Evidence for increased lipid peroxidation in multiple sclerosis

Pentane and ethane are degradation products of unsaturated fatty acids which are released during lipid peroxidation. In order to assess whether multiple sclerosis is associated with lipid peroxidation, we measured pentane and ethane excretion by 16 patients with multiple sclerosis and compared them to healthy control subjects. Patients with acute exacerbation of multiple sclerosis had significantly higher concentrations of pentane (10.5±4.2 nmol/l)(p<0.01) compared to either patients in remission (4.5±1.7 nmol/l) or control subjects (4.9±1.1 nmol/l). The concentrations of ethane were not significantly different among these groups. Of the patients with acute exacerbation who later achieved remission, the pentane excretion also returned to normal (5.6±0.9 nmol/l). One patient who failed to reachieve clinical remission continued to excrete large amounts of pentane. We conclude that oxygen free radical activity is enhanced during exacerbation multiple sclerosis.     

In vivo lipid peroxidation in man as measured by the respiratory excretion of ethane, pentane, and other low-molecular-weight hydrocarbons

A method for the collection and measurement of low-molecular-weight volatile hydrocarbons exhaled in human breath as a result of lipid peroxidation in vivo is described. Subjects breathed in a closed-circuit rebreathe system and samples were taken over a 2-h period, extracted, and analyzed by gas-liquid chromatography isothermally on a 3-m column of n-octane/Porasil-C. Immediately, prior to rebreathing subjects were equilibrated with scrubbed air containing very low ambient levels of hydrocarbons to eliminate the effects of previous exposure to hydrocarbon-contaminated environments. Only under these conditions could hydrocarbon exhalation be measured. In the rebreathe system C3-C5 hydrocarbon concentrations increased linearly initially but reached a steady state after 1.5 h while ethane did not approach equilibrium even after 2 h. The steady-state equilibrium was demonstrated to be due to tissue uptake and metabolism of the hydrocarbon gases. Ethane metabolism was slow, allowing calculation of the endogenous production from the initial rate of change in concentration and an experimentally determined total body solubility coefficient. Similar calculations for pentane were not valid as metabolism was rapid; therefore production was estimated from the equilibrium value reached after 2 h. Ethane production in six healthy subjects was calculated to be 95.1 +/- 19.0 pmol/kg/h while equilibrium values for pentane were 120 +/- 50 pmol/liter. This method now allows the quantitation in man of lipid peroxidation in vivo.     

Methods for measuring ethane and pentane in expired air from rats and humans

Numerous studies in animals and humans provide evidence that ethane and pentane in expired air are useful markers of in vivo lipid peroxidation. The measurement of breath hydrocarbons, being noninvasive, is well suited for routine use in research and clinical settings. However, the lack of standardized methods for collecting, processing, and analyzing expired air has resulted in the use of a wide variety of different methods that have yielded highly disparate results among investigators. This review outlines the methods that we have developed and validated for measuring ethane and pentane in expired air from rats and humans. We describe the advantages of these methods, their performance, as well as potential errors that can be introduced during sample collection, concentration, and analysis. A main source of error involves contamination with ambient-air ethane and pentane, the concentrations of which are usually much greater and more variable than those in expired air. Thus, it appears that the effective removal of ambient-air hydrocarbons from the subject's lungs before collection is an important step in standardizing the collection procedure. Also discussed is whether ethane or pentane is a better marker of in vivo lipid peroxidation.     

Consumption of pentane by hepatic microsomes and consequences on pentane measurement in exhaled gases

Pentane measurement in exhaled gases was proposed as a safe method to evaluate the importance of lipoperoxidation in vivo, in man and in animals. However we have observed that pentane, which arises from lipoperoxide decomposition, is significantly consumed by cytochrome P-450-rich liver microsomes. This pentane consumption is completely inhibited after heating the microsomes at 100 degrees C, and is considerably reduced by metyrapone, a cytochrome P-450 inhibitor. Hepatic metabolism of pentane, particularly after cytochrome P-450 induction, constitutes a risk of error, when pentane exhalation is taken as an index of lipoperoxidation in vivo.     

