Accuracy of Handheld Blood Glucose Meters at High Altitude

Pieter De Mol,Hans G Krabbe,Marion J Fokkert,Henk J G Bilo,Bert D Dikkeschei,Karin M Bilo,Suzanna T De Vries,Rienk Rienks,Marian Ludgate

doi:10.1371/journal.pone.0015485

Pieter De Mol, Hans G Krabbe + Show 7 more

Open Access

https://doi.org/10.1371/journal.pone.0015485

Copy DOI

Abstract

BackgroundDue to increasing numbers of people with diabetes taking part in extreme sports (e.g., high-altitude trekking), reliable handheld blood glucose meters (BGMs) are necessary. Accurate blood glucose measurement under extreme conditions is paramount for safe recreation at altitude. Prior studies reported bias in blood glucose measurements using different BGMs at high altitude. We hypothesized that glucose-oxidase based BGMs are more influenced by the lower atmospheric oxygen pressure at altitude than glucose dehydrogenase based BGMs.Methodology/Principal FindingsGlucose measurements at simulated altitude of nine BGMs (six glucose dehydrogenase and three glucose oxidase BGMs) were compared to glucose measurement on a similar BGM at sea level and to a laboratory glucose reference method. Venous blood samples of four different glucose levels were used. Moreover, two glucose oxidase and two glucose dehydrogenase based BGMs were evaluated at different altitudes on Mount Kilimanjaro. Accuracy criteria were set at a bias <15% from reference glucose (when >6.5 mmol/L) and <1 mmol/L from reference glucose (when <6.5 mmol/L). No significant difference was observed between measurements at simulated altitude and sea level for either glucose oxidase based BGMs or glucose dehydrogenase based BGMs as a group phenomenon. Two GDH based BGMs did not meet set performance criteria. Most BGMs are generally overestimating true glucose concentration at high altitude.ConclusionAt simulated high altitude all tested BGMs, including glucose oxidase based BGMs, did not show influence of low atmospheric oxygen pressure. All BGMs, except for two GDH based BGMs, performed within predefined criteria. At true high altitude one GDH based BGM had best precision and accuracy.

Highlights

Regular exercise and a healthy life style should be part of daily life of everybody, but definitely of any person with diabetes mellitus
Hypobaric chamber experiment Each sample was tested in duplicate under hypobaric and normobaric conditions simultaneously, and results are presented as the mean glucose levels with absolute or relative (%) bias from Glucose Hexokinase (GHex) glucose determination
Four of six tested glucose dehydrogenase (GDH) and all three glucose oxidase (GOX) based blood glucose meters (BGMs) performed within predefined performance criteria of 61.0 mmol/ L when reference glucose was,6.5 mmol/L and 615% when reference glucose was .6.5 mmol/L at all simulated altitudes

Summary

Introduction

Regular exercise and a healthy life style should be part of daily life of everybody, but definitely of any person with diabetes mellitus. Increasing numbers of people with diabetes do participate in more strenuous forms of physical activity, amongst others high-altitude trekking and mountain climbing. These kinds of activities do pose special challenges to subjects with diabetes mellitus treated with insulin. Glucose levels have to be kept under good control, and it is a challenge to find a balance between energy intake, energy expenditure, blood glucose levels, and insulin requirements. Due to increasing numbers of people with diabetes taking part in extreme sports (e.g., high-altitude trekking), reliable handheld blood glucose meters (BGMs) are necessary. Prior studies reported bias in blood glucose measurements using different BGMs at high altitude.

Objectives

Methods

Results

Discussion

Conclusion