Altered blood pressure course during normal pregnancy and increased preeclampsia at high altitude (3100 meters) in Colorado

Maternal uterine artery Doppler studies at high altitude and sea level

OBJECTIVE

To determine uterine artery impedance using Doppler in the second and third trimesters at sea level and at high altitude.

METHODS

Uterine artery resistance and pulsatility indices (RI and PI, respectively) were obtained by Doppler velocimetry from 242 women in Cerro de Pasco (4300 m altitude) and 200 women in Lima (sea level), all with normal singleton pregnancies between 14 and 40 weeks of gestation. Impedance indices at high altitude and sea level were compared using fractional polynomial regression analysis.

RESULTS

Impedance to uterine artery blood flow was lower at high altitude than at sea level (for PI ratio Lima/Cerro de Pasco = 1.06; P = 0.011). If gestation bands were compared, the difference was significant up to 25 weeks.

CONCLUSION

At high altitude, pregnancy is associated with lower uteroplacental impedance than at sea level. This may reflect a compensatory mechanism of uteroplacental development to lower oxygen tension associated with altitude.

Reduction of subcutaneous mass, but not lean mass, in normal fetuses in Denver, Colorado

OBJECTIVE

To test the hypothesis that reduced birth weight in normal fetuses born at moderately high altitude (Denver), compared with the birth weight in normal fetuses born at sea level (Milan), is caused by a reduction in both lean mass and subcutaneous fat mass.

STUDY DESIGN

Ninety-four normal singleton pregnancies (46 in Denver, 48 in Milan) had serial ultrasonographic axial images obtained to assess subcutaneous tissues of fetuses as a measure of body fat. The abdominal wall thickness and mid upper arm and mid thigh were examined. The equation was: Subcutaneous tissue equals total cross-sectional area minus bone and muscle area. Lean mass included the area of muscle and bone, head circumference, and femur length.

RESULTS

Gestational age at delivery was similar between groups. Birth weight was less at Denver's altitude (2991 +/- 79 g versus 3247 +/- 96 g; P =.04). Abdominal wall thickness, mid upper arm, and mid thigh subcutaneous tissues measurements were significantly reduced at Denver's altitude and increased further in significance with advancing gestational age. Lean mass measurements were similar between groups.

CONCLUSIONS

The reduced birth weight of the newborns in Denver was the result of a reduction in fetal subcutaneous fat tissue and not lean mass. Ultrasonography can be used to follow subcutaneous measurements longitudinally and to detect differences, and potentially disease processes, in study populations.

Human genetic adaptation to high altitude

Some 140 million persons live permanently at high altitudes (>2500 m) in North, Central and South America, East Africa, and Asia. Reviewed here are recent studies which address the question as to whether genetic adaptation to high altitude has occurred. Common to these studies are the use of the oxygen transport system and the passage of time as organizing principles, and the recognition of the multifaceted ways in which genetic factors can influence physiological processes. They differ in terms of study approach and sources of evidence for judging duration of high altitude residence. Migrant, family set, and admixture study designs have been used for comparisons within populations. These collectively demonstrate the existence of genetic influences on physiological characteristics of oxygen transport. Differences in oxygen transport-related traits between Tibetan, Andean and European populations have been interpreted as having demonstrated the existence of genetic influences on high altitude adaptation but there is not consensus as to which groups are the best-adapted. Part of the controversy lies in the kinds of evidence used to assess duration of high altitude habitation. More other information is needed for a fuller appreciation of duration of residence and also features of population history (genetic drift, gene flow) but existing data are consistent with Tibetans having lived at high altitude longer than the other groups studied. Another issue surrounds usage of the term "adaptation." The definition should be based on evolutionary biology and physiological traits linked to indices of differential fertility and/or mortality. Two examples are developed to illustrate such linkages; intrauterine growth restriction (IUGR) at high altitude and the prevalence of Chronic Mountain Sickness (CMS). Interpopulational as well as intrapopulational variation exists in these conditions which appear linked to characteristics of oxygen transport. Both adversely influence survival and appear to be less severe (IUGR) or less common (CMS) among Tibetans than other groups. Thus available evidence suggest that Tibetans are better adapted. Needed, however, are studies which are better controlled for population ancestry, especially in South America, to determine the extent to which Tibetans differ from Andean highlanders. More precise information is also needed regarding the genetic factors underlying characteristics of oxygen transport. Such studies in Tibetan, Andean and Europeans as well as other high altitude populations offers a promising avenue for clarifying the adaptive value of physiological components of oxygen transport and the extent to which such factors differ among high altitude populations.

