INTRODUCTION

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CARBAMAZEPINE (CBZ) is widely used as an anticonvulsant drug in adults and children. The drug is known to cause multiple metabolic alterations, among them changes in serum lipoprotein concentrations (3, 6, 8, 14, 16, 19-21, 29, 30, 32, 36, 42, 43, 46, 47, 51, 53, 54). The precise frequency and nature of these changes are unclear as are the underlying mechanisms of action. In many studies increased total and/or low-density lipoprotein cholesterol (LDL-C) concentrations were found (3, 6, 14, 16, 20, 21, 42, 43, 46, 47, 51), and elevated high-density lipoprotein cholesterol (HDL-C) is also frequently reported (3, 8, 19-21, 29, 36, 42, 47, 51, 53). The interpretation of most studies is limited due to unsatisfactory study designs; there are only four prospective studies (6, 16, 19, 21), whereas all other studies were cross-sectional and a variety of different control groups were used for comparison. In many studies there were antiepileptic comedications. Studies in children are difficult to interpret because lipoprotein profiles change with increasing age. In addition, it cannot be completely ruled out that epilepsy itself can lead to changes in lipoprotein profiles.

Cholesterol concentrations and especially the ratio of LDL-C to HDL-C are relevant determinants for the incidence and mortality from coronary heart disease (2, 9). There is some evidence that coronary heart disease is less common in patients with epilepsy (15, 27, 34), although these data are still uncertain. CBZ is known to be a powerful inducing agent of cytochrome P-450 enzymes (22, 24, 41), and its effects on lipoproteins have been largely attributed to its enzyme-inducing action (12, 31). Overall, however, there is very little information about the metabolic changes that are responsible for the effects of CBZ on lipids and no study controlled for confounding factors such as diet.

The aim of this trial was therefore to investigate prospectively in normolipemic healthy adult volunteers the effects of CBZ on lipoproteins and to employ intraindividual paired data statistics. Furthermore, we were interested in comprehensive analyses of lipid profiles including apolipoproteins. To gain insight into the mechanisms underlying changes in lipids, we conducted elaborate lipoprotein turnover studies using endogenous stable isotope-labeling tracer kinetics and multicompartmental modeling. In addition, we determined cholesterol precursors as markers of cholesterol synthesis (mevalonic acid, lathosterol) and plant sterols as markers of intestinal cholesterol absorption (noncholesterol sterols).

	METHODS

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Subjects

After inclusion, each participant started with treatment of the antiepileptic drug carbamazepine (Tegretol, Ciba-Geigy; Wehr, Germany). To minimize side effects, the dosage was gradually increased during the first 10 days of medication, reaching a constant dosage regimen of 400 mg CBZ bid from day 11 on. During medication, compliance, drug tolerability, and adverse events were checked and recorded. On day 10 and thereafter, CBZ concentrations were determined at weekly intervals. Lipoprotein profiles were determined at regular intervals during treatment to evaluate the time course of lipoprotein changes.

Protocol

The turnover study protocol began in the morning after an at least a 12-h fast. Subjects were admitted to the metabolic ward at 7:00 AM. They were studied in the fasted state and remained supine during the time of infusion and 4 h after its termination. One hour before the infusion was started, each participant drank 400 ml of mineral water to standardize their hydration state. Noncaloric and caffeine-free beverages were allowed ad libitum from 3 h after start of the infusion and thereafter.

One intravenous line was inserted into the left arm for infusion with the deuterated amino acid L-[5,5,5-²H₃]leucine ([D₃]leucine; MassTrace, Woburn, MA) dissolved in buffered saline. The infusion had been shown to be pyrogen free and sterile. A second line was placed intravenously for blood sampling in the opposite arm. At time 0, tracer administration was started with a bolus injection of [D₃]leucine of 1.4 mg/kg body wt immediately followed by a continuous (constant) infusion of [D₃]leucine (1.4 mg · kg¹ · h¹) for a period of 10 h. Four hours after the infusion was stopped, subjects received dinner and then fasted again until after the 24-h blood sample had been drawn.

