Topiramate concentration in saliva: an alternative to serum monitoring

This study examines the relationship between serum and saliva topiramate concentrations, and attempts to determine if saliva may be a useful alternative to serum for therapeutic monitoring. Saliva and blood specimens were collected from 31 epilepsy patients (mean age 10.5 +/- 6.0 years; range 2.5 years to 24.8 years), and topiramate concentrations were determined by fluorescence polarization immunoassay. One patient's results were omitted because the saliva concentration was below the limit of quantitation of the assay. A strong correlation exists between serum and saliva topiramate concentrations (adjusted r(2) = 0.97, n = 30, P < 0.0001). The mean fraction of saliva to serum concentration is 89.8% +/- 12.1% (range 62.9% to 112.7%). The results of this study support the use of saliva as a viable alternative to serum for monitoring topiramate therapy. Topiramate concentration in saliva: an alternative to serum monitoring.

Interactions of lamotrigine with topiramate and first-generation antiepileptic drugs in the maximal electroshock test in mice: an isobolographic analysis

PURPOSE

The study investigated the types of interactions between lamotrigine (LTG) and first-generation antiepileptic drugs (AEDs) or topiramate (TPM) with isobolographic analysis.

METHODS

Anticonvulsant and adverse-effect profiles of combinations of LTG with other AEDs, at fixed ratios of 1:3, 1:1, and 3:1, were evaluated in the maximal electroshock (MES)-induced seizures and the chimney test (motor performance) in mice, which allowed the determination of benefit indices (BIs) for individual combinations.

RESULTS

Combinations of LTG with TPM or valproate (VPA), at fixed ratios of 1:1, were significantly supraadditive (synergistic) in the MES test and, simultaneously, subadditive (antagonistic) in the chimney test, showing the best profile for AED combinations. In contrast, combinations between LTG and carbamazepine (CBZ), in terms of antiseizure protection against MES, were subadditive (antagonistic) and additive in the chimney test, resulting in unfavorable AED combinations. Moreover, the combination of LTG with phenobarbital (PB), at a fixed ratio of 1:1, despite synergy in the MES test, also was synergistic in the chimney test, resulting in a modest BI for AED combination. LTG combined with phenytoin was additive in both the MES and chimney tests in mice. The remaining combinations, at fixed ratios not mentioned earlier, also showed an average BI for AED combinations. Furthermore, LTG combined with all studied AEDs did not affect long-term memory in mice. None of the AEDs influenced the free plasma level of LTG, whereas LTG slightly reduced the free plasma concentration of PB.

CONCLUSIONS

Interactions between LTG and TPM or LTG and VPA at a fixed ratio of 1:1 might be profitable from a preclinical point of view, displaying the most optimal BI.

Vigabatrin, but not gabapentin or topiramate, produces concentration-related effects on enzymes and intermediates of the GABA shunt in rat brain and retina

PURPOSE

The antiepileptic drug (AED) vigabatrin (VGB), which exerts its pharmacologic effects on the gamma-aminobutyric acid (GABA) system, causes concentric visual field constriction in >40% of exposed adults. This may be a class effect of all agents with GABA-related mechanisms of action. We compared the concentration-related effects of VGB in rat brain and eye with those of gabapentin (GBP) and topiramate (TPM), both of which have been reported to elevate brain GABA concentrations in humans.

METHODS

Adult male rats (n = 10) were administered 0.9% saline (control), VGB (250, 500, 1,000 mg/kg), GBP (50, 100, 200 mg/kg), or TPM (12.5, 25, 50, 100 mg/kg). At 2 h after dosing, animals were killed, a blood sample obtained, the brain dissected into eight distinct regions, and the retina and vitreous humor isolated from each eye. Samples were analyzed for several GABA-related neurochemical parameters, and serum and tissue drug concentrations determined.

RESULTS

VGB treatment produced a significant (p < 0.05) dose-related increase in GABA concentrations and decrease in GABA-transaminase activity in all tissues investigated. This effect was most pronounced in the retina, where VGB concentrations were 18.5-fold higher than those in brain. In contrast, GBP and TPM were without effect on any of the neurochemical parameters investigated and did not accumulate appreciably in the retina.

CONCLUSIONS

These findings corroborate a previously reported accumulation of VGB in the retina, which may be responsible for the visual field constriction observed clinically. This phenomenon does not appear to extend to other GABAergic drugs, suggesting that these agents might not cause visual field defects.

Fatal acute topiramate toxicity

A 44-year-old Caucasian female was found dead in bed. Qualitative screening detected ethanol, phenobarbital, and methotrimeprazine. However, none were sufficient to attribute as the cause of death. Additionally, high concentrations of topiramate, an antiepilieptic agent, were found. Analysis of available biological fluids and tissues was carried out with the following results: blood (central) 170 mg/L, liver 140 mg/kg, stomach contents greater than 300 mg, and vitreous fluid 65 mg/L. The cause of death was ascribed to topiramate overdose.