Tibetan protection from intrauterine growth restriction (IUGR) and reproductive loss at high altitude

Chronic hypoxia at high altitude restricts fetal growth, reducing birth weight and increasing infant mortality. We asked whether Tibetans, a long-resident high-altitude population, exhibit less altitude-associated intrauterine growth restriction (IUGR) and prenatal or postnatal reproductive loss than Han (ethnic Chinese), a group that has lived there for a shorter period of time. A population sample was obtained, comprising 485 deliveries to Tibetan or Han women over an 18-month period at 8 general hospitals or clinics located at 2,700-4,700 m in the Tibet Autonomous Region, China. Birth weight, gestational age, and other information were recorded for each delivery. Prenatal and postnatal mortality were calculated using information obtained from all pregnancies or babies born to study participants. Tibetan babies weighed more than the Han, averaging 310 g heavier at altitudes 2,700-3,000 m (95% CI = 126, 494 g; P < 0.01) and 530 g heavier at 3,000-3,800 m (210, 750 g; P < 0.01). More Han than Tibetan babies were born prematurely. Prenatal and postnatal mortality rose with increasing elevation and were 3-fold higher across all altitudes in the Han than the Tibetans (P < 0.05). Tibetans experience less altitude-associated IUGR than Han and have lower levels of prenatal and postnatal mortality. When the relationships between birth weight and altitude are compared among these and other high-altitude populations, those living at high altitude the longest have the least altitude-associated IUGR. This may suggest the occurrence of an evolutionary adaptation.

Oxygen transport in tibetan women during pregnancy at 3,658 m

High-altitude reduces infant birth weight as a result of intrauterine growth restriction (IUGR) and is associated with increased neonatal mortality. We hypothesized that babies born to Tibetan compared to Han (Chinese) high-altitude residents were protected from IUGR as the result of increased maternal O(2) transport due, in turn, to increased uterine artery (UA) blood flow. We studied 68 nonpregnant or pregnant Tibetan or Han residents of Lhasa, Tibet Autonomous Region, China (3,658 m). The pregnant women had higher hypoxic ventilatory responses (HVR A) and resting ventilations (V(E)) than their nonpregnant counterparts (Tib HVR = 134 +/- 16 (SEM) vs. 30 +/- 8, Han HVR = 134 +/- 16 vs. 66 +/- 18 A units; Tib V(E) = 11.8 +/- 0.3 vs. 10.1 +/- 0.5, Han V(E) = 10.7 +/- 0.5 vs. 9.4 +/- 0.5 l BTPS/min; all P < 0.05). Pregnancy did not change hemoglobin concentration in the Han but lowered values more than 2 g/dl in the Tibetans, serving to reduce arterial O(2) content below Han values (15.4 +/- 0.3 vs. 17.4 +/- 0.5 ml O(2)/100 ml whole blood, P < 0.05). Compared with the Han, the pregnant Tibetans had higher UA blood flow velocity (58.5 +/- 2.9 vs. 49.1 +/- 3.2, P < 0. 05) and distributed a higher portion of common iliac (CI) blood flow to the UA (4.8 +/- 0.4 vs. 3.3 +/- 0.3, P < 0.05). Birth weights averaged 635 g greater in the Tibetan than Han high-altitude residents (3,280 +/- 78 vs. 2,645 +/- 96 g, P < 0.01), or 694 g more when adjusted for maternal age, parity, height, and near-term body weight. Heavier birth weight babies were born to women with higher V(E) (r = 0.62, P < 0.01) and greater distribution of CI blood flow to the UA (r = 0.42, P < 0.05). We conclude that increased UA blood flow, and not higher arterial O(2) content, permits Tibetan women to increase uteroplacental O(2) delivery and protect their infants from altitude-associated IUGR.

Comparison of low- and high-altitude Doppler velocimetry in the peripheral and central circulations of normal fetuses

OBJECTIVE

Our aim was to test the hypothesis that Doppler velocimetry of the peripheral and central circulations in normal fetuses is not affected by moderately high altitude (Denver, Colo-1609 m) compared with sea level (Milan, Italy-40 m).

STUDY DESIGN

One hundred nineteen patients with singleton pregnancies underwent Doppler waveform analysis of the following: umbilical artery, uterine artery, middle cerebral artery, ductus venosus, and the tricuspid and mitral valves.

RESULTS

Birth weights were reduced at Denver's altitude (P<.001). The early/late diastolic inflow ratios of the atrioventricular valves increased with gestational age (P<.01), whereas systolic/diastolic ratios of the uterine and umbilical arteries decreased with gestational age (P<.01). There were no Doppler velocimetry differences in any vessel between Denver's and Milan's altitudes.

CONCLUSIONS

Gestational age has the same effect on Doppler index at both high and low altitudes. Moderately high altitude does not affect uteroplacental or fetal vascular Doppler index and may reflect normal acclimatization in the smaller Denver fetuses.

Endothelin-mediated preeclampsia at high altitude

Preeclampsia is pregnancy-induced hypertension. The hypoxia at high altitude increases the incidence of preeclampsia. Endothelin is released in response to hypoxia and is associated with other hypertensive states at high altitude. Endothelin may play a major role in preeclampsia for individuals residing at high altitude. Endothelin antagonists may prove useful in the treatment of preeclampsia.