Blood samples were drawn during the infusion and on the following days in EDTA tubes to which had been added a mixture of inhibitors of enzymes and bacterial growth (sodium azide, chloramphenicol, gentamicin sulfate, and aprotinin). Blood samples were collected at baseline and at various intervals during the infusion and for another 19 days (days 1, 2, 3, 4, 5, 7, 10, 14, and 19) after the end of infusion to determine isotopic enrichment of leucine in plasma as well as in apolipoprotein B (ApoB) in different lipoprotein fractions. During the turnover study, plasma aliquots were taken at seven different time points (four of these were during the infusion) for determination of the ApoB pool size. A 12-h urine collection was conducted during each infusion day.

Dietary protocol and body composition. Dietary intake and body composition were determined thoroughly in the subjects undergoing turnover studies. No specific dietary advice was imposed before the studies. Instead, each participant had to fill in a 7-day food record documenting nutritional intake during the week before onset of the first turnover study (CBZ period). These food records were then handed out to the subjects, and they were instructed to follow this first food record during the week before the second turnover study (control period) started. They were asked in addition to keep a second 7-day food record during that time to assess possible effects of variation in nutritional intake.

Analytic Methods

Carbamazepine determination. CBZ serum levels were measured by a fluorescence polarization immunoassay with an automatic analyzer (TDx, Abbott; Wiesbaden, Germany).

Lipoprotein chemistry. Cholesterol and triglycerides were measured enzymatically in total plasma as well as in the lipoprotein fractions very-low-density lipoprotein (VLDL), intermediate density lipoprotein (IDL), and LDL according to the cholesterol oxidase phenol 4-aminophenazone and the glycerol phosphate oxygen phenol 4-aminophenazone method (Boehringer Mannheim), respectively. HDL-C was determined enzymatically after precipitation of ApoB-containing lipoproteins (7). The concentration of LDL-C was also calculated according to the Friedewald formula (17). The coefficient of variation for cholesterol measurements was 0.99% for total cholesterol, 2.64% for LDL-C, 2.22% for HDL-C, and 1.14% for triglycerides (laboratory day-to-day variation).

Lipoprotein separation. Isolation of the lipoprotein fractions VLDL, IDL, and LDL was performed using preparative sequential density ultracentrifugation. At first, a (3.2 ml) polycarbonate tube was filled with a 1.5-ml aliquot of plasma and a 1.5 ml sodium chloride density solution (0.9%) and centrifuged at 16°C in a TLA 100.4 rotor for 2.5 h at 100,000 g in an Optima TLX centrifuge (Beckmann Instruments). All density solutions used contained 1 g/l EDTA. After centrifugation, the supernatant containing VLDL (density < 1.006) was removed after tube slicing with a CentriTube Slicer (Beckmann Instruments). To isolate the IDL fraction (density = 1.006 to density = 1.019), the remaining infranatant was transferred into a new tube adding a second, more dense sodium chloride density solution (4.5%) and an analogous centrifugation step was started. After tube slicing and transfer of the infranatant in a third new tube was completed, the centrifugation procedure was repeated, this time using an even more dense sodium chloride density solution (15%) to separate the LDL lipoprotein fraction (density = 1.019 to density = 1.063). All isolated lipoprotein fractions were aliquoted and stored frozen for measurement of cholesterol, triglyceride, and ApoB concentrations as well as for ApoB separation for leucine enrichment determination.

Isolation of plasma amino acids. Plasma free amino acids were isolated from 0.5 ml of plasma by cation exchange chromatography. Disposable columns were prepared with 0.6 ml of AG-50W-X8 resin (Bio-Rad Laboratories; Hercules, CA) that had been stored in sodium hydroxide. The amino acids were eluted with ammonium hydroxide, and thereafter the samples were dried with the use of a Savant SpeedVac (Savant Instruments; Framingdale, NY).

