SciELO - Scientific Electronic Library Online

 
vol.46 issue3Mortality and hyperchloremia in the intensive care unitAnesthetic implications of muscular dystrophies author indexsubject indexarticles search
Home Pagealphabetic serial listing  

Services on Demand

Journal

Article

Indicators

Related links

  • On index processCited by Google
  • Have no similar articlesSimilars in SciELO
  • On index processSimilars in Google

Share


Colombian Journal of Anestesiology

Print version ISSN 0120-3347

Rev. colomb. anestesiol. vol.46 no.3 Bogotá July/Sept. 2018

https://doi.org/10.1097/cj9.0000000000000065 

SCIENTIFIC AND TECHNOLOGICAL RESEARCH

Arterial blood gas in young adults at an average altitude of 1605-m above sea level: Armenia, Colombia 2016

Fabio Hernán Cárdenas-Santamaríaa  b 

Margarita Ardüa-Flórezb 

Juan Manuel Jaramillo-Mejíab  c 

Viviana Echeverry-Restrepob  c 

Leidy Alexandra García-Gutiérrezb  c 

Ángela Liliana Londoño-Francob  * 

a Intensive Care Unit, Hospital Universitario San Juan de Dios, Quindío, Colombia

b School of Health Sciences, Universidad del Quindío, Quindío, Colombia

c Hospital Universitario San Juan de Dios, Universidad del Quindío, Quindío, Colombia.


Abstract

Introduction:

Arterial blood gas measurement is an essential quick test in clinical practice to evaluate oxygenation and for the identification and diagnosis of acid-base and metabolic disorders. Arterial blood gas reference values vary as a result of altitude changes associated with barometric pressure (bp).

Objectives:

To determine the PaCO2, PaO2, HCO3, and SaO2% values for a young population without lung disease in a city located at an average altitude of 1605-m above sea level and a bp of 624mm Hg.

Materials and methods:

Descriptive cross-sectional study in 137 arterial blood gas samples from male and female healthy volunteers aged between 18 and 40 years old. An COPD® point of care blood analysis portable system was used for readings with single-use individual cards.

Results and conclusion:

The 95% confidence interval (CI) limits were pH between 7.43 and 7.45, PaO2 between 86.23 and 88.83, PaCO2 between 32.64 and 33.87, and SatO2% between 97.13 and 97.38. No gender or age differences were found. When comparing the findings against other trials conducted over 2640-m above sea level, some differences were identified: PaO2 between 18 and 26 mm Hg lower at an altitude of 1605 m (Armenia), PCO2 between 2.0 and 2.7 mm Hg higher in Armenia, and also the SaO2% was between 3.6% and 6.2% higher. PaO2 and HCO3~ were mildly higher as compared with a study conducted in Medellin. The oxygenation index (PaO2/FIO2) was 416.83 (95% CI 410.63-23.03)- as expected-considering the difference in altitude due to the geographic location, pursuant to the referenced studies.

Keywords: Oxygenation; Blood Gas Analysis; Acid-Base Equilibrium; Young Adult; Atmospheric Pressure

Resumen

Introducción:

La gasometría arterial es una prueba rápida indispensable en la práctica clínica para la evaluación de la oxigenación y para identificar y diagnosticar desórdenes metabólicos, por alteración en el equilibrio ácido base. Los valores de referencia varían por los cambios de altitud relacionados con la presión barométrica (pb).

Objetivos:

Determinar los valores de PaCO2, PaO2, HCO3- y SaO2% en población joven sin enfermedad pulmonar en una ciudad con altura promedio de 1605 msnm y pb de 624 mmHg.

Materiales y métodos:

Estudio descriptivo transversal en 137 muestras de sangre arterial de voluntarios sanos de 18 a 40 años ambos sexos. Para la lectura se utilizó un equipo portátil "point of care en sangre EPOC®" con tarjetas individuales de un solo uso.

Resultados y conclusiones:

Los límites de intervalos de confianza del 95% de las medias fueron: pH entre 7,43 y 7,45; PaO2 86,23 y 88,83; PaCO2 32,64 y 33,87 y SaO2% 97,13 y 97,38. No se encontraron diferencias por sexo ni edad. Al comparar los hallazgos con estudios realizados por encima de los 2640 msnm, se observaron diferencias: PaO2 entre18y 26 mm de Hg menor que a 1605 msnm (Armenia), PCO2 entre 2,0 y 2,7 mm Hg mayor en Armenia al igual que la SaO2% entre 3,6 y 6,2%. La PaO2 y el HCO3- fueron levemente mayores que un estudio realizado en Medellín. El índice de oxigenación (PaO2/FIO2) fue de 416,83 (IC 95% 410,63-423,03), resultados esperados, teniendo en cuenta la diferencia de altura por la ubicación geográfica, según los estudios referenciados.