A general model for aerobic yeast growth: batch growth

A general model for aerobic yeast growth in batch culture is presented. It is based on the concept that the aerobic metabolism of all yeasts is determined by the relative sizes of the transport rate of sugar into the cell and the transport rate of respiratory intermediates into the mitochondrion. If the rate of sugar uptake rate exceeds the rate of transport of respiratory intermediates into the mitochondrion (as in Saccharomyces cerevisiae, S. uvarum, and S. pombe), the metabolism exhibits the features of ethanol excretion and limited specific oxygen uptake rate. If the rate of transport of respiratory intermediates into the mitochondrion is of the same order as the transport of sugar into the cell (as in Candida utilis), the metabolism is characterized by little or no ethanol excretion and a much higher specific oxygen uptake rate. Batch data from an extensive range of yeast and carbon sources is used to illustrate the use of this model. The ability of this model to fit such an extensive range of experimental data suggests that it can be used as a generalized model for aerobic yeast growth.     

Effect of alcoholic cirrhosis on ethane and pentane levels in breath

Lipid peroxidation can be monitored by measuring one or several highly volatile alkanes in exhaled air. The concentrations of ethane and pentane were determined in breath samples from patients with alcoholic and non-alcoholic cirrhosis as well as from healthy subjects. The greatest increase of exhaled pentane was found in 17 patients with alcoholic cirrhosis (2.85 +/- 2.37 pmol/ml) in comparison with 10 patients with non-alcoholic cirrhosis (0.71 +/- 0.33 pmol/ml) and 10 control subjects (0.59 +/- 0.41 pmol/ml). On the contrary, no significant difference was detected as far as exhaled ethane is concerned. These data suggest that: a) gas-chromatographic determination of exhaled pentane may play a significant role in detecting alcohol-induced liver disease; b) hepatic injury may be mediated by lipid peroxidation in these patients.     

The effect of exhaustive exercise on expired pentane as a measure of in vivo lipid peroxidation in the rat

The concentrations of pentane and ethane in the expired breath of swimming rats were used to determine the possible occurrence of lipid peroxidation caused by strenuous exercise. Rats swum to exhaustion produced significantly more pentane but not ethane than did rats at rest. Rats fed a vitamin E-deficient diet produced slightly more pentane following exhaustive exercise than they did while at rest, but this increase was not statistically significant. Rats were also swum for prescribed lengths of time. Only rats that had swum for 20 or 40 min had significantly elevated concentrations of pentane in the breath. Rats swum for 10 or 30 min had elevated concentrations of pentane in the breath, but these increases were not statistically significant. These results suggest that lipid peroxidation is moderately increased following exhaustive exercise.     

Normal copper metabolism in quaking mice

This research measured lipid peroxidation products in rats of varying age by a new method. Wistar male rats, 4, 12, 22 and 32 months old, were examined for lipid peroxidation in vivo by measurement of ethane, ethylene, butane and pentane in breath gases of intact animals. In the older rats, the amounts of the four hydrocarbons exhaled were greater than those in younger rats. All hydrocarbons tested were related to age by an exponential relationship, and quantitatively, ethane and ethylene were related to age with a linear regression fit correlation coefficient, 0.466–0.622 (p<0.01-0.001). When hydrocarbon gas production of 32 month-old rats was compared with that of 4 month-old rats, the greatest ratio was that for pentane (1.99). The following order was ethylene >ethane>butane. There were significant differences in the production of all hydrocarbons between 32 month-old rats and 4 month-old rats.Thiobarbituric acid reactants in serum exhibited an increasing tendency with age, but the values of 32 month-old rats were lower than those of 22 month-old rats. However, the differences between the age groups were not significant.These results showed that the measurement of hydrocarbons in the rats'breath was a sensitive index of in vivo peroxidation during aging.     

