Microalbuminuria in Healthy Adolescents: A Comparative Study at High Altitude and at Sea Level

Abdias Hurtado*, 1, Raquel Cancino 2, Joel Figueroa 2, Euclides Padilla 2, Christian Morales 2, Irma Ortiz 2, Shailendra Sharma 3, Richard J Johnson 3, Jackeline Pando 4
1 The Division of Nephrology, Hospital Arzobispo Loayza, Cayetano Heredia University, Lima, Peru
2 Division of Family Medicine, Hospital Arzobispo Loayza, Cayetano Heredia University, Lima, Peru
3 The Division of Renal Diseases and Hypertension, University of Colorado, Denver, USA. and
4 Department of Paediatrics and Child Health, University College Cork, Ireland

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© Hurtado et al.; Licensee Bentham Open.

open-access license: This is an open access article licensed under the terms of the Creative Commons Attribution Non-Commercial License ( which permits unrestricted, non-commercial use, distribution and reproduction in any medium, provided the work is properly cited.

* Address correspondence to this author at the Division of Nephrology, Hospital Arzobispo Loayza, Cayetano Heredia University, Lima 27, Peru. Tel: 511 2248178; Fax: 511 3309361; E-mail:


Background :

High altitude is associated with hypobaric hypoxia and increased risk for microalbuminuria in adults. We hypothesized that healthy adolescents at higher altitude might have an increased frequency of microalbuminuria in comparison with a group of adolescents living at sea level.

Methods :

We evaluated the presence of microalbuminuria in adolescents at sea level (n=68, altitude 130 meters) and at high altitude (n=114, altitude 3200 meters) living in Peru. Each subject was evaluated for body mass index, Blood Pressure, microalbuminuria, proteinuria, hematuria and leukocyturia in a first morning urine sample. Subjects with a positive test for microalbuminuria underwent repeat testing one or two weeks after the initial screening.

Results :

Subjects at sea level and high altitude had similar age, weight, height and blood pressure (p=NS). Microalbuminuria without any other urinary abnormality, was higher in the first screening among adolescents residing at high altitude compared to those living at sea level (42 vs15, p: 0.0215). In the second screening the results were similar in both groups (31 vs 11, p: 0.0879).

Conclusion :

Persistent microalbuminuria was observed in more than one-quarter of adolescents living at high altitude. This study suggests that subtle renal injury may occur early in subjects living at high altitude.

Keywords: Adolescents, high altitude, microalbuminuria..


Microalbuminuria (MA) is commonly measured as a risk factor for kidney disease or endothelial dysfunction in diabetic [1] and hypertensive [2] patients. The prevalence of MA among adult healthy population varies between 6 and 8% and increases with age [3-5].

Over 140 million people live at high altitude (HA), defined as living at an altitude of 2400m or more above sea level. They represent 2% of the world´s population [6]. People who reside at HA are exposed to an environment of chronic hypobaric hypoxia. Recent studies done in adult population residing at HA have shown a higher risk of developing renal disease and MA [7, 8], but there is no data in younger population. We therefore hypothesized that adolescents at higher altitude might have increased frequency of MA. To test this hypothesis, we conducted a screening for MA and proteinuria among adolescents residing at high altitude and compared it with a group of adolescents living at sea level (SL).


Materials and Subjects

This was an observational and cross sectional study done between 2011 and 2012. The subjects were Peruvian adolescent students from the last year of high school. There were two groups. The first group resides at HA - in the rural town of Llamellin-Ancash at 3200 meters above sea level. The second group resides in the town of Tahuantinsuyo - Lima, at 130 meters above sea level. In the town of Llamellin there were 870 students and in Tahuantinsuyo there were 940 students. To obtain the sample size we used a 5% error margin with a 95% confidence level and a heterogeneity level of 10%. The sample size calculated was 129 students.

Teachers and parents were informed about the study and consent forms were obtained. 114 out of 127 students residing at HA accepted to participate in the study, same as 68 out of 96 students residing at SL.