Topiramate and lamotrigine pharmacokinetics during repetitive monotherapy and combination therapy in epilepsy patients

PURPOSE

To determine at steady state (in the same group of patients): (a) the pharmacokinetics (PK) of lamotrigine (LTG) with LTG monotherapy, (b) the PK of LTG concomitantly administered with topiramate (TPM) at three escalating TPM doses (100, 200, and 400 mg/day), (c) the PK of TPM at three escalating TPM doses while receiving fixed-dose LTG therapy, and (d) the PK of TPM with TPM monotherapy.

METHODS

This was an open-label, sequential, single-group, dose-escalating PK study in which 13 patients with epilepsy not optimally controlled with LTG received stable-dose LTG monotherapy for 2 weeks, followed by stable-dose LTG therapy combined with escalating doses of TPM for </=16 weeks, stable-dose TPM therapy combined with tapered-dose LTG therapy for 4 weeks, and stable-dose TPM monotherapy for 2 weeks. Serial blood and urine samples were collected before and during TPM dosing, and safety data were collected throughout the study.

RESULTS

The exposure, or area under the plasma LTG concentration-time curve within a dosing interval at steady state (AUCss), did not change in the presence of TPM, with mean AUCss values ranging at each TPM dose level between 66 and 81 mg x h/L with concomitant LTG/TPM therapy compared with 77 mgxh/L with LTG monotherapy. No significant change was found in the steady-state peak (Cmax) and trough (Cmin) plasma levels of LTG in the presence and absence of TPM. The mean (+/-SD) oral clearance (CL/F) of TPM (400 mg/day) was 2.6 +/- 1.1 L/h when given alone and 2.7 +/- 0.7 L/h when given with LTG. The similarity of CL/F values also was reflected by the similar exposure (AUCss), Cmax, and Cmin values of TPM in the absence, and presence of LTG.

CONCLUSIONS

The results of this study show that no PK interaction between TPM and LTGwas observed at the doses used in this study.

Relative bioavailability of topiramate administered rectally

OBJECTIVE

To determine the relative bioavailability and tolerability of a topiramate (TPM) suspension after rectal administration.

DESIGN/METHOD

Seven healthy men and five healthy non-pregnant women were enrolled. A 100 or 200 mg tablet of TPM was given orally and a 200 mg dose was given rectally in a randomized, open-label, crossover study with at least a 2-week washout period between doses. Plasma samples were collected prior to dosing and the following times after each dose: 0.5, 1, 1.5, 2, 3, 4, 6, 8, 12, 16, 24, 48, 72, and 96 h. Relative bioavailability was determined by calculating the ratio of the dose-normalized area under the curve (AUC/D) for the rectal and oral doses.

RESULTS

Ten subjects completed the study. Two of the first seven subjects who received a 200 mg initial oral dose, withdrew because of side effects. The remaining subjects received a 100 mg oral dose. Three subjects received a 200 mg dose orally and rectally, and seven subjects received 100 mg orally and 200mg rectally. The average AUC/D was 0.72+/-0.18 h/l for the rectal dose and 0.76+/-0.20 h/l for the oral dose. The relative bioavailability (n=10) for TPM administered rectally was 0.95+/-0.17 with a range of 0.68-1.2. There were no statistically significant differences between the oral or rectal pharmacokinetic parameters.

CONCLUSIONS

In healthy adults, rectally administered TPM is absorbed to a similar extent as the oral dosage form. Rectal administration is an acceptable route of administration for TPM, when the oral route is temporarily unavailable.

The ideal pharmacokinetic properties of an antiepileptic drug: how close does levetiracetam come?

The pharmacokinetic properties of a drug are the primary deter-minant of the extent and duration of drug action, and influence susceptibility to clinically important drug interactions. Most of the older-generation antiepileptic drugs (AEDs) are far from ideal in terms of pharmacokinetics and interaction potential. For example, phenytoin, carbamazepine, and valproic acid exhibit non-linear kinetics; carbamazepine and valproic acid have relatively short half-lives; and most of these drugs cause either enzyme induction (phenytoin, phenobarbital, primidone, carbamazepine) or enzyme inhibition (valproic acid). Compared with older agents, certain new-generation AEDs offer a num-ber of pharmacokinetic advantages, particularly in terms of reduced inter-patient variability in drug clearance and a lower interaction potential. One of the most recently developed of these drugs, levetiracetam, comes especially close to fulfilling the desirable pharmacokinetic characteristics for an AED: (1) it has a high oral bioavailability, which is unaffected by food; (2) it is not significantly bound to plasma proteins; (3) it is eliminated partly in unchanged form by the kidneys and partly by hydrolysis to an inactive metabolite, without involvement of oxidative and conjugative enzymes; (4) it has linear kinetics; and (5) it is not vulnerable to important drug interactions, nor does it cause clinically significant alterations in the kinetics of concomitantly administered drugs. Although its half-life is relatively short (6 to 8 hours), its duration of action is longer than anticipated from its pharmacokinetics in plasma, and a twice-daily dosing regimen is adequate to produce the desired response.