A practical and reliable method for measuring ethane and pentane in expired air from humans.

We describe a method for the collection of expired air and further document the performance of our analytical technique that is used to measure ethane and pentane simultaneously. Four minutes of breathing hydrocarbon-free air before collection effectively removed high concentrations of residual ambient ethane and pentane from the lungs, with washout times up to 30 min resulting in no further reductions in breath hydrocarbons. Mean (+/-SE) exhalation rates (pmol/kg b.wt./min) in 11 subjects were 2.4 +/- 0.6 for ethane and 1.5 +/- 1.3 for pentane. Total intraindividual variability in exhalation rates (as percent coefficient of variation, %CV), measured from 4 subjects on at least 6 different days, was greater for pentane (44% CV) than for ethane (29% CV). Analytical variability contributed 6% to the total %CV. Advantages of the method are described, and reasons for the large variability in values reported in the literature are discussed.     

Some Physical and Chemical Properties of Nuclease P1

The inhibitory action of compressed hydrocarbon gases on the growth of the yeast Saccharomyces cerevisiae was investigated quantitatively by microcalorimetry. Both the 50% inhibitory pressure (IP₅₀) and the minimum inhibitory pressure (MIP), which are regarded as indices of the toxicity of hydrocarbon gases, were determined from growth thermograms. Based on these values, the inhibitory potency of the hydrocarbon gases increased in the order methane << ethane < propane < i-butane < n-butane. The toxicity of these hydrocarbon gases correlated to their hydrophobicity, suggesting that hydrocarbon gases interact with some hydrophobic regions of the cell membrane. In support of this, we found that UV absorbing materials at 260 nm were released from yeast cells exposed to compressed hydrocarbon gases. Additionally, scanning electron microscopy indicated that morphological changes occurred in these cells.     

In vivo breath alkane as an index of lipid peroxidation

Interaction of active oxygen species with polyunsaturated fatty acids (PUFA) results in a series of reactions called lipid peroxidation. During the process of peroxidation of polyunsaturated fatty acids there is a scission of an alkane fragment extending from the methyl end of the fatty acid to the double bond. Thus, with a w-6 polyunsaturated fatty acid pentane is released, and with a w-3 polyunsaturated fatty acid ethane is released. These hydrocarbons are distributed in the body, partly metabolized, and excreted in the breath, making it possible to estimate the magnitude of in vivo lipid peroxidation by measuring pentane and ethane exhaled in breath. Advantages of this method are discussed as well as limitations and possible sources of error.     

Effects of vitamin E, ascorbic acid and mannitol on alloxan-induced lipid peroxidation in rats

ω6- and ω3-unsaturated lipid hydroperoxides decompose to yield pentane and ethane, respectively. Alloxan toxicity was studied in rats in relation to pentane and ethane produced during lipid peroxidation induced by intraperitoneal injection of 20 mg of alloxan/100 g body wt. Fifteen minutes after injection, vitamin E-deficient rats exhaled 102- and 11.2-fold more pentane and ethane, respectively, than prior to injection. Injection of 75 mg ascorbic acid/100 g body wt 30 min prior to alloxan treatment prolonged the time over which peroxidation occurred and all vitamin E-deficient rats died before 4 h. Vitamin E-deficient rats injected with 100 mg of the radical scavenger mannitol/ 100 g body wt 30 min prior to alloxan treatment were completely protected against lipid peroxidation, and none of the rats died by 4 h. Rats fed 40 iu dl-α-tocopherol acetate/kg diet or injected with 100 mg dl-α-tocopherol/100 g body wt were either totally protected against alloxan and alloxan-ascorbic acid-induced peroxidation or were only slightly affected as shown by very low-level pentane and ethane production. Thiobarbituric acid reactants in plasma, liver and pancreas 4 h after alloxan treatment reflected the prooxidant nature of ascorbic acid and alloxan, the vitamin E status of the rats and the protective effect of mannitol. Plasma glucose levels 4 h after alloxan injection were lowest in vitamin E-injected rats and highest in vitamin E-deficient rats. Only in vitamin E-deficient rats were both lipid peroxidation and significantly elevated plasma glucose levels observed by 4 h post-alloxan treatment.     

