Digoxin prevents MPTP-induced dopamine depletion in mouse striatum.

Inhibition of Na+/K+ ATPase by cardiac glycosides has been shown to potentiate toxic effects of excitatory amino acids and mitochondrial poisons in neurons in vitro. The present study tested the hypothesis that the systemic administration of the cardiac glycoside, digoxin, potentiates effects of the dopamine neurotoxin 1-methyl-4-phenyl-1,2,5,6-tetrahydropyridine (MPTP) in vivo. Mice were injected with digoxin (1 mg/kg) or vehicle followed by MPTP (20 mg/kg) or saline 1 h later. After 1 or 8 days, mice were euthanized and dopamine levels in the striatum were measured by high-performance liquid chromatography with electrochemical detection. MPTP caused a significant 35-45% reduction in striatal dopamine levels compared to those in control mice. However, pretreatment with digoxin completely prevented the MPTP-induced dopamine depletion. This result was unexpected and suggests that cardiac glycosides may protect against MPTP neurotoxicity.

Apomorphine tolerance in Parkinson's disease: lack of a dose effect.

The development of tolerance to dopaminergic drugs may be important in the long-term therapy of Parkinson's disease. In this study, we sought to determine whether tolerance developed during infusions of apomorphine and if there was evidence of any dose dependency. Eight patients with Parkinson's disease received 4- to 6-h infusions of apomorphine at low, medium, and high rates on consecutive days. Before and after each infusion, test boluses of apomorphine were administered to measure sensitivity to the drug. The duration of motor effects after the postinfusion boluses were reduced in comparison to those of the preinfusion boluses, indicating that tolerance developed during the infusions. The infusion rate did not affect the responses to the postinfusion test boluses. Our observations indicate that tolerance develops to the antiparkinsonian effect of apomorphine after several hours of its constant infusion, but is not influenced by the dose of drug administered.

Apomorphine infusional therapy in Parkinson's disease: clinical utility and lack of tolerance.

We assessed the clinical utility of apomorphine infusional therapy in patients with parkinsonism and motor fluctuations and sought evidence for alterations in drug response resulting from chronic treatment. Six patients with Parkinson's disease were treated for 3 months with s.c. infusions of apomorphine administered during waking hours. At the beginning and the end of the study, test doses of apomorphine (12.5-100 micrograms/kg) were administered to establish a dose-response curve. Over the study, the patients reported a significant improvement in the number of "on" hours experienced per day and substantially reduced the dose and frequency of levodopa and other antiparkinsonian medications. No average change in apomorphine dose-response relationships or pharmacokinetics was observed during the study. However, two patients lowered the infusion rate during the 3-month observation and exhibited higher drug levels and longer responses following test doses of apomorphine given at the end of the study. Although pragmatic concerns with the use of infusion pumps solutions and adverse effects limited the overall benefit afforded by the treatment, this kind of drug treatment may be useful in selected patients with severe parkinsonism and fluctuations.

Episodic ataxia/myokymia syndrome is associated with point mutations in the human potassium channel gene, KCNA1.

Episodic ataxia (EA) is a rare, familial disorder producing attacks of generalized ataxia, with normal or near-normal neurological function between attacks. One type of EA is characterized by brief episodes of ataxia with myokymia (rippling of muscles) evident between attacks. Linkage studies in four such families suggested localization of an EA/myokymia gene near the voltage gated K+ channel gene, KCNA1 (Kv1.1), on chromosome 12p. Mutation analysis of the KCNA1 coding region in these families identified four different missense point mutations present in the heterozygous state, indicating that EA/myokymia can result from mutations in this gene.

Controlled release levodopa/carbidopa 25/100 (Sinemet CR 25/100): pharmacokinetics and clinical efficacy in untreated parkinsonian patients.

The pharmacokinetics of the clinically determined optimal dose of controlled release levodopa/carbidopa 25/100 (Sinemet CR 25/100) after 12 weeks of therapy was studied in nine parkinsonian patients without prior exposure to levodopa. The pharmacokinetics of single oral doses of controlled release levodopa/carbidopa 25/100 and 50/200 were also compared. As predicted from the plasma half-life (1.7 +/- 0.3 h) and confirmed by morning trough levels, levodopa did not accumulate when controlled released levodopa/carbidopa 25/100 was administered twice daily. The absorption and bioavailability of CR 25/100 are minimally greater than CR 50/200. Controlled released levodopa/carbidopa 25/100 levodopa plasma levels peak slightly faster than controlled release levodopa/carbidopa 50/200.

Effect of peripheral catechol-O-methyltransferase inhibition on the pharmacokinetics and pharmacodynamics of levodopa in parkinsonian patients.

