Abrupt awakening phenomenon associated with gamma-hydroxybutyrate use: a case series.

Case reports mention a sudden awakening from GHB-associated coma but do not specify its time course. The aim of the present case series was to investigate the time course of the awakening from GHB intoxication and the relationship to plasma concentrations of GHB and the presence of other drugs. Unconscious (GCS or=12 was 30 minutes (range 10 to 50 minutes). A subgroup of five patients had a GCS of 3 upon arrival and remained at 3 for a median time of 60 minutes (range 30 to 110 minutes), while the median time for the transition between the last point with GCS 3 and the first with GCS 15 was 30 minutes (range 20 to 60 minutes). This case series illustrates that patients with GHB intoxications remain in a deep coma for a relatively long period of time, after which they awaken over about 30 minutes. This awakening is accompanied by a small change in GHB concentrations. A confounding factor in these observations is co-ingested illicit drugs.

Medical problems related to recreational drug use at nocturnal dance parties.

During 'I love techno' (edition 2001), an indoor rave party attended by 37 000 people, data about medical problems (especially drug-related problems) were collected. To place these data in a wider perspective, a similar registration was done during 'De Nacht', a traditional New Year's Eve dance party held at the same location and attended by 12 000 people. Furthermore, a prospective study on the time course of the level of consciousness (Glasgow Coma Score) and blood concentrations of illicit drugs, especially gamma-hydroxybutyrate was set up. The results revealed that during 'I love techno' the incidence of medical problems was high (66.5/10 000 attendees), but not higher than during 'De Nacht' (70.0/10 000 attendees). At 'I love techno', however, mainly illicit drugs were used, more frequently leading to severe drug-related medical problems. The observations in patients with a drug-related medical problem who had taken gamma-hydroxybutyrate showed that for a given level of consciousness the gamma-hydroxybutyrate concentrations may show important differences, that the transition from coma (Glasgow Coma Score < or =7) to full recovery (Glasgow Coma Score 15) takes only 30-60 min (and only a small decrease in gamma-hydroxybutyrate concentrations), and that the time it takes before a comatose patient reaches the above-mentioned 'transition area' may be a few hours.

Comparative kinetics of the uremic toxin p-cresol versus creatinine in rats with and without renal failure.

BACKGROUND: p-cresol, which is extensively metabolized into p-cresylglucuronide in the rat, is related to several biochemical and physiologic alterations in uremia and is not removed adequately by current hemodialysis strategies. The knowledge of its in vivo kinetic behavior could be helpful to improve the current removal strategies. METHODS: We investigated the kinetic behavior of intravenously injected p-cresol (10 mg/kg) in rats with normal and decreased renal function, and compared the results with those obtained for creatinine (60 mg/kg) under similar conditions. Renal failure was obtained by 5/6 nephrectomy. Both p-cresol and p-cresylglucuronide were analyzed using reversed-phase high-performance liquid chromatography (RP-HPLC). The relation between the p-cresylglucuronide peak height and the underlying amount of p-cresol was determined after hydrolysis of the glucuronide with beta-glucuronidase. We calculated urinary excretion of p-cresol with and without taking p-cresylglucuronide into account. In addition, total, renal, and non-renal clearance, half-life, and volume of distribution were calculated for p-cresol. RESULTS: Over a 4-hour period, p-cresol serum concentration showed only a minimal decline in rats with decreased renal function (t1/2 = 11.7 +/- 0.4 hours), compared to rats with normal renal function (t1/2 = 1.4 +/- 0.7 hours). A similar observation was made for p-cresylglucuronide. In rats with normal renal function, 21.0 +/- 10.0% of the injected p-cresol was excreted in urine as p-cresol and 60.7 +/- 25.0% as p-cresylglucuronide; in rats with renal failure, the respective amounts were 6.7 +/- 7.5% and 32.0 +/- 25.3% (P < 0.05 vs. normal renal function) (total recovery 81.81 +/- 31.07% vs. 38.50 +/- 32.09%, P < 0.05). The volume of distribution of p-cresol was approximately 4 times larger than that of creatinine, but was not significantly affected by renal failure. Not only renal, but also non-renal and total clearance, were much lower in rats with decreased renal function. CONCLUSION: The present data sheds a light on the kinetic behavior of p-cresol in uremic patients; the large volume of distribution, especially, might explain the inadequate dialytic removal of p-cresol. In addition, a substantial amount of p-cresol is removed by metabolism, and both renal and non-renal clearance are disturbed in uremia.

