Review article
The potential of the hydrocarbon breath test as a measure of lipid peroxidation

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Abstract

The straight chain aliphatic hydrocarbons ethane and pentane have been advocated as noninvasive markers of free-radical induced lipid peroxidation in humans. In in vitro studies, the evolution of ethane and pentane as end products of n-3 and n-6 polyunsaturated fatty acids, respectively, correlates very well with other markers of lipid peroxidation and even seems to be the most sensitive test available. In laboratory animals the use of both hydrocarbons as in vivo markers of lipid peroxidation has been validated extensively. Although there are other possible sources of hydrocarbons in the body, such as protein oxidation and colonic bacterial metabolism, these apparently are of limited importance and do not interfere with the interpretation of the hydrocarbon breath test. The production of hydrocarbons relative to that of other end products of lipid peroxidation depends on variables that are difficult to control, such as the local availability of iron(II) ions and dioxygen. In addition, hydrocarbons are metabolized in the body, which especially influences the excretion of pentane. Because of the extremely low concentrations of ethane and pentane in human breath, which often are not significantly higher than those in ambient air, the hydrocarbon breath test requires a flawless technique regarding such factors as: (1) the preparation of the subject with hydrocarbon-free air to wash out ambient air hydrocarbons from the lungs, (2) the avoidance of ambient air contamination of the breath sample by using appropriate materials for sampling and storing, and (3) the procedures used to concentrate and filter the samples prior to gas chromatographi determination. For the gas chromatographic separation of hydrocarbons, open tubular capillary columns are preferred because of their high resolution capacity. Only in those settings where expired hydrocarbon levels are substantially higher than ambient air levels might washout prove to be unnecessary, at least in adults. Although many investigators have concentrated on one marker, it seems preferable to measure both ethane and pentane concurrently.

The results of the hydrocarbon breath test are not influenced by prior food consumption, but both vitamin E and β-carotene supplementation decrease hydrocarbon excretion. Nevertheless, the long-term use of a diet high in polyunsaturated fatty acids, such as in parenteral nutrition regimens, may results in increased hydrocarbon exhalation. Hydrocarbon excretion slightly increases with increasing age. Short-term increases follow physical and intellectual stress and exposure to hyperbaric dioxygen. Several other factors require further evaluation, including normal ranges in infants and children and the effects on the test of altered diffusion and local lipid peroxidation as a consequence of lung disease. The test seems to be unreliable in smokers, because smoking cigarettes results in impressive increase in ethane and penthane exhalation.

Hydrocarbon excretion is increased in a great variety of conditions in which lipid peroxidation was thought to be involved, which confirms both the reliability and the nonspecific nature of the test. Abnormal excretion has been documented in alcoholic and cholestatic liver disease, vitamin E deficiency, pulmonary disease, autoimmune disease, inflammatory bowel disease, ischemia-reperfusion injury, and neurologic disease. In many, if not most, conditions, increased lipid peroxidation is an epiphenomenon instead of playing a pathogenetic role. Therefore, the results of the hydrocarbon breath test should not be regarded in isolation but in the light of clinical and laboratory parameters, including other markers of lipid peroxidation.

In conclusion, the hydrocarbon breath test, being noninvasive, has great potential for the assessment of the role of lipid peroxidation in clinical conditions, as well as for the detection and follow-up of lipid peroxidation-induced disease in clinical practice. Because the test is time-consuming and requires a flawless technique, it is yet unclear whether the test will ever proceed to become a clinical tool.

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    1

    Frank Kneepkens obtained his M.D. degreee in 1974 at Leyden University and his Ph.D. degree in 1986 at Groningen University, The Netherlands. Since 1985 he has been an associate professor in Pediatric Gastroenterology at the Vrije Universiteit and the Free University Hospital at Amsterdam, The Netherlands. His main interest is in breath analysis applied to gastrointestinal conditions. This article results from a postdoctoral fellowship at Hôpital Ste-Justine in 1990 and 1991.

    2

    Guy Lepage worked as a technician for many years in the Gastroenterology Research Unit of Hôpital Ste-Justine before obtaining an M.Sc. degree in clinical sciences in 1992. He is currently pursuing studies leading to a Ph.D. degree at the Université de Montréal. His research focuses on sterol and lipid biochemistry as it relates to cholestasis, malasorption, and malnutrition.

    3

    Claude C. Roy has been Professor of Pediatrics in the Department of Pediatrics at Hôpital Ste-Justine and at the Université de Montréal since 1970. After serving as head of the Pediatric Research Center, he became chief of the Gastroenterology division and is currently chairman of the Department of Pediatrics. For the past few years, the major thrust of his research has been to document the effects of essential fatty acids deficiency on membrane structure and function.

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