Inclusion criteria were: adolescent students from Llamellin and Tahuantinsuyo on their last year of high school. Signed inform consent obtained from the parents. Exclusion criteria: Students who did not agree to participate in the study, students who at the time of the screening had and acute infectious illness, students with a previously known illness, students on medications.

The protocol was approved by the Bioethics Committee of the “Hospital Nacional Arzobispo Loayza”, Lima, Peru in accordance with the Declaration of Helsinki.


Past medical history and current health status was obtained among the students who volunteered for the study, so as to exclude those with a current illness. In those subjects selected, there were the following procedures done: Anthropometric measurements: weight and height were obtained after removing shoes and heavy clothes. BMI was calculated [9]. Blood Pressure (BP) measure: subjects were asked to remain seated and at rest for 15 minutes prior to measuring their BP. Three recordings were taken, with a 3 minute interval between each other [10]. OMRON (Japan) calibrated machines were used. Proteinuria screening: The subjects were asked to collect their first morning urine sample (to eliminate the possibility of orthostatic proteinuria) after adequate hygiene. We used Meditest, Combi 10R, SGL, Macherey-Nagel urinary dipsticks to measure proteinuria, hematuria and leukocyturia. Meditest is a semiquantative method. The minimum sensitivity of the test strip is 10 mg protein/dL urine. The color fields correspond to the following ranges of albumin concentrations: negative, 1+: 30, 2+: 100 and 3+: 500 mg/dL. MA: was measured in the same morning urine sample, MA was measured using Micral Test R Roche. A value greater than 20 mg/L was considered as positive.

In those students who presented with a positive result, both tests were repeated one or two weeks after the initial screening [11].

Statistical Analysis

The quantitative variables are expressed as mean and standard deviation and the qualitative variables are expressed as percentages. We used T students and Chi square to compare continuous and discrete variables respectively. A value of p <0.05 was considered as statistically significant. We used SPSS 16 to analyze the data.


There were 114 adolescents evaluated at HA and 68 at SL. The age range for both groups was 15-18 years. The demographics in both groups were similar and are shown in Table 1. None of the students were hypertensive or obese.

Table 1.

Demographical characteristics of the High Altitude and the Sea Level groups.

  High Altitude Group (n:114) Sea Level  Group (n:68) p Value
Gender: Male/Female 63/51 30/38 0.1558
Age ( years) 16.7 ± 1.3 16.3 ± 1.0 0.8185
Weight ( kilograms) 54.9 ± 7.2 56.9 ± 8.7 0.8622
Height (meters) 1.6 ± 0.1 1.61 ± 0.07 0.9435
Body mass index * 21.4 ± 2.4 21.9 ± 2.58 0.8926
Systolic Blood Pressure (mmHg) 115.7 ± 10.7 120.9 ± 11.4 0.7523
Diastolic Blood Pressure (mmHg) 69.3 ± 9.3 67.2 ± 8.3 0.8783


Table 2.

Urinalysis results of the high altitude and the sea level groups.

  High Altitude Group 1st Screening (n: 114) Sea Level Group 1st Screening (n: 68) p Value
Leukocyturia: 1st screening 6 5 0.7492
Leukocyturia: 2nd screening 0 1 0.3736
Hematuria: 1st screening 15 13 0.2810
Hematuria: 2nd screening 4 6 0.0887
Proteinuria: 1st screening 13 11 0.4875
Proteinuria: 2nd screening 5 6 0.3714
Microalbuminuria: 1st screening 42 15 0.0215
Microalbuminuria: 2nd screening 31 11 0.0879

Microalbuminuria was defined as a value greater than 20 mg/L using MicralTestR Roche.

The results of the urinary screening are shown in Table 2. Leukocyturia and hematuria were similar in both groups and both parameters were significantly decreased in the second evaluation. Proteinuria was similar in both groups in the first screening (13/114 (11.4%) vs 11/68 (16.1%) and decreased in the second screening (5/13 vs 6/11).