Amino acid derivatization. For derivatization the amino acids were esterified with N-propanol and then derivatized with N-heptafluorobutyric anhydride (Pierce; Rockford, IL) to form stable volatile molecules for gas chromatography separation (4). The samples were dissolved in ethyl acetate and transferred into vials for gas chromatography-mass spectrometry analysis.

ApoB separation. The ApoB of the lipoprotein fractions VLDL, IDL, and LDL was isolated and purified using a previously described isopropanol precipitation method (13). The precipitated protein was quantitatively hydrolyzed to amino acids with constant boiling HCl for 24 h at 110°C. The HCl was subsequently evaporated in the SpeedVac centrifuge. The amino acids obtained were then also subjected to cation exchange chromatography and subsequently derivatized.

Determination of enrichment and calculation of tracer-to-tracee ratio. Isotopic enrichment determination of leucine was performed on a Fisons GC8060/Trio 1000 quadrupole system (ThermoQuest; Egelsbach, Germany). The samples were injected into a 30-m × 0.32-mm, 0.25-µm DB-5MS capillary column (J&W Scientific; Rancho Cordova, CA). Mass spectrometry was performed by negative ion chemical ionization with methane as the reagent gas. Selected ion monitoring of the leucine peak was performed for ²H₃ enrichment using the [M  HF] and [M  HF + 3] isotopomers (mass-to-charge ratio = 349 and 352), respectively, where M is mass and HF is hydrogen fluoride. Measurements were done in quadruplicates at baseline and in triplicates in subsequent samples. Because of the nonnegligible mass associated with stable isotope tracers, it was necessary to transform enrichment data to tracer-to-tracee ratios (10).

Kinetic analysis. A multicompartmental model (Fig. 1) was used to describe VLDL-, IDL-, and LDL-ApoB isotopic enrichment data. Each compartment or pool represents a group of kinetically homogenous particles. In the present study, the SAAM II program (SAAM Institute; Seattle, WA) was used to fit the observed tracer data to the model. Metabolic parameters were subsequently derived from the model parameters giving the best fit. The model consists of a precursor compartment of amino acids (compartment 1) and the delay compartment (compartment 2), which accounts for the time required for synthesis and secretion of VLDL ApoB into plasma. Plasma leucine tracer-to-tracee data were fit using the forcing function to drive the appearance of tracer (amino acid) in the compartment model. The purpose of the forcing function is to decouple components of the system under investigation, which obviates the need to model leucine metabolism separately and takes into account the recycling of tracer and thus minimizes its effect on the slow-turnover compartments. Mathematically, the forcing function replaces the amount of tracer in compartment 1 with the value of the amino acid enrichment data used as forcing function (FF) at the same time. In other words, the value of q1(t), the amount of material and tracer in compartment 1 at time t, is replaced by the term q1 × FF(t). We used plasma data to decouple the kinetics of free amino acid from that of the tracer in ApoB.

View larger version (22K): [in this window] [in a new window]   Fig. 1.   Multicompartmental model for apolipoprotein B (ApoB)-100 metabolism. Isotopic enrichment data were fit to tracer-to-tracee ratios. Compartment 1 shows the precursor with plasma leucine enrichment data used as forcing function. Compartment 2 is the delay compartment for intracellular hepatic synthesis and secretion of very-low-density lipoprotein (VLDL)-ApoB-100. Compartments 11, 12, and 13 represent one rapid and two slow VLDL turnover compartments, respectively. Compartments 21 and 22 correspond to a rapid and slow intermediate density lipoprotein (IDL) turnover compartment, and compartment 31 shows the low-density liporprotein (LDL) compartment. Numbers on arrows given as means ± SD are fractional rate constants (k values) expressed in pools per hour for the control (top) and carbamazepine (CBZ) period (bottom).

Determination of plant sterols, cholestanol, and lathosterol. The plant sterols campesterol (24-methyl-cholesterol) and sitosterol (24-ethyl-cholesterol), the 5-cholesterol derivative cholestanol, and the endogenous cholesterol precursor lathosterol were determined by gas liquid chromatography as previously described (5). The concentrations of these compounds are expressed as ratios to cholesterol (µg per mg) to correct for changes in cholesterol concentrations.