Palabras clave: Oxigenación; Análisis de los Gases de la Sangre; Equilibrio Ácido-Base; Adulto Joven; Presión Atmosférica

Introduction

In clinical practice, arterial blood gas measurement is an essential test for analyzing arterial oxygenation (PaO2), arterial oxygen saturation (SatO2), acid-base balance, and indirectly, ventilation with the CO2 arterial pressure value (PaCO2). It also helps in evaluating and measuring the patient's response to therapeutic interventions such as oxygen therapy, mechanical ventilation, and to follow-up the evolution of the pulmonary and/or metabolic disease.1

Among other factors, the arterial blood gases measurement varies as a result of the atmospheric or barometric pressure (bp), which at sea level is 760 mm Hg.2-6 The arterial oxygen pressure (PaO2) depends on the oxygen that varies with bp, and hence with the altitude at which the individual breathes ambient air; the arterial partial pressure of oxygen is inversely proportional to the altitude at which a particular individual lives;4 the PaO2 may be further affected by age, because the normal lung tissue aging alters the oxygen exchange at the level of the alveolar capillary septum.7,8

The HCO3 - (concentration of bicarbonate ions in plasma) is the most important base in the body to maintain a stable pH.6,9 The pH is a critical parameter in the acid-base balance; the hydrogen ions concentration (H+) depends on the interaction between PaCO2 and HCO3 -.10

Several research studies conducted in various places describe the variations in blood gas measurements at varying altitudes, but most of these studies take place in cities at high altitudes or at sea level; likewise, the studies identified at altitudes similar to Armenia have been conducted in small sample sizes.8,11

The evaluation and monitoring of the acid-base balance in the young critical patient need to associate various aspects of the clinical manifestations and the physical examination with the gas measurements.10 In addition to the conditions that alter the acid-base balance in this age group, trauma (injuries from external causes) is much more frequent; in Colombia, trauma represents the third cause of death among males and the second cause of death among females.12 Furthermore, the detection and management of acid-base balance alterations have a significant impact on morbidity and mortality.13,14

Due to the above considerations, and since the results of the parameters may vary with altitude, this study was intended to determine the blood gas measurements in a city located in the coffee-growing area, at 1605-m above sea level, with a bp of 624mm Hg. The study population comprised healthy, non-smokers aged between 18 and 40 years old. In addition, the results were compared against a number of studies conducted at other altitudes; these findings are intended to contribute to the information about the region and other regions at similar altitudes.

Materials and methods

Type of study

Descriptive, cross-sectional study.

Study population

The study comprised 137 participants from the University of Quindío, where the project was publicized; undergraduate students, professors, and administrative staff were invited to participate. The importance of the study was clearly emphasized and most of the participants that volunteered to submit a sample were from the School of Health programs.

Exclusion criteria. Cigarette and/or tobacco use-more than 2U/day-in the last 3 years. Chronic cardiopulmonary disease, systemic lupus erythematosus, rheumatoid arthritis, bronchial asthma, congenital heart disease, COPD, pneumoconiosis or occupational exposure to inhaled smoke or chemicals, and coagulopathies or anticoagulation therapy.

Techniques and procedures

The samples were collected by the anesthesiologist or the nurse (investigators) using an COPD® point of care blood analysis portable system with individual single-use cards, which render the following measurements: pH, PaCO2, PaO2, and HCO3-, and SaO2% estimates.15-19

Pre-conditions. Before taking the sample, the patient was at rest for 10 minutes while being informed about the procedure, signed the informed consent and completed the sampling instrument. No fasting was required.

Test technique. With the patient seated the wrist is hyperextended at approximately 45° with the wrist resting on a dorsal cushion; the asepsis and antisepsis of the puncture site is conducted, and the radial artery is palpated with the fingers of 1 hand to localize the precise puncture site, whereas the other hand inserts and slowly advances the needle entering the skin at an angle of approximately 45°.

An amount of 1 mL of arterial blood is collected and then the needle is quickly removed. The samples are immediately processed.