Effect of topiramate on the anticonvulsant activity of conventional antiepileptic drugs in two models of experimental epilepsy

PURPOSE

The objective of this study was to evaluate the interaction of the novel antiepileptic drug (AED), topiramate (TPM), with conventional AEDs against amygdala-kindled seizures in rats and pentylenetetrazol-induced convulsions in mice.

METHODS

Experiments were performed on mice and fully kindled rats. In pentylenetetrazol test, the chemoconvulsant was used at its CD97 dose of 105 mg/kg, producing clonic seizures in 97% of mice. Adverse effects were evaluated with the chimney test and passive avoidance task. Plasma levels of AEDs were measured with immunofluorescence.

RESULTS

TPM at 20 mg/kg exerted a significant anticonvulsant effect as regards seizure and afterdischarge durations in amygdala-kindled seizures in rats, being ineffective at lower doses. Coadministration of TPM (10 mg/kg) with valproate (VPA; at a subtherapeutic dose of 50 mg/kg) resulted in essential reductions of seizure and afterdischarge durations. TPM (10 mg/kg) combined with carbamazepine (CBZ; at a subtherapeutic dose of 15 mg/kg) significantly increased afterdischarge threshold, simultaneously decreasing the remaining seizure parameters (duration or severity of seizures and afterdischarge duration). TPM (10 mg/kg) given with phenobarbital (PB; 15 mg/kg) markedly shortened seizure severity and seizure and afterdischarge durations. Combinations of TPM with diphenylhydantoin (PHT) were ineffective against kindled seizures in rats. TPM combined with VPA and PB did not alter their plasma levels, but its combination with CBZ resulted in an increased free plasma CBZ concentration. TPM (10 and 20 mg/kg) alone and its combinations with conventional AEDs affected neither motor coordination nor long-term memory, evaluated in the chimney and passive avoidance tests, respectively, in rats. In pentylenetetrazol-evoked convulsions in mice, TPM (175 and 200 mg/kg) showed anticonvulsant effects per se. Moreover, TPM (at its subtherapeutic dose of 150 mg/kg), significantly potentiated the anticonvulsant action of ethosuximide (ESM), but not that of VPA, PB, or clonazepam (CZP) against pentylenetetrazol-induced seizures. Either TPM alone (150 mg/kg) or its combination with ESM did not result in significant undesired effects.

CONCLUSIONS

The experimental data indicate that except for PHT, the combinations of TPM with conventional AEDs are beneficial against amygdala-kindled seizures in rats. In the pentylenetetrazol test, this novel AED potentiated only the protection offered by ESM.

Evaluation of topiramate neuroprotective effect in severe TBI using microdialysis

Despite recent advances in our understanding of human traumatic brain injury (TBI) pathophysiology, we still need effective neuroprotective agents. The lack of rigorous drug pharmacokinetic studies in the "living" brain is an important cause of neuroprotection trials failure in human TBI research. In the past, several drugs have been labeled as inefficient, and even withdrawn from expensive trials, without knowing their actual penetration in the traumatized human brain. The injured brain is characterized by an increased diffusion distance, due to edema, and reduced blood flow that modulates drug transport across the blood-brain barrier (BBB). In the study reported in this paper, we used cerebral microdialysis to provide a safe and efficient tool for continuous in vivo evaluation of bioavailability and pharmacologic efficacy of topiramate, a glutamate release inhibitor. Topiramate crossed the BBB in neuroprotective concentrations, and showed a lowering effect on glutamate levels, thereby modifying the natural history of glutamate release after TBI. The use of cerebral microdialysis in phase II drug studies will allow the detection of the appropriate therapeutic window and dosage for the neuroprotective agent. This strategy represents a clear improvement compared to traditional clinical trial design, and will reduce the trial costs.

The locally acting glucocorticosteroid budesonide enhances intestinal sugar uptake following intestinal resection in rats

BACKGROUND AND AIMS

Locally and systemically acting corticosteroids alter the morphology and transport function of the intestine. This study was undertaken to assess the effect of budesonide, prednisone, and dexamethasone on sugar uptake.

METHODS

Adult male Sprague Dawley rats underwent transection or resection of 50% of the middle portion of the small intestine, and in vitro uptake of sugars was measured.