Catechol-O-methyltransferase (COMT) metabolizes a portion of administered levodopa and thus makes it unavailable for conversion to dopamine in the brain. In an open-label trail, we examined the effects of entacapone, a peripheral inhibitor of COMT, administered acutely or for 8 weeks, on the pharmacokinetics and pharmacodynamics of levodopa in 15 parkinsonian subjects with a fluctuating response to levodopa. Acutely and chronically administered entacapone similarly decreased the plasma elimination of orally and intravenously administered levodopa. Absorption of levodopa was minimally affected. During chronic entacapone treatment, daily levodopa dosages were reduced by 27% yet mean plasma levodopa concentrations were increased by 23%. Plasma 3-O-methyldopa concentrations were decreased by 60%. Entacapone increased the duration of action of single doses of levodopa by a mean of 56%. The percent of the day "on" after 8 weeks of entacapone treatment was 77%; it dropped to 44% upon withdrawal of entacapone. We conclude that inhibition of COMT by entacapone increases the plasma half-life of levodopa and augments the antiparkinsonian effects of single and repeated doses of levodopa.

Does tolerance develop to levodopa? Comparison of 2- and 21-H levodopa infusions.

To determine if acute tolerance to levodopa develops, we compared the response to 2- and 21-h levodopa infusions with the rate adjusted during the long infusion to yield the same plasma concentration as at the end of the 2-h infusion. The duration of response after discontinuing the long infusions was briefer than after discontinuing the short infusion, suggesting the development of tolerance. Furthermore, dyskinesia severity was greater during long infusions. We conclude that continuous dopaminergic stimulation with levodopa may not offer optimal control of parkinsonism in patients with response fluctuations.

Time course of tolerance to apomorphine in parkinsonism.

We sought to determine if tolerance developed to the antiparkinsonian effects of apomorphine and, if so, what temporal factors influenced its development. Seven patients with parkinsonism and motor fluctuations received short (6-hour) and long (22- to 31-hour) apomorphine infusions. Tolerance was evaluated by comparison of the responses to test doses of apomorphine that were administered before and after each infusion. The responses to the test doses that followed either infusion were reduced by 35% after the short infusion and by 68% after the long infusion, although plasma apomorphine levels were similar to or higher than levels achieved with preinfusion test doses. The duration of improvement in parkinsonism after discontinuation of the long infusion was briefer than that after the short infusion. We conclude that tolerance to apomorphine occurs in parkinsonism, and the loss of response is greater after longer periods of drug administration.

Effect of long-term therapy on the pharmacodynamics of levodopa. Relation to on-off phenomenon.

To determine how the response to levodopa is altered by long-term therapy, we examined the dose response to 2-hour infusions of levodopa in three groups of parkinsonian patients: those who were previously untreated, those who exhibited stable responses, and those who exhibited fluctuating responses to levodopa therapy, using tapping speed as an index of bradykinesia. The baseline tapping speed was greater in the patients with stable responses than in the untreated patients, probably representing a "long-duration response" to levodopa therapy. A "short-duration response," indicated by an increase in tapping speed lasting hours, was observed in most patients in all groups. The onset of the short-duration effect was more rapid and the incremental increase in tapping speed was twice as large in the patients with fluctuating responses compared with the untreated patients and patients with stable responses. The duration of the short-duration effect was greatest in the untreated group but did not differ between the groups with stable and fluctuating responses. Dyskinesia was not observed in any of the de novo patients but was observed in three of 12 patients with stable responses and eight of nine patients with fluctuating responses to levodopa therapy. Dyskinesia appeared before or with the antiparkinsonian effects in patients with stable responses, giving no indication of a higher threshold for dyskinesia in these patients compared with those with fluctuating responses. The plasma half-life clearance, volume of distribution, and maximum plasma concentrations of levodopa did not differ among groups.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacodynamics of the hypotensive effect of levodopa in parkinsonian patients.

Blood pressure effects of i.v. levodopa were examined in parkinsonian patients with stable and fluctuating responses to levodopa. The magnitude of the hypotensive effect of levodopa was concentration dependent and was fit to an Emax model in fluctuating responders. Stable responders demonstrated a small hypotensive response. Baseline blood pressures were higher in fluctuating patients; a higher baseline blood pressure correlated with greater hypotensive effects. Antiparkinsonian effects of levodopa temporally correlated with blood pressure changes. Phenylalanine, a large neutral amino acid (LNAA) competing with levodopa for transport across the blood-brain barrier, reduced the hypotensive and antiparkinsonian effects of levodopa. We conclude that levodopa has a central hypotensive action that parallels the motor effects in fluctuating patients. The hypotensive effect appears to be related to the higher baseline blood pressure we observed in fluctuating patients relative to stable patients.

Differences in the motor response to apomorphine between untreated and fluctuating patients with Parkinson's disease.