Information processing and analysis

The information was processed using the SPSS version 19.0 (Armonk, New York) statistical package and the normality of the quantitative variables was determined with the Kolmogorov-Smirnov test. Central trend measurements, position, and confidence intervals (CIs) were estimated for the study variables; analysis of variance (ANOVA) was conducted to compare the parameters by age groups. The oxygenation index was estimated using the PaO2/FiO2 ratio. The results from the study were compared against other studies conducted at different altitudes above sea level.

Bioethical considerations

From the ethical-legal perspective, the project was conducted according to resolution 8430 of 1993 of the Ministry of Health, which establishes the technical, scientific, and administrative standards for every health-related research project. The project was previously approved by the Bioethics Committee of Universidad del Quindío. The resulting information was managed confidentially, ensuring the privacy of all patients and the results shall only be used with a view to obtaining scientific information. The informed consent form was duly completed by each participant and the consent form explained the test technique and warned against potential pain or puncture-associated complications.

Results

A total of 137 participants were enrolled. A sample was taken from each participant to analyze the parameters of the study; the mean age was 22.5 years (95% CI 21.7-23.3) and the age range as from 18 to 40 years old. Table 1 shows the results for PaO2, PaCO2, HCO3~, pH, and SaO2%.

Table 1 Values of the parameters analyzed in a population living at an altitude of 1605-m above sea level 

CI=confidence interval, SD=standard deviation.

Source: Authors.

A total of 40.1% (n = 55) of the samples were taken from males and 59.9% (n = 82) from females. The HCO3 - and PaCO2 values were significantly higher in males than in females, with a 1.88 (95% CI 1.26-2.50) and 2.94mm Hg (95% CI 1.78-4.09) difference, respectively (Table 2).

Table 2 Values of parameters analyzed according to gender at an altitude of 1605-m above sea level 

CI=confidence interval, MD=mean differences (significance).

Source: Authors.

An analysis by age groups was conducted and ANOVA was administered; no significant differences were found (Table 3).

Table 3 Parameters analyzed according to age groups at an altitude of 1605-m above sea level 

AV=analysis of variance (significance), CI=confidence interval, Me=median, OI=oxygenation index (PaO2/FIO2), X=average.

Source: Authors.

As a second stage, studies conducted in Bogotá and Cusco with altitudes of 2640 and 3350-m above sea level, respectively, were selected; the results of other altitudes, but with very alike populations to ours, were compared with the results of our study, calculating the median differences. According to the observations, in Armenia, the PaCO2, PaO2, and SaO2% values were higher as compared against the referred studies; the pH was identical. When comparing against the trial conducted in Medellin at an altitude of 1538-m above sea level, in Armenia the PaO2, and HCO3- were slightly higher (Table 4).

Table 4 Difference of parameter measurements at an altitude of 1605-m above sea level vs other altitudes 

CI=confidence interval, MD=missing data, SD=standard deviation.

∗ Place: city and altitude in meters above sea level.

† Difference with Armenia vs measurements in other places (MD).

Source: Authors.

Finally, the oxygenation index was calculated (PaO2/FIO2) obtaining average values of 416.83 (95% CI 410.63-423.03), ranging between 337.62 and 513.81; no gender or age differences were identified (P = 0.69). The scatter plot illustrating the relationship between (PaO2/ FIO2) and SaO2% indicated that the 76.6% variability (variance) was the same for both variables, with an R2 of 0.875 (Fig. 1).

Source: Authors.

Figure 1 Relationship between oxygenation index and SaO2%. 

Discussion

The arterial blood gas measurement is an instant report of the oxygenation status, the ventilation condition, and the internal acid-base balance; it is an indispensable quick test in the clinical care of patients with respiratory disease, acute or chronic pulmonary conditions, or metabolic disorders.9 According to the geographic location, and as result of the changes in bp due to the different altitudes above sea level, the information about the normal blood gases parameters should be available as a tool in daily clinical practice.

In our study conducted in young individuals without pulmonary disease, non-smokers, and at rest, we identified pH values ranging from 7.43 to 7.45; PaO2 values between 86.23 and 88.83; PaCO2 values from 32.64 to 33.87; and SaO2% values ranging from 97.13 to 97.38. No gender or age differences were found. Studies conducted at altitudes similar to Armenia's, such as the study conducted by Ortega et al8 in the city of Medellin, suggested that the reference values for healthy adults aged 20 to 45 were as follows: pH 7.42, PaO2 80.82 mm Hg, PaCO2 31.68 mm Hg, and HCO3~ 20.37 mEq/L.