RESULTS

The 50% enterectomy did not alter jejunal or ileal uptake of glucose or fructose. Prednisone had no effect on the uptake of glucose or fructose in resected animals. In contrast, in resected rats budesonide increased by over 120% the value of the jejunal maximal transport rate for the uptake of glucose, and increased by over 150% ileal uptake of fructose. Protein abundance and mRNA expression of the sodium dependent glucose transporter in brush border membrane (SGLT1), sodium independent fructose transporter in the brush border membrane (GLUT5), sodium independent glucose and fructose transporter in the basolateral and brush border membranes (GLUT2), and Na(+)/K(+) ATPase alpha1 and beta1 did not explain the enhancing effect of budesonide on glucose or fructose uptake. Budesonide, prednisone, and dexamethasone reduced jejunal expression of the early response gene c-jun. In resected animals, expression of the mRNA of ornithine decarboxylase (ODC) in the jejunum was reduced, and corticosteroids reduced jejunal expression of the mRNA of proglucagon.

CONCLUSIONS

These data suggest that the influence of corticosteroids on sugar uptake in resected animals may be achieved by post translational processes involving signalling with c-jun, ODC, and proglucagon, or other as yet unknown signals. It remains to be determined whether budesonide may be useful to stimulate the absorption of sugars following intestinal resection in humans.

PET imaging of somatostatin receptors: design, synthesis and preclinical evaluation of a novel 18F-labelled, carbohydrated analogue of octreotide

Because of the excellent nuclear properties of fluorine-18 and the growing interest in somatostatin receptor (sst) scintigraphy with PET, a novel carbohydrated (18)F-labelled sst ligand was developed and preclinically evaluated. Synthesis of N(alpha)-(1-deoxy- D-fructosyl)- N(epsilon)-(2-[(18)F]fluoropropionyl)-Lys(0)-Tyr(3)-octreotate ([(18)F]FP-Gluc-TOCA) was completed in approximately 3 h (20%-30% yield). [(19)F]FP-Gluc-TOCA showed no affinity to hsst1 and hsst3, moderate affinity to hsst4 (IC(50): 437+/-84 n M) and hsst5 (IC(50): 123+/-8.8 n M) and very high affinity to hsst2 (IC(50): 2.8+/-0.4 n M). As a result of carbohydration, lipophilicity of [(18)F]FP-Gluc-TOCA was found to be low (lg P(OW)=-1.70+/-0.02). In mice, the tracer was rapidly cleared via renal excretion (kidneys: 8.69%+/-1.09%ID/g) and showed low uptake in liver (0.72%+/-0.14%ID/g) and intestine (1.88%+/-0.52%ID/g) and high tumour uptake (13.54%+/-1.47%ID/g) (all data at 1 h p.i.). Tumour to non-tumour ratios at 60 min p.i. reached 25, 19, 7, 1.6 and 56 for blood, liver, intestine, kidney and muscle, respectively. A similar biodistribution pattern was observed in pancreatic tumour-bearing rats. Tumour uptake in rats was reduced to 36% and 18% of control (30 and 60 min) by co-injection of 500 microg Tyr(3)-octreotide, demonstrating sst-specific uptake. In a first [(18)F]FP-Gluc-TOCA-PET study of a patient with a metastatic carcinoid in the liver the tracer showed superior pharmacokinetics, e.g. rapid urinary excretion and low uptake in liver, kidney and spleen. Multiple liver lesions (SUVs ranging from 21.4 to 38.0) and previously unknown focal uptake in the abdomen (SUV 10.0) were clearly visible. This is the first report on PET imaging using an (18)F-labelled sst binding peptide; it indicates that [(18)F]FP-Gluc-TOCA offers excellent imaging characteristics and allows sst imaging with high tumour to non-tumour contrast.

Review of the use of topiramate for treatment of bipolar disorders

Lithium alone or in combination with other psychotherapeutic drugs has long been the gold standard of management for bipolar disorder (BD). Recognition of its limitations in the acute and chronic management of BD has led to the development of alternative therapies. One such approach involves the use of antiepileptic drugs (AEDs). The AED topiramate is currently being studied in the efficacy and management of BD. Topiramate has mechanisms in common with other AEDs, including sodium channel-blocking activity and enhancement of cerebral GABA concentrations. Open-label trials have evaluated topiramate at mean daily doses of 100 to 300 mg in various BD subtypes, including acute mania, depression, rapid-cycling, mixed states, and BD refractory to other medications. Results from these trials suggest topiramate may be efficacious in BD subtypes, particularly in rapid-cycling patients and those refractory to conventional treatment. Its side effect profile appears benign when used as monotherapy or in combination with other mood stabilizers. Placebo-controlled, double-blind studies are warranted to evaluate topiramate further in BD.