Stimulation of lipid peroxidation by methyl mercury in rats

As an index lipid peroxidation, thiobarbituric acid (TBA)-reactive substances in the liver, kidney, and serum, and hydrocarbons (ethane and pentane) in the exhalation of rats injected subcutaneously with 10 mg/kg/day of methylmercuric chloride (MMC) were determined. Formation of TBA-reactive substances in the liver and kidney of rats was significantly increased 4 and 2 days after initial injection of MMC, respectively. The result for serum was similar to that for the kidney. The maximum ethane production in the exhaled gases was observed 4 days after initial injection of MMC, and thereafter decreased slowly. Pentane production was significantly increased 5 days after initial injection of MMC, and thereafter continued to increase. Glutathione peroxidase activity and amount of vitamin C in the liver were depleted 4 days after initial injection of MMC; vitamin E was not depleted. In the kidney, significant decreases of glutathione peroxidase activity and vitamin C content were also seen 4 days after initial injection of MMC, but vitamin E content was unaltered.Thus, a clear increase of lipid peroxidation as determined by measurement of TBA-reactive substances in tissues and of hydrocarbons in the exhaled gases of rats after MMC treatment was demonstrated, though there was a lag phase of several days before the increase of lipid peroxidation. It is suggested that the significant increase of lipid peroxide formation may be a result of depletion of defending factors against lipid peroxidation.     

Elevated breath pentane in heart failure reduced by free radical scavenger

Pentane, a product of lipid peroxidation, has been detected in situations involving ischemic injury. Such injury may be limited if lipid peroxidation can be controlled by antioxidants. The role of lipid peroxidation in chronic heart failure (CHF) was assessed by measuring breath pentane in patients with CHF vs. age matched controls. The effect of a free radical scavenger on pentane released during CHF was also measured. Pentane levels were correlated with the daily dose of captopril, a sulfhydril-containing drug used to treat CHF, which is an angiotensin converting enzyme inhibitor. To separate the scavening effects of captopril from the pharmacologic effects of converting enzyme inhibitors, a crossover study using a nonsulfhydril inhibitor was used. Patients with CHF excreted (p < 0.005) hich concentrations of pentane (5.7 ± 2.1 vs. control 3.6 ± 1.2 nmol/l). Patients treated with captopril also had significantly higher (p < 0.05) excretion of pentane than the control patients (4.7 ± 1.3 vs. 3.6 ± 1.2 nmol/l). The dose of captopril was inversely proportional to the concentration of pentane excreted (r = 0.55, p < 0.05). Pentane excretion during captopril therapy was significantly lower before (p < 0.01) and after (p < 0.02) nonsulfhydril inhibitor therapy. Conclusion: breath pentane is elevated in CHF and it can be reduced by a free radical scavenger. This reduction of pentane excretion is not a converting enzyme inhibitor class effect.     

Metabolism of 2,3-diaminopropionate in the rat

L-[U-¹⁴C]-2, 3-diaminopropionate was metabolised slowly in the rat. Nearly 75% of the total radioactivity could be accounted for by respiratory CO2 (60%) and by the concentration of the isotope in the liver and kidney (15%). The rate limiting step in its metabolism may be the activity of 2, 3-diaminopropionate: ammonia lyase in the liver. It is more readily metabolised than its 3-oxalyl derivative, which is neurotoxic.     