Determination of mevalonic acid. Mevalonic acid was determined in serum and in urine as previously described in detail using a highly sensitive isotope dilution gas chromatography-mass spectrometry method (25).

Determination of 6--hydroxycortisol. 6--Hydroxycortisol, a reliable indicator of the degree of enzyme induction, was measured in urine using a sandwich-ELISA (Stabiligen; Nancy, France).

Statistical Analysis

	RESULTS

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Dosage, Compliance, and Tolerability

Body Weight, Body Composition, and Dietary Records

Lipoprotein Concentrations and Composition

During CBZ treatment there were significant increases in all lipoprotein fractions except for HDL-C. Total cholesterol increased by 13 ± 15% (P = 0.002), LDL-C increased by 17 ± 21% (P = 0.004), and triglycerides increased by 18 ± 31% (P = 0.028). The mean values of HDL-C were virtually unchanged (+4 ± 16%, P = 0.45). There was no relationship between changes in LDL-C and CBZ plasma concentrations.

Table 4 shows the lipoprotein concentrations in the 13 volunteers that were studied in more detail with turnover procedures. There was a substantial and significant increase in both cholesterol and ApoB concentration in all ApoB-containing lipoprotein fractions. This increase was most pronounced in IDL (cholesterol, +38 ± 35%; ApoB, +33 ± 36%), followed by VLDL (cholesterol, + 29 ± 21%; ApoB, +29 ± 23%) and LDL (cholesterol, + 10 ± 14%; ApoB, +13 ± 14%). There was also a significant increase in total serum triglycerides (+21 ± 27%). Triglycerides in lipoprotein subfractions increased by 27 ± 37% in VLDL (P = 0.03), 60 ± 80% in IDL (P = 0.035), and 35 ± 41% in LDL (P = 0.011), individual data not shown.

Table 5 shows the average changes in lipoprotein particle composition, as indicated by ratios of cholesterol to ApoB, cholesterol to triglycerides, and triglycerides to ApoB. None of these ratios showed significant differences. The relation of cholesterol to ApoB and to triglycerides remained remarkably stable, indicating that CBZ-induced changes altered the content of these lipoprotein particles in a similar unidirectional fashion. Triglyceride content in relation to ApoB seems to increase in denser lipoproteins (IDL, LDL), although this tendency also did not reach statistical significance.

Lipoprotein Kinetics

View larger version (16K): [in this window] [in a new window]   Fig. 2.   VLDL-, IDL- and LDL-ApoB tracer-to-tracee ratios of observed data (symbols) and calculated fits (lines) using the multicompartmental model in a representative normolipemic healthy volunteer.

Plant Sterols, Cholestanol, and Cholesterol Synthesis Precursors

6--Hydroxycortisol Concentrations

	DISCUSSION

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As the main result of this prospective study in normolipemic volunteers, we found unexpectedly no change in HDL-C concentrations during treatment with CBZ. A marked increase in HDL-cholesterol was seen only in two subjects (subjects 2 and 20). This is in contrast to most other studies that have reported a significant increase in HDL-C concentration (3, 8, 20, 30, 36, 42, 47). The present results are well in accordance with those from a prospective study of Isojärvi et al. (21), who found a significant increase in HDL-C in patients with idiopathic epilepsy for the total group investigated but could not be confirmed for the subgroup of men.

In addition, in the present study, a significant increase was observed in triglycerides and in total and LDL-C concentrations by 18%, 13%, and 17%, respectively. Other studies have also shown markedly elevated LDL-C levels (8, 14, 21, 42, 43, 46, 47, 51), although not always being consistent for both males and females (8, 20, 21, 42, 47). Hindi et al. (20) found a significant increase in LDL-C in females, whereas Calandre et al. (8) only observed an increase in men. Isojärvi et al. (21) and Sudhop et al. (47) found significantly higher LDL-C concentrations in both sexes compared with a control group.