Tolerance to the hypnotic and electroencephalographic effect of gamma-hydroxybutyrate in the rat: pharmacokinetic and pharmacodynamic aspects.

Tolerance to gamma-hydroxybutyrate (GHB) has been suggested in illicit users and has been described for the hypnotic effect in the rat. The aim of this study was to investigate whether tolerance is also observed for the EEG effect, and whether the EEG can give insight into the pharmacodynamic aspects of GHB tolerance. In three series of experiments, rats were pre-treated with either the GHB precursor gamma-butyrolactone (GBL) or saline intraperitoneally twice daily. In the first series, a reduction in sleeping time was observed in the GBL pre-treated rats compared with controls. In the second series, a fast infusion of GHB (300 mg kg(-1) over 5 min) was given after 10 days pre-treatment. The GHB plasma concentration-time curves showed a slightly faster decrease in GHB concentration in the GBL pre-treated rats, suggesting a small induction of the GHB metabolism (V(max) = 2882 +/- 457 microg min(-1) kg(-1) vs 2205 +/- 315 microg min(-1) kg(-1), P < 0.01). In contrast to controls, GBL pre-treated rats did not lose righting reflex. In the third series, a slow infusion of 480 mg kg(-1) h(-1) was given after 7 days pre-treatment, which allowed fitting a sigmoid E(max) model to the EEG amplitude versus GHB plasma concentration curve. This showed reduced end-organ sensitivity to GHB in the GBL pre-treated rats (EC50 (concentration required to obtain 50% depression of the baseline effect) = 653+/- 183 microg mL(-1) vs 323 +/- 68 microg mL(-1), P < 0.001). In conclusion, chronic pre-treatment with gamma-butyrolactone in the rat results in a reduced sleeping time and this tolerance is reflected by the EEG. This can mainly be explained by reduced end-organ sensitivity.

Urinary excretion of the uraemic toxin p-cresol in the rat: contribution of glucuronidation to its metabolization.

BACKGROUND: Increasing evidence indicates that lipophilic and/or protein-bound substances such as p-cresol are responsible for adverse physiological alterations in uraemic patients. To better understand the evolution of p-cresol disposition in renal failure and dialysis patients, it is necessary to determine its kinetic characteristics and biotransformation pathways. METHODS: We studied the biotransformation of p-cresol after intravenous injection of the compound in eight rats with normal renal function. Urine was collected in four 1 h intervals. To evaluate the presence of p-cresol metabolites, beta-glucuronidase was added to urine samples and the isolated unidentified chromatographic peak observed in previous experiments was submitted to tandem mass spectrometry (MS/MS) analysis. RESULTS: Administration of p-cresol produced a p-cresol peak and an unknown peak, suggesting biotransformation of the compound. Addition of beta-glucuronidase to urine samples and incubation at 37 degrees C resulted in a marked decrease in the unidentified peak height (P<0.001) together with an increase in p-cresol peak height (P<0.001), suggesting that the unidentified peak was composed, at least in part, of p-cresylglucuronide. Mass spectrometry (MS) and MS/MS analysis of the isolated unidentified peak confirmed the presence of p-cresylglucuronide. Linear regression between the peak height of p-cresylglucuronide before enzyme treatment and the increase in p-cresol peak height after enzyme treatment in samples incubated with beta-glucuronidase allowed us to calculate the amount of p-cresylglucuronide as its p-cresol equivalents. This revealed that 64% of the injected p-cresol was excreted as glucuronide. There was no change in peak heights when sulphatase was added to the urine. When p-cresol and p-cresylglucuronide levels were combined, approximately 85% of all administered p-cresol was recovered in the urine. In addition, the combined urinary excretion of p-cresol and p-cresylglucuronide was more than four times greater than excretion of p-cresol by itself (P<0.01). CONCLUSIONS: In rats with normal renal function, intravenous administration of p-cresol results in immediate and extensive metabolization of the compound into p-cresylglucuronide. The elimination of p-cresol from the body depends largely on the urinary excretion of this metabolite.