A Lack of Specificity for Ethylene-induced Mitochondrial Changes

A critical evaluation was made of the hypothesis that the primary mode of action of ethylene in inducing physiological responses is by changing the permeability of cell organelles. The parameter investigated was the evaluation of the influence of ethylene and other gases on mitochondrial oxidation and swelling. Spectrometric evidence demonstrated that mitochondria prepared with good respiratory control can be induced to swell more rapidly with ethylene and other aliphatic gases (ethane, propene, propane, I-butene) in test solutions of 0.125 m KCl. The fact that saturated as well as unsaturated hydrocarbon gases elicited similar changes provides evidence that ethylene does not directly alter membrane permeability as its mechanism of action.     

An investigation of d-{1-13C} xylose metabolism in Pichia stipitis under aerobic and anaerobic conditions

Summary The uptake of d-{1-¹³C} xylose, the accumulation of intermediates and the distribution of the label in ethanol in Pichia stipitis under aerobic and anaerobic conditions were investigated by nuclear magnetic resonance spectroscopy. The rate-limiting step of d-xylose metabolism under aerobic conditions appeared to be uptake, whereas under anaerobic conditions it was the conversion of xylitol to xylulose. The yeast showed no preference to either the alpha-or beta-forms of d-xylose. Under anaerobic conditions only {2-¹³C{ ethanol was detected and this suggests that NADH but not NADPH was used as cofactor in the conversion of xylose to xylitol. d-Xylose is most likely metabolised by the pentose phosphate pathway in this yeast.     

The Relationship Between Lipid Composition of Red Blood Cells and Their Susceptibility to Lipid Peroxidation

Red blood cells from 31 healthy donors were examined for the cholesterol content, the fatty acid composition. and the susceptibility to lipid peroxidation induced by either hydrogen peroxide or phenylhy-drazine. Lipid peroxidation was monitored by the release of pentane and ethane. In addition, plasma fatty acids were measured in order to find out, whether plasma and red cell fatty acids were correlated. In experiments with hydrogen peroxide, a significant positive correlation was found between the proportion of arachidonic acid (C 20:4n – 6; r = 0.57, p < 0.01) and docosahexaenoic acid (C 22:6; - 3; r = +0.71, p < 0.01), and the release of pentane and ethane, respectively. A significant negative correlation was found between the membrane cholesterol content and the pentane release (r -0.44, p< 0.05). In experiments performed with phenylhydrazine, red cell membrane lipid composition did not influence the susceptibility of red cells to lipid peroxidation. A close correlation was found between plasma and red cell fatty acids (palmitic acid, r = +0.46, p < 0.01; linoleic acid, r = +0.41, p < 0.05; arachidonic acid, r = +0.59, p < 0.01; docosahexaenoic acid, r = +0.67, p < 0.01). The results demonstrated that the degree of peroxide-induced oxidation of erythrocyte lipids depends on the content of polyunsaturated fatty acids in the membrane, which on the other hand, is determined by plasma fatty acids. It is suggested that dietary variations may influence the susceptibility of red cells to lipid peroxidation.     

Caffeic acid derivatives in artichoke extract are metabolised to phenolic acids in vivo

The purpose of this study was to investigate the absorption and metabolism of hydroxycinnamates from artichoke extract by determining the urinary excretion of the conjugates. Ten healthy, non smoking volunteers (5 female, 5 male) were given three capsules containing artichoke extract every 4 h (0, 4, 8h) following two days of a low-polyphenol diet. One capsule contained 320 mg of artichoke extract equivalent to 34.3 ± 0.6 mg/g hydroxycinnamates (caffeic acid derivatives) and 5.6 ± 0.1 mg/g flavonoids. Polyphenols and phenolic acids present in the artichoke extract were not detected in the urine either as conjugates or aglycones. However, ferulic, isoferulic, dihydroferulic and vanillic acid were identified as major metabolites after β-glucuronidase treatment of urine. The amount excreted as well as the ratio to that of creatinine, a biomarker for the general excretion rate, increased significantly on the study day compared to the presupplementation day. Thus, the caffeic acid esters found in the artichoke extract capsule are absorbed, metabolised and excreted as methylated phenolic acids such as ferulic, isoferulic, dihydroferulic and vanillic acid.