Development of high-affinity ligands and photoaffinity labels for the D-fructose transporter GLUT5

The GLUT5 transporter catalyses the specific uptake of D-fructose and can accept this hexose in its furanose and pyranose ring forms. The transporter does not accept fructose epimers and has very limited tolerance of bulky groups substituted at the 2-, 3-, 4- and 5-OH positions [Tatibouët, Yang, Morin and Holman (2000) Bioorg. Med. Chem. 8, 1825-1833]. To further explore whether bulky groups can be tolerated at the primary OH positions, a D-fructose analogue with an allylamine group substitution to replace the 1-OH group was synthesized and was found to be quite well tolerated ( K (i)=27.1 mM). However, this analogue occurs in multiple ring forms. By contrast, 2,5-anhydro-D-mannitol is a symmetrical molecule that occurs only in a furanose ring form in which C-1 and C-6 are equivalent. We have therefore synthesized new 2,5-anhydro-D-mannitol analogues (substituted at the equivalent of the 6-OH of D-fructose) and from studies in Chinese hamster ovary cells expressing GLUT5 cells report that (i) the allylamine derivative of 2,5-anhydro-D-mannitol is well tolerated ( K (i)=2.66 mM); (ii) introduction of a di-nitrophenyl-substituted secondary amine group enhances affinity ( K (i)=0.56 mM); (iii) introduction of amide-linked biotinylated photolabel moieties is possible without loss of affinity relative to 2,5-anhydro-D-mannitol but a small secondary amine spacer between the biotinylated photolabelling moiety and the fructofuranose ring increases affinity (fructose photolabel 2; K (i)=1.16 mM); (iv) introduction of a hydrophilic tartarate spacer between biotin and the diazirine photoreactive groups can be accomplished without reduction in affinity and (v) photoactivation of biotinylated fructose photolabels leads to specific biotin tagging of GLUT5. These data suggest that substitution of a secondary amine group (-NH) to replace the C-6 (or C-1) -OH of 2,5-anhydro-D-mannitol results in compounds of high affinity; the affinity is enhanced over 10-fold compared with D-fructose.

Topiramate kinetics during delivery, lactation, and in the neonate: preliminary observations

PURPOSE

To study the pharmacokinetics of topiramate (TPM) during delivery, lactation, and in the neonate.

METHODS

TPM concentrations in plasma and breast milk were measured with fluorescence polarization immunoassay (FPIA) in five women with epilepsy treated with TPM during pregnancy and lactation. Blood samples were obtained at delivery from mothers, from the umbilical cord, and from the newborns on three occasions (24, 48, and 72 h) after delivery. Blood and breast milk also were collected from mothers 2 weeks, and 1 and 3 months postpartum. Blood samples also were drawn from the infants during breast-feeding. Three of the mother-infant pairs were studied both at delivery and during lactation; two contributed with data from delivery only.

RESULTS

The umbilical cord plasma/maternal plasma ratios were close to unity, suggesting extensive transplacental transfer of TPM. The mean milk/maternal plasma concentration ratio was 0.86 (range, 0.67-1.1) at 2-3 weeks after delivery. The milk/maternal plasma concentration ratios at sampling 1 and 3 months after delivery were similar (0.86 and 0.69, respectively). Two to 3 weeks after delivery, two of the breast-fed infants had detectable (>0.9 microM) concentrations of TPM, although below the limit of quantification (2.8 microM), and one had an undetectable concentration.

CONCLUSIONS

Our limited data suggest free passage of TPM over the placenta and an extensive transfer into breast milk. Breast-fed infants had very low TPM concentrations, and no adverse effects were observed in the infants.

Topiramate and phenytoin pharmacokinetics during repetitive monotherapy and combination therapy to epileptic patients

PURPOSE

To evaluate the potential pharmacokinetic interactions between topiramate (TPM) and phenytoin (PHT) in patients with epilepsy by studying their pharmacokinetics (PK) after monotherapy and concomitant TPM/PHT treatment.

METHODS

Twelve patients with epilepsy stabilized on PHT monotherapy were enrolled in this study, with 10 and seven patients completing the phases with 400 and 800 mg TPM daily doses, respectively. TPM was added at escalating doses, and after stabilization at the highest tolerated TPM dose, PHT doses were tapered. Serial blood and urine samples were collected for PK analysis during the monotherapy phase or the lowest PHT dose after taper and the concomitant TPM/PHT phase. Potential metabolic interaction between PHT and TPM also was studied in vitro in human liver microsomal preparations.

RESULTS

In nine of the 12 patients, PHT plasma concentrations remained stable, with a mean (+/-SD) area under the curve (AUC) ratio (combination therapy/monotherapy) of 1.13 +/- 0.17 (range, 0.89-1.23). Three patients had AUC ratios of 1.25, 1.39, and 1.55, respectively, and with the addition of TPM (800, 400, and 400 mg daily, respectively), their peak PHT plasma concentrations increased from 15 to 21 mg/L, 28 to 36 mg/L, and 27 to 41 mg/L, respectively. Human liver microsomal studies with S-mephenytoin showed that TPM partially inhibited CYP2C19 at very high concentrations of 300 microM (11% inhibition) and 900 microM (29% inhibition). Such high plasma concentrations would correspond to doses in humans that are 5 to 15 times higher than the recommended dose (200-400 mg). TPM clearance was approximately twofold higher during concomitant TPM/PHT therapy

CONCLUSIONS

This study provides evidence that the addition of TPM to PHT generally does not cause clinically significant PK interaction. PHT induces the metabolism of TPM, causing increased TPM clearance, which may require TPM dose adjustments when PHT therapy is added or is discontinued. TPM may affect PHT concentrations in a few patients because of inhibition by TPM of the CYP2C19-mediated minor metabolic pathway of PHT.