Characterization of the pharmacokinetic and pharmacodynamic interaction between gamma-hydroxybutyrate and ethanol in the rat.

It has been reported that ethanol enhances the hypnotic effect of gamma-hydroxybutyrate (GHB). In order to clarify the nature of this interaction we studied the pharmacokinetics and pharmacodynamics of combinations of GHB and ethanol in rats. Intraperitoneal injections of the GHB precursor gamma-butyrolactone (300 mg/kg) together with ethanol (3000 mg/kg) (n = 4) resulted in a longer "sleeping time" than the sum of the individual times (n = 8). Pharmacokinetic analysis of GHB concentrations with a two-compartment model with Michaelis-Menten (M-M) elimination in rats receiving a bolus of GHB (400 mg/kg, i.v.) in addition to steady-state ethanol concentrations (300-3000 microg/ml) (n = 12) or saline (n = 15) showed no marked differences in the area under the curve. The nature of the pharmacodynamic interaction was studied using isobolographs and an interaction model for the loss of the startle and righting reflex and a reaction to a painful tail clamp in rats receiving combinations of steady state concentrations of ethanol (1000-3000 microg/ml) and GHB (200-1400 microg/ml). For the righting reflex, synergy was observed at high ethanol concentrations (>2000 microg/ml) and additivity at lower concentrations. For the startle reflex, it was antagonistic at ethanol concentrations below 1000 microg/ml, and additivity was seen at higher concentrations. For the tail clamp reaction, a slight but significant antagonism was found at all combined concentrations. It is concluded that ethanol prolongs the sleeping time induced by GHB in the rat, which may not be due to a pharmacokinetic interaction. Pharmacodynamic interactions between GHB and ethanol in the rat occur, and the nature varies with the reflex studied and the concentration of ethanol used.

The influence of endotoxemia on the pharmacokinetics and the electroencephalographic effect of propofol in the rat.

Endotoxemia decreases the dose requirement for anesthetics but no data are available for propofol. A rat model was used in which the influence of endotoxin administration on the pharmacokinetics and pharmacodynamics of propofol was investigated. Chronically instrumented rats were randomly allocated to either a control (n = 9) or an endotoxin (n = 9) group. Six hours after pretreatment with either endotoxin or its solvent, propofol was infused (150 mg x kg(-1) x h(-1)) until isoelectric periods of 5 s or longer were observed in the electroencephalogram. The changes observed in the electroencephalogram were quantified using aperiodic analysis and used as a surrogate measure of hypnosis. The righting reflex served as a clinical measure of hypnosis. The propofol dose needed to reach the electroencephalographic end point in the endotoxin-treated rats was reduced by almost 50% (p < 0.01). This could be attributed to a decrease in propofol clearance and in distribution volume related to the degree of physiologic and metabolic disturbances induced by endotoxin. To investigate changes in end organ sensitivity, the biphasic electroencephalographic effect versus effect-site concentration relationship was studied. This relationship was characterized by descriptors that showed an increased intrinsic efficacy of propofol in the endotoxin group. The effect-site concentration at the return of righting reflex was lower in the endotoxin group. Our study demonstrates that endotoxin-treated animals need a lower dose of propofol to reach the same degree of anesthetic effect which can mainly be attributed to changes in pharmacokinetics.

Influence of hypovolemia on the pharmacokinetics and electroencephalographic effect of gamma-hydroxybutyrate in the rat.

BACKGROUND: Hypovolemia alters the effect of propofol in the rat by influencing the pharmacokinetics and the end organ sensitivity. We now studied the effect of hypovolemia on the anesthetic gamma-hydroxybutyrate (GHB) because in contrast with propofol it increases blood pressure. METHODS: Thirty-two rats were randomly assigned to undergo moderate hypovolemia or a control procedure. Each rat received either an infusion of sodium-GHB (390 mg x kg(-1) x 5 min(-1)) or the same volume of an equimolar solution of sodium chloride (6.9%). Plasma samples were taken for GHB assay (high-performance liquid chromatography) and the electroencephalography and blood pressure values were recorded. A two-compartment model with Michaelis-Menten elimination was fitted to the concentration-time data and a sigmoid E(max) model to the electroencephalographic effect effect site concentration curve allowing the study of the end organ sensitivity. RESULTS: Plasma concentration-time curves and the total volume of distribution in hypovolemic and normovolemic rats were comparable with only small but significant differences in central volume of distribution and the intercompartmental clearance. There was no significant difference either in the distribution from the plasma to the brain (k(e0)) or in the end organ sensitivity (EC50 = 335 +/- 76 microg/ml in control vs. 341 +/- 89 microg/ml in hypovolemic rats). GHB temporarily increased mean arterial pressure in both groups, which cannot be explained by the sodium salt alone. CONCLUSIONS: Hypovolemia does not influence the overall concentration-time curve of GHB and induces no changes in the electroencephalographic effect of GHB in the rat. This difference with propofol may be due to the fact that it increases blood pressure but also due to its different pharmacokinetic properties.

