66±2.49 | 27.71±3.38 | 5.39±0.79 | 31.70±3.37 |
| P-value | 0.011 | <0.001 | <0.001 | 0.010 | 0.002 |
Discussion
CMS is an excessive polycythemia that is common
among high-altitude residents, particularly in migrants (2). According to the prevalence of CMS,
millions of residents on the Qinghai-Tibetan plateau suffer from
CMS. Therefore, these residents may benefit from a treatment that
reduces their hemoglobin concentration and pulmonary arterial
pressure.
The physiopathology of CMS has been attributed to
the following sequence: hypoxemia, excessive erythropoiesis and
pulmonary hypertension (4,7). In the present study, following
treatment with Ifs, the hematocrit and hemoglobin concentrations of
the subjects were significantly decreased compared with the values
prior to treatment. Therefore, the number of polycythemic
individuals (hemoglobin ≥21 g/dl) decreased from 28 to 17 following
treatment with Ifs. Moreover, 45 days of treatment with Ifs
significantly increased SaO2 and decreased HR and the
CMS score compared with the values prior to treatment, which
indicated a reduction in hypoxemia and clinical indisposition. In
addition, Ifs significantly reduced MPA, RVEAD, RVETD, RVAW and
RVOT. Therefore, these results indicated improvements in hypoxia
and clinical indisposition, and an amelioration of the right
ventricular index and pulmonary hemodynamics in patients with CMS
following treatment with Ifs. Furthermore, these results were
consistent with our previous observations in rats, which showed the
preventive effects of phytoestrogens on chronic hypoxic pulmonary
hypertension and right ventricular hypertrophy (25,26).
In addition, there were no adverse effects, such as diuresis,
paresthesia and heartburn, following treatment with Ifs in the
present study. Data from Hamilton-Reeves et al(28) and our own laboratory showed that
Ifs elicited no effects on reproductive hormones in men or male
rats (26,28). Ifs may have a more extensive
applications in patients with CMS compared with Acz, which exhibits
beneficial and adverse effects.
Furthermore, the present study demonstrated that
treatment with Ifs significantly decreased plasma MDA levels and
increased SOD activity, indicating an attenuation of oxidative
damage in patients with CMS. This may result in the relief of
malaise in patients with CMS during long-term exposure to
high-altitude hypoxia. Marked increases in the plasma activity of
NOS and circulating NO levels were observed following 45 days of
treatment with Ifs compared with the values prior to treatment. NO
has been demonstrated to be important in adaptation or
acclimatization to high altitude. Scherrer et al(29) revealed that NO reduced pulmonary
arterial pressure and improved oxygen saturation among patients
suffering from high-altitude pulmonary edema (29). Furthermore, total NO has been
demonstrated to be negatively correlated with pulmonary arterial
systolic pressure and positively correlated with pulmonary blood
flow and oxygen delivery at 4,200 m (30). In age and biomarker-adjusted
logistic regression, NOS was also shown to be inversely predictive
of CMS (31). In the present
study, the increased plasma activity of NOS and circulating NO
levels, induced by 45 days of treatment with Ifs, relaxed small
pulmonary arteries and reduced MPA and right ventricular ejection
resistance. These observations were consistent with the results
from our previous studies, in which treatment with genistein, the
most active form of Ifs, inhibited pulmonary vascular structural
remodeling and right ventricular hypertrophy induced by chronic
hypoxia (5,000 m, 21 days) in male Wistar rats (25,26).
In conclusion, the present study demonstrated the
potential beneficial effects of Ifs in reducing excessive
erythrocytosis, alleviating oxidative damage and ameliorating right
ventricular index and pulmonary hemodynamics in CMS. We propose
that Ifs are a potential low-cost treatment for CMS. Studies with a
control group and a dose-effect analysis, and large-scale trials
are required to evaluate the feasibility of the implementation of
treatment for CMS in the Tibetan region.
Acknowledgements
This study was supported by the ‘Eleventh Five-Year’
National Technology Support Program of China (grant no.
2009BAI85B01), the National Key Basic Research Development Program
of China (grant no. 2012CB518201) and the National Science
Foundation of China (grant nos. 30971426 and 81101469).
Abbreviations:
|
CMS
|
chronic mountain sickness
|
|
Acz
|
acetazolamide
|
|
Ifs
|
isoflavones
|
|
NO
|
nitric oxide
|
|
NOS
|
nitric oxide synthase
|
|
SOD
|
superoxide dismutase
|
|
MDA
|
malondialdehyde
|
|
MPA
|
main pulmonary artery diameter
|
|
RVEAD
|
right ventricular end-diastolic
anteroposterior diameter
|
|
RVETD
|
right ventricular end-diastolic trans
diameter
|
|
RVAW
|
right ventricular anterior wall
|
|
RVOT
|
right ventricular outflow tract
|
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