Over the course of the review, several studies conducted in Bogotá, Colombia, located at an altitude of 2.640-m above sea level and with a bp of 560 mm Hg, have established the normal values for various age groups, indicating average normal pH values between 7.36 and 7.47; PaCO2 values between 29 and 35, PaO2 values of 60 to 69, and SaO2 values of 90 to 93.8.20-22

At a higher altitude, in Huancayo (Peru), located at 3249-m above sea level, and in Cusco at 3350-m above sea level, the bps were 535 and 530 mm Hg, respectively. The following average normal values are available: pH 7.4 to 7.5, PaCO2 between 23.0 and 35.3, PaO2 of 59.5 to 72.9, and SaO2 91.7% to 96.1%18; furthermore, the Cusco study also found a 0.122 drop in PaO2 and a 0.05% decline in SO2 per each year of life.23

When comparing our findings against studies conducted in Bogotá and Peru,24,25 differences in PaO2 between 18 and 26 mm Hg less than Armenia were identified; the PCO2 is between 2.0 and 2.7-mm Hg higher in our city, and SaO2% is between 3.6% and 6.2% higher also. Likewise, the comparison against the study conducted in Medellin8 at an altitude of 1538-m above sea level, showed very similar results, although in Armenia, the PaO2 and HCO3- values were somewhat higher.

The oxygenation index (PaO2/FIO2) in the study population showed values in the normal range; this indicator is still important as a diagnostic and severity staging criterion in the acute respiratory distress syndrome, and is a marker for evolution and survival.26

In conclusion, this study provided arterial blood gases values at 1600-m above sea level-the geographic location of Armenia. These measurements can be used as a reference for the young, healthy population, with no risk factors for pulmonary disease, and free of any lung pathology. As described in the physiology, the results are significantly different from those reported at sea level and at higher altitudes. The results from this study represent a fundamental tool for the diagnosis, staging, and management of patients with acute or chronic pulmonary disease.

Ethical responsibilities

Protection of persons and animals. The authors declare that no experiments in humans or in animals were conducted for this research.

Confidentiality of information. The authors declare that they have followed the protocols established by their institution on the disclosure of patient information.

Right to privacy and informed consent. The authors declare that this article contains no patient data.

References

1. Trulock EPIII. Walker HK. Arterial blood gases. Clinical methods: the history, physical, and laboratory examinations 3rd ed.Butter-worths, Boston:1990;254Chapter 49. [Accessed 2016 Mar 31]. Available at: https://www.ncbi.nlm.nih.gov/books/NBK371/. [ Links ]

2. Real Academia Española. Diccionario de la Lengua española. 22° ed. 2001. [Accessed 2017 Mar 20]. Available at: http://dle.rae.es/srv/fetch?id=U6hxHwV. [ Links ]

3. Hurtado JC, Salazar T, Peña M. Normal values of the arterial gases in Bogotá. Umbral Científico 2007;1:93-101. [ Links ]

4. Williams AJ. ABC of oxygen: assessing and interpreting arterial blood gases and acid-base balance. BMJ 1998;317:1213-1216. [ Links ]

5. Guyton AC, Hall JE. Guyton AC, Hall JE. Transporte de oxígeno y dióxido de carbono en la sangre y los líquidos tisulares. Tratado de fisiología médica 11 ed. Elsevier, Madrid:2006;502-513. [ Links ]

6. West J. West J. Intercambio Gaseoso. Fisiopatología Pulmonar 6a ed. Editorial Panamericana, Buenos Aires:2004;17-38. Capítulo 2. [ Links ]

7. Rodríguez-Roisin R. Grupo de trabajo SEPAR. Regulation of arterial blood gases analyses. Arch Bronconeumol 1998;34:142-153. [ Links ]

8. Ortega H, Millán A, Mesa GH. Arterial blood gases in healthy adult population of the city of Medellín. Acta Med Colomb 2002;27:98-102. [ Links ]

9. Ganong WF. Ganong WF. Regulación de la respiración. Fisiología Médica 23 ed. Interamericana-McGraw-Hill, Madrid:2011;625-638. [ Links ]