Behavioral hyposensitivity to repeated apomorphine administration has been observed in fluctuating parkinsonian patients. To investigate whether a similar phenomenon occurs in patients never treated with levodopa, we studied the response to apomorphine in 20 de novo patients with Parkinson's disease. Six patients showed no or minimal improvement after apomorphine injections (maximal dose 3.5 mg). Fourteen patients responded and were then given up to four repeated subcutaneous injections of apomorphine [minimal effective dose (MED)]. The responses of de novo patients were compared with responses in 10 patients with motor fluctuations previously studied by the same protocol. There was no significant difference in latency and duration of motor responses after repeated apomorphine injections in de novo patients. MED was similar in de novo and fluctuating patients, but duration of improvement induced by each apomorphine bolus was longer in the de novo group. These results indicate that response duration to apomorphine is longer in previously untreated patients and that behavioral tolerance associated with pulsatile dopaminergic stimulation by apomorphine occurs mainly in patients with more advanced disease under chronic levodopa therapy.

Absorption of apomorphine by various routes in parkinsonism.

We wanted to determine the absorption and clinical effect of sublingual (SL) and transdermal apomorphine in parkinsonism. Patients received single SL apomorphine doses (N = 7) and the absorption was compared with parenteral (N = 5) and oral (N = 4) doses. One patient received a transdermal dose of apomorphine. The relative bioavailability of SL apomorphine ranged from 10 to 22% of a parenteral apomorphine dose. Oral apomorphine was less than 4% bioavailable, and the transdermal dose did not produce detectable plasma levels. Three patients with motor fluctuations responded to SL apomorphine, with a latency to effect of 20-40 min and a duration of effect of 15-100 min. One patient used SL apomorphine as an adjunct with levodopa, and during 1 month reported a large decrease in "off" periods. We conclude that apomorphine is effectively absorbed by the sublingual route.

Gilles de la Tourette syndrome is not linked to D2-dopamine receptor.

Gilles de la Tourette syndrome has an important genetic component; the pathophysiology of this disorder may involve the dopamine system. We tested a D2-dopamine receptor (locus DRD2, recognized by probe hD2G1) for genetic linkage with Gilles de la Tourette syndrome. Using a genetic linkage map of the region of DRD2 on the long arm of chromosome 11 and restriction fragment length polymorphism data from a total of four markers (DRD2 itself, D11S84, D11S29, and PBGD), we were able to exclude linkage of this candidate gene and Gilles de la Tourette syndrome in two extended kindreds segregating for Gilles de la Tourette syndrome. This rules out causation of Gilles de la Tourette syndrome by mutation in DRD2 in the kindreds studied under the genetic assumptions we employed; use of the map and multipoint linkage analyses also allowed us to exclude a Gilles de la Tourette syndrome susceptibility locus from a larger genetic region.

The short-duration response to apomorphine: implications for the mechanism of dopaminergic effects in parkinsonism.

The pharmacological basis of the short-duration response to dopaminergic stimulation in parkinsonism is not completely understood. Whereas it is generally assumed that the response reflects concurrent dopamine receptor occupancy, it is also possible that receptor activation triggers events that outlast the time that receptors are occupied by agonist. To distinguish between these two possibilities, we administered apomorphine, a mixed D1-D2 agonist with rapid equilibration between plasma and brain, to patients with parkinsonism. The clinical response to apomorphine injections lagged behind peak plasma concentrations and persisted beyond the time plasma concentrations following ineffective doses. We conclude that dopaminergic stimulation triggers effects that outlast the period of receptor occupancy by agonist. Understanding these steps may offer new pharmacological therapies for parkinsonism.

Studies of renal function in animals chronically treated with apomorphine.

Based on the observation that orally administered apomorphine may induce nephrotoxicity, we studied the renal effects of a two-week subcutaneous infusion of apomorphine in rats. Drug-treated rats did not exhibit any change in renal cortical uptake of an organic cation (tetraethyl ammonium), organic anion (para-hippuric acid), creatinine clearance, or fractional excretion of sodium and potassium. Renal histology showed no change specific to drug. A small increase in urinary N-acetylglucosaminidase, a tubular enzyme, was measured but a second tubular enzyme showed no change. We conclude that parenterally administered apomorphine is not associated with renal toxicity.

Peripheral pharmacokinetics of apomorphine in humans.

Apomorphine, a potent dopamine agonist, has been used in acute and chronic studies of parkinsonism and other neurological disorders. To define its peripheral pharmacokinetics, we administered apomorphine by subcutaneous injection, by subcutaneous infusion, and by intravenous infusion to 15 patients with parkinsonism and measured plasma apomorphine levels by high-performance liquid chromatography with electrochemical detection. The peak drug levels and area under the curve were closely correlated with the dose administered; time to peak was brief and was independent of dose. The variation in absorption was high between subjects but low within individual subjects. In 11 of 15 subjects, the disappearance of drug could be described by a two-compartment model, with a distribution half-life of 5 minutes and an elimination half-life of 33 minutes. The drug absorption, volume of distribution, plasma clearance, and half-lives were similar for subcutaneous injection, subcutaneous infusion, and intravenous infusion. We conclude that apomorphine is rapidly and completely absorbed from subcutaneous tissue, correlating with the rapid onset of clinical effects, and that the brief duration of clinical action of the drug is explained by its rapid clearance.