Pharmacokinetic and pharmacodynamic considerations when treating patients with sepsis and septic shock.

Sepsis and septic shock are accompanied by profound changes in the organism that may alter both the pharmacokinetics and the pharmacodynamics of drugs. This review elaborates on the mechanisms by which sepsis-induced pathophysiological changes may influence pharmacological processes. Drug absorption following intramuscular, subcutaneous, transdermal and oral administration may be reduced due to a decreased perfusion of muscles, skin and splanchnic organs. Compromised tissue perfusion may also affect drug distribution, resulting in a decrease of distribution volume. On the other hand, the increase in capillary permeability and interstitial oedema during sepsis and septic shock may enhance drug distribution. Changes in plasma protein binding, body water, tissue mass and pH may also affect drug distribution. For basic drugs that are bound to the acute phase reactant alpha(1)-acid glycoprotein, the increase in plasma concentration of this protein will result in a decreased distribution volume. The opposite may be observed for drugs that are extensively bound to albumin, as the latter protein decreases during septic conditions. For many drugs, the liver is the main organ for metabolism. The determinants of hepatic clearance of drugs are liver blood flow, drug binding in plasma and the activity of the metabolic enzymes; each of these may be influenced by sepsis and septic shock. For high extraction drugs, clearance is mainly flow-dependent, and sepsis-induced liver hypoperfusion may result in a decreased clearance. For low extraction drugs, clearance is determined by the degree of plasma binding and the activity of the metabolic enzymes. Oxidative metabolism via the cytochrome P450 enzyme system is an important clearance mechanism for many drugs, and has been shown to be markedly affected in septic conditions, resulting in decreased drug clearance. The kidneys are an important excretion pathway for many drugs. Renal failure, which often accompanies sepsis and septic shock, will result in accumulation of both parent drug and its metabolites. Changes in drug effect during septic conditions may theoretically result from changes in pharmacodynamics due to changes in the affinity of the receptor for the drug or alterations in the intrinsic activity at the receptor. The lack of valid pharmacological studies in patients with sepsis and septic shock makes drug administration in these patients a difficult challenge. The patient's underlying pathophysiological condition may guide individual dosage selection, which may be guided by measuring plasma concentration or drug effect.

Post-mortem redistribution of 3,4-methylenedioxymethamphetamine (MDMA, "ecstasy") in the rabbit. Part I: experimental approach after in vivo intravenous infusion.

Post-mortem redistribution is known to influence blood and tissue levels of various drugs. An animal model was used in an attempt to elucidate this problem for the amphetamine analogue, 3,4-methylenedioxymethamphetamine (MDMA). Rabbits received 1 mg/kg MDMA intravenously (iv) and were killed 2 h later in order to simulate the state of complete distribution in the body. MDMA and 3,4-methylenedioxyamphetamine (MDA) concentrations were determined in blood, urine, bile, vitreous humour, and various tissues (eye globe walls, brain, cardiac muscle, lungs, liver, kidneys, iliopsoas muscle and adipose tissue) using a high pressure liquid chromatographic (HPLC) procedure with fluorescence detection. In the first group (control group, sampling immediately post mortem) considerable MDMA concentrations were found in the brain and both lungs. In addition, our data indicate the elimination of MDMA by hepatic biotransformation and excretion via the bile. When the animals were preserved either 24 or 72 h post mortem (second group), an increase of MDMA and MDA levels in the liver and the eye globe walls was noticed. In the lungs, on the other hand, they tended to decline as a function of increasing post-mortem interval. MDMA levels in cardiac and iliopsoas muscle were fairly comparable and remained stable up to 72 h after death. In the third group, ligation of the large vessels around the heart took place immediately post mortem, but significant differences in blood and tissue MDMA concentrations between rabbits of group 2 and 3 could not be demonstrated. We therefore conclude that post-mortem redistribution of MDMA at the cellular level (viz. by pure diffusion gradient from higher to lower concentrations) is more important than its redistribution via the vascular pathway. Finally, MDA levels were relatively low in all samples, thus indicating that this is not a major metabolite in the rabbit, at least within the first 2 h after administration.