Pharmacokinetics of new anticonvulsants in psychiatry

The newer AEDs have potential in the treatment of psychiatric disorders. In light of this expanding spectrum of activity, it is necessary to refine and focus the safety and efficacy of the use of these agents among a wider population. The classic AEDs had numerous problems, ranging from inconvenient dosing schedules to frequent side effects due to active metabolites and common drug interactions; newer agents have been developed to avoid some of these pitfalls. Indeed, a generation of drugs that appears to have relatively simple pharmacokinetics and limited drug interactions--making them safer and easier to administer--is now available. The use of these agents in psychiatry will necessitate additional investigation into their dosing and administration guidelines, as well as their interactions with other common psychiatric or concomitant drugs. Certainly, over time, they will be evaluated for these parameters in the newer indications. In the meantime, a review of the established pharmacokinetic and pharmacodynamic activities of these agents is the first step in defining their optimal uses and limitations in the psychiatric setting.

Topiramate therapeutic monitoring in patients with epilepsy: effect of concomitant antiepileptic drugs

The authors assessed the effect of concomitant antiepileptic therapy on steady-state plasma concentrations of the new antiepileptic drug (AED) topiramate and the potential relation between topiramate plasma levels and side effects in a cohort of 116 patients with epilepsy. On the basis of concomitant AEDs, patients were divided into two subgroups, otherwise comparable for age and weight-adjusted daily dose of topiramate. Group A (n = 73) received topiramate plus AED inducers of cytochrome P450 (CYP) metabolism, such as carbamazepine, phenobarbital, and phenytoin. Group B (n = 43) received topiramate plus AEDs without inducing properties of CYP metabolism (namely valproic acid and lamotrigine). Weight-normalized topiramate clearance values, calculated as dosing rate/steady-state plasma drug concentration, were about 1.5-fold in patients receiving AED inducers compared with patients receiving AED noninducers. Topiramate plasma concentrations were linearly related to daily drug doses, regardless of concomitant AED therapy, over a dose range from 25 to 800 mg/d, although, at a given daily dose, a large interpatient variability was observed in matched plasma drug concentrations within each group of patients. Thirty-nine patients (34%) reported side effects associated with topiramate, mostly central nervous system effects. No consistent relation was observed between topiramate plasma concentrations and adverse effects, either in the cohort of patients as a whole or within each subgroup. From a clinical point of view, patients receiving concurrent treatment with enzyme-inducing AEDs can show twofold lower topiramate plasma concentrations compared with patients receiving valproic acid or lamotrigine, and appropriate topiramate dosage adjustments may be required when concomitant AED inducers are either added or withdrawn. Due to the observed variability in topiramate metabolic variables and the complex spectrum of possible pharmacokinetic and pharmacodynamic interactions with the most commonly coprescribed AEDs, monitoring of plasma topiramate concentrations may help the physician in the pharmacokinetic optimization of the drug dosage schedule in individual patients.

Metabolism of D-[1-(13)C]fructose, D-[2-(13)C]fructose, and D-[6-(13)C]fructose in rat hepatocytes incubated in the presence of H(2)O or D(2)O

Isolated hepatocytes from fed rats were exposed for 120 min to D-[1-(13)C]fructose, D-[2-(13)C]fructose, or D-[6-(13)C]fructose in the presence of H(2)O or D(2)O. The identification and quantification of (13)C-enriched metabolites (D-glucose, L-lactate) in the incubation medium and the measurement of their deuterated isotopomers indicated that the ketohexose was phosphorylated predominantly at the intervention of fructokinase and that the majority of the D-glyceraldehyde molecules generated from d-fructose 1-phosphate were further metabolized, e.g., after phosphorylation to D-glyceraldehyde 3-phosphate. It is proposed that the present procedure may help to further characterize the regulation of D-fructose metabolism in both hepatocytes and other cell types.