Elevated total cholesterol, LDL-C, and triglyceride levels are known cardiovascular risk factors, whereas a protective role has been established for HDL-C (2). The ratios of total cholesterol to HDL-C and LDL-C to HDL-C, known as relevant predictors for the prognosis of coronary heart disease, changed to more unfavorable ratios in this study with borderline significant differences (4.4 ± 1.0 vs. 4.7 ± 0.9, P = 0.073, and 2.9 ± 0.8 vs. 3.2 ± 0.8, P = 0.067, respectively). Similar results were observed in most studies comparable in design to our study (20, 42, 47, 54). There is some evidence that coronary heart disease may be less common in patients with epilepsy (15, 27, 34), raising the question whether drugs like CBZ contribute to a more favorable lipid profile and may thus be responsible for this observation. From the changes in lipid profiles in this and the aforementioned studies, especially with regard to elevated LDL-C and triglycerides in men (with unchanged HDL-C levels), a protective effect of long-term CBZ treatment to the risk for cardiovascular disease has to be questioned.

Apart from drug treatment effects, it cannot be excluded that the disease itself may affect lipoprotein concentrations, although there is no publication having explicitly addressed this issue. Therefore, to rule out a possible influence on changes in lipoprotein metabolism caused by epilepsy, healthy individuals were investigated in the present study. In contrast to this, previously published trials examining the effects of anticonvulsant drugs on lipoprotein metabolism were mostly conducted in patient cohorts (mainly in epileptic patients).

Shortcomings of most studies investigating patients receiving various drugs or combinations of anticonvulsant drugs are small sample sizes if subgroup analyses are made for patients receiving only monotherapies. In some studies, especially in the CBZ-treated subgroups, the number of males was small (6, 8, 30, 53). To exclude the influence of other drugs and to take sex differences in lipoprotein metabolism into account, only male subjects receiving monotherapy with CBZ were investigated in the present study.

Contradictory results in lipoprotein concentrations during treatment with anticonvulsant drugs may at least in part be due to differences in the quality of lipid/lipoprotein determinations. Usually little is known about the quality of lipid determinations. Most studies are based on one single measurement of the lipoprotein concentration that does not take into account intraindividual variations. A single measurement of lipid concentrations may cause misleading interpretations of the relationship between lipoprotein concentration and the parameter(s) of interest. To ensure high-quality measurement in the present study, lipoprotein concentrations were determined as the means of three independent blood samples. In 23% of all subjects interday variation coefficients of greater than 10% were found for LDL-C as were 14% and 18% for total cholesterol and HDL-C, respectively. We therefore conclude that on the basis of precise measurements of lipoprotein concentrations, reliable estimation of changes in concentrations was possible. In addition, during the turnover studies, lipid concentrations (cholesterol, ApoB, and triglycerides) in the lipoprotein subfractions VLDL, IDL, and LDL were determined as means of seven independent blood samples in the control and CBZ period.

Furthermore, 7-day food records were assessed to control for dietary intake during the week before the infusion day in both periods. Nutritional intake may be an important influencing and/or confounding factor on lipoprotein metabolism. In this study, caloric and macronutrient intakes were virtually unchanged. An influence of monounsaturated fat on hepatic ApoB production could not be observed; the slight shift to a more favorable intake of monounsaturated fat did not correlate with changes in VLDL-ApoB FCR and VLDL-ApoB PR. We conclude that reliable results of kinetic parameters in ApoB metabolism were assessed in both the control and CBZ treatment period.