10. Aristizábal-Salazar R, Calvo-Torres L, Valencia-Arango A, et al. Equilibrio ácido-base: el mejor enfoque clínico. Rev Colomb Anestesiol 2015;43:219-224. [ Links ]

11. Tinoco A, Román A, Charri J. Arterial blood gas analysis at different levels of altitude in healthy adult residents of Peru. Horiz Med 2017;17:6-10. [ Links ]

12. Ministerio de Salud de Colombia. Indicadores básicos de salud 2014. 2015. [Accessed 2018 May 15]. Available at: https://www.minsalud.gov.co/sites/rid/Lists/BibliotecaDigital/RIDE/VS/ED/PSP/Indicadores-basicos-salud-2014.pdf. [ Links ]

13. Aristizábal RE, Martínez JW, Montoya-Cañón M, et al. Relationship of acid-base equilibrium and survival in adults with diagnosis of trauma in intensive care unit in San Jorge University Hospital. 2001-2010, Pereira, Colombia. Rev Méd UIS 2015;28:273-280. [ Links ]

14. Carranza-Cortés J. Damage control in abdominal trauma. Anest Méx 2016;28:34-39. [ Links ]

15. EPOC, Manual del sistema. (c)2010 Epocal Inc. 2060 Walkley Road Ottawa, Ontario, Canadá K1G 3P5. 2010. [ Links ]

16. Shrake K, Blonshine S, Brown R, et al. AARC clinical practice guideline: Sampling for arterial blood gas analysis. Respiratory Care 1992;37:913-914. [ Links ]

17. Theodore A. Arterial blood gases. Post TW, ed. UpToDate. Waltham, MA: UpToDate Inc. [Accessed 2017 Mar 15]. Available at: http://www.uptodate.com. [ Links ]

18. Fundación Hospital Universitario San Vicente de Paul. Protocolo de toma, conservación transporte de muestras para exámenes de laboratorio clínico. Versión 9. Medellín:2011. [ Links ]

19. Fundación Neumológica Colombiana. Laboratorio de función pulmonar: Manual de procedimientos. Capítulo 11: Gases Arteriales. 2000. [ Links ]

20. Lasso JI. Interpretation of arterial blood gases in Bogotá (2640-m above sea level) based on the Siggaard-Andersen nomogram, a proposal to facilitate and unify readings. Rev Colomb Neumol 2014;26:25-36. [ Links ]

21. Acevedo L, Solarte I. Arterial blood gases in young adults in Bogotá's altuitude. Acta Med Colomb 1984;9:7-14. [ Links ]

22. Maldonado D, González-García M, Barrero M, et al. Reference values for arterial blood gases at an altitude of 2.640 meters. Am J Respir Crit Care Med 2013;187:A4852. [ Links ]

23. Yumbo C. Study of reference values of arterial blood gases in high-altitude populations. Enferm Tórax 2002;45:40-42. [ Links ]

24. Pereira-Victorio CJ, Huamanquispe-Quintana J, Castelo-Tamayo LE. Arterial blood gases in clinically healthy adults living at 3,350 meters of altitude. Rev Peru Med Exp Salud Publica 2014;31:473-479. [ Links ]

25. Restrepo J, Reyes P, Vasquez P, et al. Arterial blood and alveolar gases in healthy adults in Bogotá’s altuitude. Acta Med Colomb 1982;7:461-466. [ Links ]

26. Miranda M, López-Herce J, Martínez M, et al. Relation between between PaO2/FiO2 and SatO2/FiO2 with mortality and duration of admission in critically ill children. An Pediatr (Barc) 2012;76:16-22. [ Links ]

How to cite this article: Cárdenas-Santamaría FH, Ardila-Flórez M, Jaramillo-Mejía JM, Echeverry-Restrepo V, García-Gutiérrez LA, Londoño-Franco ÁL. Arterial blood gas in young adults at an average altitude of 1605-m above sea level: Armenia, Colombia 2016. Rev Colomb Anestesiol. 2018;46:222-227.

Funding comment This study was entirely funded by a research grant of the Universidad del Quindío, under number 723.

Conflicts of interest The authors have no conflicts of interest to disclose.

* Correspondence: Facultad Ciencias de la Salud, Universidad del Quindío, Cra. 15 Cll 12 norte, Quindío, Colombia. E-mail: angelalilianal@uniquindio.edu.co

Creative Commons License This is an open-access article distributed under the terms of the Creative Commons Attribution License