Malabsorption of modified food starch (acetylated distarch phosphate) in normal infants and in 8-24-month-old toddlers with non-specific diarrhea, as influenced by sorbitol and fructose

Acetylated distarch phosphate (ADiSP) is a modified starch used in some baby foods. The bioavailability of ADiSP and a native (unmodified) starch was evaluated in 20 normal infants and 21 toddlers aged 8-24 mo with chronic non-specific diarrhea. Formulae contained 8% native or 8% modified waxy maize starch. No infant or toddler consuming Formula N (native starch) had elevated peak breath hydrogen levels (20 ppm or greater), stools clinically positive for reducing substances (0.75% or greater) or loose stools. Fourteen infants received formula M (modified starch): 2 had elevated breath hydrogen, 1 had positive stools and another had loose stools. Of the 21 toddlers fed formula M, 2 had elevated breath hydrogen, but none had positive stools or loose stools. Formula NS (native starch with 2% sorbitol) had little effect on breath hydrogen in the infants but significantly increased it in the toddlers. Formula NS produced loose stools in 2 toddlers but no clinically positive stools in any infant or toddler. Formula MS (modified starch with 2% sorbitol) elevated breath hydrogen in 3 infants and 8 toddlers, and produced positive stools in 2 infants and 2 toddlers, and loose stools in 4 infants and 7 toddlers. Formula MSF (modified starch with 2% sorbitol and 5% fructose) elevated breath hydrogen in 7 infants and 10 toddlers, positive stools in 7 infants and 6 toddlers, and loose stools or diarrhea in 7 infants and 11 toddlers.

CONCLUSION

ADiSP modified starch can increase breath hydrogen and produce loose stools. Sorbitol and fructose aggravate the malabsorption, in some cases leading to frank diarrhea.

Plasma concentration of topiramate correlates with cerebrospinal fluid concentration

The authors examined the ratio between the plasma and the cerebrospinal fluid (CSF) concentration of topiramate in 14 adults with epilepsy. Simultaneous trough samples of venous blood and CSF were collected and analyzed as total and unbound concentrations. Concomitant levels were also analyzed of lamotrigine (n = 5) and the relevant oxcarbazepine metabolite, 10-hydroxycarbazepine (n = 3). There was a close correlation between the plasma and the CSF concentration for both the total and unbound concentration of topiramate. The median CSF/plasma ratio of total topiramate was 0.85. The free topiramate concentration in plasma was not different from the free topiramate concentration in CSF. The CSF/plasma ratios showed little variation and were independent of the plasma level for both the total and the unbound levels. The unbound fraction of topiramate was 84% in plasma and 97% in CSF. The CSF concentrations of lamotrigine and 10-hydroxycarbazepine were 50% and 61% of the plasma concentrations, respectively. For topiramate, there is a close correlation between the plasma concentration and the CSF concentration. There does not seem to be a saturable carrier mechanism restricting topiramate transport across the blood-brain barrier. The concentration of topiramate in CSF is equal to the unbound proportion of topiramate in plasma, implying that the delivery of topiramate to the brain occurs via transfer from the unbound plasma pool. Plasma is thus a relevant matrix for therapeutic drug monitoring of topiramate.

Simple and rapid liquid chromatographic-turbo ion spray mass spectrometric determination of topiramate in human plasma

We present a simple and fast method for the determination of the novel antiepileptic drug topiramate in human plasma by high-performance liquid chromatography coupled with turbo ion spray mass spectrometry. Plasma sample pre-treatment was based on simple deproteinization by acetonitrile. Liquid chromatographic analysis was carried out on a reversed-phase column (C18, 125x4 mm I.D., 5 microm) using acetonitrile-ammonium acetate buffer, pH 6.3 as the mobile phase, at a flow-rate of 0.8 ml/min. Retention time for topiramate was 2.1 min. The detector was a single quadrupole mass spectrometer coupled to a turbo ion spray ion source and a heated nebulizer probe, operating in the positive ion mode. Ion source temperature was off; voltage was +5800 V; nebulizer and curtain gas flow-rates were 6 and 10 ml/min, respectively. Calibration curves for topiramate were linear over the range 1 to 20 microg/ml. Absolute recovery ranged between 92 and 95%. Intra- and inter-assay precision was <4%. The present procedure, omitting extraction and drying steps, is faster and simpler than the previously reported analytical methods for topiramate and was demonstrated to possess adequate sensitivity for routine therapeutic drug monitoring in plasma from patients with epilepsy.