Post-mortem redistribution of 3,4-methylenedioxymethamphetamine (MDMA, "ecstasy") in the rabbit. Part II: post-mortem infusion in trachea or stomach.

Drug concentrations in autopsy samples can also be influenced by post-mortem gastric diffusion when the stomach contains a substantial amount of the drug or by diffusion from the trachea when agonal aspiration or post-mortem regurgitation of vomit occurs. This was studied in a rabbit animal model in which MDMA solutions were infused post mortem either in the trachea or in the stomach. At 24, 48 or 72 h post mortem, samples including cardiac blood, vitreous humour, urine, bile, gastric content and several tissues were taken for toxicological analysis. After post-mortem tracheal infusion, MDMA can easily diffuse not only into the lungs but also in great quantities into the cardiac blood and, to a lesser extent, into the cardiac muscle. MDMA was also found in the closely adjacent diaphragm and in the upper abdominal organs, including the liver and the stomach. Following post-mortem infusion into the stomach, considerable MDMA levels were found in cardiac blood and muscle, both lungs, diaphragm and liver tissue when the solution was concentrated nearby the lower oesophageal sphincter. However, when the MDMA solution was present deeper in the stomach, MDMA levels were high in the spleen and the liver and relatively low in cardiac blood and muscle. In both experiments, MDA levels in most tissues were low or below the limit of quantitation, but were substantial in cardiac blood and muscle, lungs and diaphragm, indicating that MDMA can be metabolised to MDA after death. These results in the rabbit model indicate that the diffusion of MDMA out of the stomach content, or due to aspirated vomit and gastro-oesophageal reflux can lead to considerable post-mortem redistribution and thus should be taken into account in current forensic practice in order to draw the right conclusions when a peripheral blood sample is not available.

Selective serotonin reuptake inhibitors and cytochrome P-450 mediated drug-drug interactions: an update.

The selective serotonin reuptake inhibitors (SSRIs) have become the most prescribed antidepressants in many countries. Although the SSRIs share a common mechanism of action, they differ substantially in their chemical structure, metabolism, and pharmacokinetics. Perhaps the most important difference between the SSRIs is their potential to cause drug-drug interactions through inhibition of cytochrome-P450 (CYP) isoforms. This paper provides an update on both the in vitro and in vivo evidence with respect to CYP-mediated drug-drug interactions with this class of antidepressants. The available evidence clearly indicates that the individual SSRIs display a distinct profile of cytochrome P450 inhibition. Fluvoxamine is a potent CYP1A2 and CYP2C19 inhibitor, and a moderate CYP2C9, CYP2D6, and CYP3A4 inhibitor. Fluoxetine and paroxetine are potent CYP2D6 inhibitors, whereas fluoxetine's main metabolite, norfluoxetine, has a moderate inhibitory effect on CYP3A4. Sertraline is a moderate CYP2D6 inhibitor; citalopram appears to have little effect on the major CYP isoforms. Fluoxetine deserves special attention as inhibitory effects on CYP-activity can persist for several weeks after fluoxetine discontinuation because of the long half-life of fluoxetine and its metabolite norfluoxetine. Drug combinations with SSRIs should be assessed on an individual basis. Knowledge regarding the CYP-isoforms involved in the metabolism of the co-administered drug may help clinicians to anticipate and avoid potentially dangerous drug-drug interactions. Anticipated interactions can usually be managed by appropriate dose adjustment and titration of the object drug. In some cases, therapeutic drug monitoring can be useful. Equally well, an SSRI with limited interaction potential may be selected to treat depression in patients that receive other medications.