The changes in lipoprotein concentrations observed during the intake of CBZ may possibly be due to the direct influence of CBZ on physiological mechanisms during endogenous synthesis or catabolism of cholesterol. An influence of CBZ on endogenous cholesterol synthesis in the liver has been discussed before (6, 28). The concentration of mevalonic acid in plasma reflects the activity of 3-hydroxy-3-methylglutaryl-CoA (HMG-CoA) reductase and was determined as an indicator of cholesterol synthesis in vivo in our study. Because concentrations of mevalonic acid in plasma might be subject to diurnal rhythm (38), mevalonic acid in urine and lathosterol concentrations in serum were determined as well. The latter is considered to be a valid indicator of whole body cholesterol synthesis in humans (23). Both changes in mevalonic acid and lathosterol concentrations (expressed as ratio lathosterol to cholesterol) did not correlate with changes in VLDL-ApoB FCR and PR (even after correcting for body weight), although during treatment with CBZ, mevalonic acid in serum was positively correlated with VLDL-ApoB and VLDL-C concentration (r = 0.87, P = 0.01; r = 0.64, P = 0.035, respectively). A direct relation between the hepatic VLDL-ApoB secretion and cholesterol precursor had been demonstrated in some (44, 52), but not in all, studies (45). Sudhop et al. (47) have also shown that the concentration of lathosterol is unchanged in CBZ-treated epileptic patients during long-term medication. From these results we conclude that CBZ does not directly influence endogenous cholesterol synthesis. It seems therefore unlikely that the increase in LDL-C concentration in this study is due to an increase in HMG-CoA reductase activity. There are, however, other microsomal enzymes involved in lipid metabolism as possible targets of direct CBZ effects. Recently, overexpression of the microsomal triglyceride transfer protein has been shown to increase VLDL-ApoB and VLDL-triglyceride secretion in the liver (49). Whether treatment with CBZ might affect these microsomal processes can only be speculated about.

Serum levels of plant sterols are regulated by their dietary intake, intestinal absorption, and biliary secretion. They have been reported to correlate negatively with cholesterol synthesis and positively with cholesterol absorption (33). In this study, sitosterol and campesterol concentrations showed a tendency toward increase during drug treatment, although not reaching statistical significance. Baseline lathosterol correlated negatively (r = 0.45, P = 0.045) with campesterol levels, but not with sitosterol. During treatment with CBZ, the concentration of sitosterol and campesterol showed no correlation with mevalonic acid concentration and its change as did percent change of lathosterol. We conclude from these results that an influence of treatment with CBZ on cholesterol absorption is unlikely.

The plasma concentrations of CBZ may have an influence on the extent of changes in lipoproteins, since low drug levels may be devoid of metabolic and therapeutic effects. In this study, mean CBZ concentrations were found to be in the lower therapeutic range. They did neither correlate with total cholesterol, LDL-C, or HDL-C or triglycerides nor with the percent lipoprotein changes during drug administration. Other authors (6, 8, 46, 47, 51) have also reported no correlation between CBZ and lipoprotein concentrations, although sometimes higher CBZ levels in serum (7-9 µg/dl) were achieved. The ratios of daily CBZ doses per kilogram body weight to the plasma concentrations achieved are shown in Fig. 3. This level-to-dose ratio could be of greater value to correct for autoinducing effects of the drug, because drug dose has been shown to be a better predictor of metabolizing capacity than plasma levels (39). There was a significant linear relationship between dosage corrected for body weight and plasma concentrations. Changes in LDL-C levels were however not correlated with level-to-dose ratios (Fig. 4). These results are in accordance with other studies (6, 30, 47) and speak against the enzyme induction being the major mechanism underlying LDL-C increase. In the literature, the enzyme-inducing properties of CBZ have usually been used to explain changes in lipoprotein profiles. CBZ acts primarily as microsomal enzyme inducer of the cytochrome P-450 system in the liver and intestine (28, 39, 48). In contrast to CBZ, other drugs that have been studied for their enzyme-inducing effects on serum lipoprotein concentrations failed to affect lipid profiles in the same manner. For example, rifampicin and antipyrine do not alter lipoprotein concentrations (35), but ketoconazole, a cytochrome P-450 inhibitor, has been found to decrease lipoprotein (total and LDL-C) levels (18). Therefore, enzyme-inducing properties as a general principle of cholesterol increase are unlikely.