Topiramate: a review of its use in childhood epilepsy

Topiramate is an antiepileptic drug (AED) which appears to have a broad range of antiseizure activity in humans. A previous overview focused primarily on results of trials of topiramate in adults with epilepsy, and this review highlights the use of topiramate in children. Clinical trials have shown that topiramate is effective when used adjunctively in children with refractory partial-onset seizures and generalised tonic-clonic seizures. The drug significantly reduced seizure frequency compared with placebo in children with partial-onset epilepsy after 16 weeks of double-blind adjunctive treatment (33.1 vs 10.5%); the frequency of secondarily generalised seizures was also markedly reduced. During a nonblind extension of this trial, the mean dosage was titrated from 4.8 to 9 mg/kg/day and further reductions in the frequency of seizures were observed (71% compared with prestudy levels). In 2 mixed adult/paediatric populations with primary generalised tonic-clonic seizures, topiramate (target dosage 5.2 to 9.3 mg/kg/day) reduced the seizure rate compared with those receiving placebo. This difference was significant in one trial (56.7 vs 9%) but not in another (57.1 vs 33.2%). A subanalysis of the paediatric patients found that the favourable effect of topiramate on seizure rates was not age-related. Topiramate (median average dosage 5.1 mg/kg/day) was also found to be useful as adjunctive therapy in the management of Lennox-Gastaut syndrome and significantly reduced the mean frequency of drop attacks by 14.8% compared with an increase of 5.1% with placebo. Further gains in seizure control were made in a nonblind extension of this trial where the mean topiramate dosage was 10 mg/kg/day. Nine of 11 patients in 1 pilot trial of children with otherwise intractable West syndrome, and 5 of 10 in another, achieved a > or =50% reduction in seizure rate with topiramate (target dosage up to 24 mg/kg/day). In an 18-month extension of the former trial (mean dosage 29 mg/kg/day) a > or =50% reduction in seizures was maintained in 7 of 11 children. Adverse events associated with adjunctive topiramate therapy in children were predominantly neuropsychiatric and generally mild to moderate in severity. Behavioural and cognitive problems do occur and are a limiting factor in some children. Also, weight loss can be problematical in some individuals. Withdrawal rates were low in the controlled trials (4.8%), but appear to be more frequent in noncomparative and post-marketing studies.

CONCLUSION

Well controlled studies have demonstrated that topiramate is an effective agent for the adjunctive therapy of partial and generalised tonic-clonic seizures in children. Treatment-limiting adverse events do occur, but these may be managed by slow titration. Although comparative studies with the other newer AEDs used in adjuntive therapy are required, topiramate is an important extension to the range of drugs that may be used to treat refractory epilepsy in children.

GLUT-5 expression in neonatal rats: crypt-villus location and age-dependent regulation

The rat fructose transporter normally appears after completion of weaning but can be precociously induced by early feeding of a high-fructose diet. In this study, the crypt-villus site, the metabolic nature of the signal, and the age dependence of induction were determined. In weaning rats fed high-glucose pellets, GLUT-5 mRNA expression was modest, localized mainly in the upper three-fourths of the villus, and there was little expression in the villus base. When fed high-fructose pellets, GLUT-5 mRNA expression was two to three times greater in all regions except the villus base. Intestinal perfusion in vivo of a nonmetabolizable fructose analog, 3-O-methylfructose, tended to increase fructose uptake rate and moderately increased GLUT-5 mRNA abundance but had no effect on glucose uptake rates and SGLT1 mRNA abundance. Gavage feeding of high-fructose, but not high-glucose, solutions enhanced fructose uptake only in pups > or =14 days, suggesting that GLUT-5 regulation is markedly age dependent. Fructose or its metabolites upregulate GLUT-5 expression in all enterocytes, except those in the crypt and villus base and in pups <14 days old.

Pharmacokinetics and pharmacodynamics of topiramate

In the treatment of children with epilepsy, the role of topiramate has been expanding gradually. The main factor that has contributed to this trend is the relatively large body of information that has accumulated on the clinical pharmacology of topiramate in children, including its broad-spectrum efficacy, pediatric pharmacokinetics, side-effect profile, and safety. It has also become increasingly apparent with time that topiramate, in contrast to other broad-spectrum antiepileptic drugs used in children, does not seem to be associated with a significant risk of any serious or life-threatening adverse effects. The present review summarizes the available evidence related to the clinical pharmacology of topiramate in children and provides an update on its known mechanisms of action. Finally, available experimental data on the neuroprotective effect of topiramate are reviewed because of their considerable clinical potential in the treatment of children and newborns.

Regulation of hepatic glucose metabolism by translocation of glucokinase between the nucleus and the cytoplasm in hepatocytes

We studied the role of glucokinase translocation between the nucleus and the cytoplasm in hepatocytes. In cultured hepatocytes, both the translocation of glucokinase from the nucleus to the cytoplasm and the rate of glucose phosphorylation were increased when cells were incubated with high concentrations of glucose. The addition of low concentrations of fructose, which is known to stimulate glucose phosphorylation, stimulated both glucokinase translocation and glucose phosphorylation. There was a good correlation between the increase in cytoplasmic glucokinase induced by fructose and that in the glucose phosphorylation rate induced by fructose. Furthermore, we observed a linear relationship between cytoplasmic glucokinase activity and rate of glucose phosphorylation over various glucose concentrations in the absence or presence of fructose. These results indicate that glucose phosphorylation in hepatocytes depended on glucokinase in the cytoplasmic compartment--that is, the increase in the rate of glucose phosphorylation was due to the increase in translocation of glucokinase out of the nucleus. Also, oral administration of glucose, fructose, or glucose plus fructose to 24-h fasted rats induced translocation of glucokinase in the liver. All of these results indicate that hepatic glucose metabolism is regulated by the translocation of glucokinase.