MA without any other urinary abnormality was higher in the first screening among the adolescents residing at HA compared to those living at SL (42/114 (36.8%) vs 15/68 (22%), p: 0.0215). In the second screening, MA decreased and the results were similar in both groups (31/42 vs 11/15, p: 0.0879).


There are few epidemiological studies evaluating MA among children and most of them have been done in children with diabetes and obesity [12, 13].

We hypothesized that adolescents living at high altitude would have a higher prevalence of MA. The primary finding was that there was a higher frequency of MA among adolescents living at HA based on a single screening (36.8 vs 22 percent). In the second screening, 31/114 patients (27%) still had microalbuminuria in the HA group compared to 11/68 (16%) in the sea level group. While the p value was only 0.08, it is trending towards significance, and may become significant in a larger sample size. The profile of the adolescents with negative MA on the second screening was similar to those who had persistent MA, with no statistical differences among their age, sex, BMI or blood pressure. It is recognized that a second screening evaluation reduces the presence of a positive result for MA up to 75 % in otherwise healthy children [14, 15]. One of the reasons for this is that MA is very variable from day to day and shows important intra-individual variability suggesting the need for multiple assessments [16, 17].

A population - based epidemiological study of CKD in Tibetan population looked at 1189 Tibetans over 18 years of age who were living at altitudes between 3658 and 4200 m, and found an adjusted prevalence of MA of 16% [7].

The presence of persistent MA in the high altitude population is interesting as adults show an increasing frequency of MA and hypertension, a syndrome called High Altitude Renal Syndrome [8]. The etiology of this syndrome may reflect hypoxia associated endothelial dysfunction, oxidative stress, effects from elevated uric acid, or relate to the higher frequency of low birth weight. Unfortunately, we were not able to test for these possibilities with this study. Exposure of rats to hypobaric hypoxia can induce subtle renal injury in the kidney, including microvascular disease, glomerular hypertrophy, and mild tubulointerstitial inflammation [18].

MA around the world in a single screen shown that in the United States a prevalence of 10.7% in boys and 19.1% in girls between 6 and 19 years [19]. Tsioufis in Greece found a prevalence of 5 to 7% in boys and 12 to 15% in girls [20]. A study done among the Pima North American native ethnic population, showed a prevalence of 6% [14]. In Nigeria, a study done among school children found a prevalence of MA of 33%, the prevalence was higher in female adolescent who were obese, hypertensive and diabetics [21]. Transient MA can be seen in children secondary to physical exertion or to febrile illness [22, 23] but these conditions were excluded in our study.

The treatment of MA in adults, includes the treatment of the underlying condition (hypertension, diabetes, obesity) and the use of the renin-angiotensin-aldosterone (RAAS) system blocking agents [24]. A small prospective randomised study among people with altitude polycythemia and proteinuria done in La Paz, Bolivia, showed a significant fall in proteinuria ( p>0.002) in those who received Enalapril for 2 years [25]. The treatment of children with MA who have less co-morbidities, opens the possibility of research looking at the natural history of this condition [26].

Limitations of the study include an uneven sample size, with a two-fold higher number of adolescents at HA compared to those at SL. This might influence the results. On the other hand the ideal way to measure MA is by measuring albumin/creatinine ratio, but this was not done in our study due to technical difficulties with preserving samples at HA. Nevertheless, screening for MA using the micraltest is reliable, detects levels as lows as 20 mg/l, and has a sensitivity of 96.7% and a specificity of 71% [27-29].

This study suggests that subtle renal injury may not be uncommon in adolescents in Peru. Disease occurring early may have a role in the development of hypertension or chronic kidney disease as an adult. Given that there are over 140 million people who currently live at high altitude, representing 2% of the world population (6), we recommend further studies evaluating community - based mass screening to help identify individuals at risk for developing CKD.


The authors confirm that this article content has no conflict of interest.


This work was partially supported by a grant from the International Society of Nephrology (ISN) Global Outreach Research & Prevention Committee".


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