View larger version (19K): [in this window] [in a new window]   Fig. 3.   Plasma concentration of CBZ (µg/ml) in relation to drug dose given corrected for body weight (mg · kg body wt1 · day1). A linear relationship could be observed (r = 0.42, P = 0.06); ignoring one data point as an outlier (possible compliance problem) would have resulted in a highly significant correlation (r = 0.64, P = 0.002). Level-to-dose ratios were in a very narrow range (0.54 ± 0.09). Individual CBZ concentrations of 21 subjects are means ± SD of two independent measurements during drug treatment at the end of the treatment phase.

View larger version (16K): [in this window] [in a new window]   Fig. 4.   Percent change in LDL-cholesterol concentration during treatment with CBZ in relation to CBZ level-to-dose ratios (calculated as ratio of daily dose per kg body weight to the plasma concentration achieved). Percent change in LDL-cholesterol was calculated between baseline (as mean value of 3 independent fasting blood samples on 3 different days), and mean value of 3 independent measurements during treatment with CBZ at the end of treatment period.

A significant increase in -GT concentrations during CBZ treatment support the role of CBZ as inducing agent. On average, -GT concentrations increased by 138%. Isojärvi et al. (21) have also shown an increase in -GT concentrations during CBZ treatment in patients with idiopathic epilepsy. But it still has to be considered that changes in liver enzyme concentrations may not sufficiently prove the enzyme-inducing effects because nonmicrosomal factors may influence -GT concentrations (28). To further verify the microsomal effects of CBZ, the concentration of 6--hydroxycholesterol in urine, a reliable indicator of enzyme induction, was found to be increased during treatment with CBZ. A correlation between changes in LDL-C and 6--hydroxycholesterol, however, was not observed.

The enzyme-inducing effects of CBZ were thought to be responsible for changes in lipoprotein concentrations as well as for changes in thyroid and sex hormone concentrations during treatment with CBZ by some authors (11, 12, 32). It has been assumed that a strong induction of these cytochrome P-450 enzymes is associated with high levels of HDL-C (and low LDL-C) (8, 32). This could not be confirmed in the present study. Nevertheless, a decrease in concentrations of free thyroxine and free triiodothyronine demonstrated an enhanced plasma clearance during treatment with CBZ caused by induction of hormone-metabolizing enzymes. In other studies a decrease in ApoB-containing lipoprotein particles during thyroxine therapy was described (1, 26, 37, 50). Interestingly, in the present study changes in thyroxine and IDL-C concentrations during CBZ administration showed a marked negative correlation (r = 0.81, P = 0.015). These results are in accordance with a study by Asami et al. (1), who found that the IDL fraction correlates inversely with free thyroxine serum levels, suggesting that thyroxine promotes the conversion of IDL to LDL, possibly by its stimulatory effect on hepatic lipase activity. Because, from the results of our kinetic modeling study, the conversion of IDL into LDL was diminished during treatment with CBZ, we assume that reduced thyroxine concentrations may be responsible for diminished activity of the lipoprotein delipidation cascade as a consequence of decreased lipase activities. Increased triglyceride content of IDL particles are well in line with this possible mechanism. It still has to be proven in further studies whether CBZ directly shows an influence on lipase activities. The CBZ-induced changes in the kinetic parameters of lipoprotein turnover showed otherwise a large variability between subjects, and there was no association between changes in lipoprotein concentrations. Thus drug effects on lipoprotein secretion or catabolism can be excluded as the responsible mechanism. Because of the elaborate and costly character of the turnover procedures, we were not able to perform a true randomized crossover design to determine lipoprotein kinetics; however, we believe that this did not affect the results.

In conclusion, the present trial indicates that the increase in LDL is neither related to its increased production nor to decreased catabolism of ApoB-containing lipoproteins but rather to changes in conversion of IDL particles. Treatment with CBZ does not directly influence endogenous cholesterol synthesis. It seems unlikely that induction of cytochrome P-450 enzymes influences cholesterol metabolism directly. Whether the increase in LDL-C concentrations is mediated through effects of CBZ on thyroid hormones has to be clarified. The influence of long-term CBZ treatment with regard to elevated total and LDL-C concentrations on cardiovascular risk should be reevaluated in epileptic patients.