An update on pharmacological, pharmacokinetic properties and drug-drug interactions of rotigotine transdermal system in Parkinson's disease and restless legs syndrome.

This narrative review reports on the pharmacological and pharmacokinetic properties of rotigotine, a non-ergolinic D3/D2/D1 dopamine receptor agonist approved for the treatment of early- and advanced-stage Parkinson's disease (PD) and moderate to severe restless legs syndrome (RLS). Rotigotine is formulated as a transdermal patch providing continuous drug delivery over 24 h, with a plasma concentration profile similar to that of administration via continuous intravenous infusion. Absolute bioavailability after 24 h transdermal delivery is 37 % of the applied rotigotine dose. Following a single administration of rotigotine transdermal system (24-h patch-on period), most of the absorbed drug is eliminated in urine and feces as sulphated and glucuronidated conjugates within 24 h of patch removal. The drug shows a high apparent volume of distribution (>2500 L) and a total body clearance of 300-600 L/h. Rotigotine transdermal system provides dose-proportional pharmacokinetics up to supratherapeutic dose rates of 24 mg/24 h, with steady-state plasma drug concentrations attained within 1-2 days of daily dosing. The pharmacokinetics of rotigotine transdermal patch are similar in healthy subjects, patients with early- or advanced-stage PD, and patients with RLS when comparing dose-normalized area under the plasma concentration-time curve (AUC) and maximum plasma drug concentration (Cmax), as well as half-life and other pharmacokinetic parameters. Also, it is not influenced in a relevant manner by age, sex, ethnicity, advanced renal insufficiency, or moderate hepatic impairment. No clinically relevant drug-drug interactions were observed following co-administration of rotigotine with levodopa/carbidopa, domperidone, or the CYP450 inhibitors cimetidine or omeprazole. Also, pharmacodynamics and pharmacokinetics of an oral hormonal contraceptive were not influenced by rotigotine co-administration. Rotigotine was generally well tolerated, with an adverse event profile consistent with dopaminergic stimulation and use of a transdermal patch. These observations, combined with the long-term efficacy demonstrated in clinical studies, support the use of rotigotine as a continuous non-ergot D3/D2/D1 dopamine receptor agonist in the treatment of PD and RLS.

Activation of PPAR gamma receptors reduces levodopa-induced dyskinesias in 6-OHDA-lesioned rats.

Long-term administration of l-3,4-dihydroxyphenylalanine (levodopa), the mainstay treatment for Parkinson's disease (PD), is accompanied by fluctuations in its duration of action and motor complications (dyskinesia) that dramatically affect the quality of life of patients. Levodopa-induced dyskinesias (LID) can be modeled in rats with unilateral 6-OHDA lesions via chronic administration of levodopa, which causes increasingly severe axial, limb, and orofacial abnormal involuntary movements (AIMs) over time. In previous studies, we showed that the direct activation of CB1 cannabinoid receptors alleviated rat AIMs. Interestingly, elevation of the endocannabinoid anandamide by URB597 (URB), an inhibitor of endocannabinoid catabolism, produced an anti-dyskinetic response that was only partially mediated via CB1 receptors and required the concomitant blockade of transient receptor potential vanilloid type-1 (TRPV1) channels by capsazepine (CPZ) (Morgese et al., 2007). In this study, we showed that the stimulation of peroxisome proliferator-activated receptors (PPAR), a family of transcription factors activated by anandamide, contributes to the anti-dyskinetic effects of URB+CPZ, and that the direct activation of the PPARγ subtype by rosiglitazone (RGZ) alleviates levodopa-induced AIMs in 6-OHDA rats. AIM reduction was associated with an attenuation of levodopa-induced increase of dynorphin, zif-268, and of ERK phosphorylation in the denervated striatum. RGZ treatment did not decrease striatal levodopa and dopamine bioavailability, nor did it affect levodopa anti-parkinsonian activity. Collectively, these data indicate that PPARγ may represent a new pharmacological target for the treatment of LID.

Analysis of CYP2D6 genotype and response to tetrabenazine.

Tetrabenazine is effective in the treatment of the chorea associated with Huntington disease and other hyperkinetic movement disorders. Following oral administration, tetrabenazine is hepatically transformed into 2 active metabolites that are CYP2D6 substrates. There are 4 CYP2D6 genotypes: poor metabolizers, intermediate metabolizers, extensive metabolizers, and ultrarapid metabolizers. CYP2D6 genotyping was performed on sequential subjects treated with tetrabenazine, but results were not known at the time of titration. Duration of titration to a stable dose, total daily dose, response rating scores, and adverse events were retrospectively collected and subsequently analyzed. Of 127 patients, the majority (n = 100) were categorized as extensive metabolizers, 14 as intermediate metabolizers, 11 as poor metabolizers, and 2 as ultrarapid metabolizers. Ultrarapid metabolizer patients needed a longer titration (8 vs 3.3, 4.4, and 3 weeks, respectively; P < .01) to achieve optimal benefit and required a higher average daily dose than the other patients, but this difference did not reach statistical significance. The treatment response was less robust in the intermediate metabolizer group when compared with the extensive metabolizer patients (P = .013), but there were no statistically significant differences between the various groups with regard to adverse effects. Our findings demonstrate that, aside from the need for a longer titration in the ultrarapid metabolizers, there are no distinguishing features of patients with various CYP2D6 genotypes, and therefore the current recommendation to systematically genotype all patients prescribed more than 50 mg/day of tetrabenazine should be reconsidered.

Safety considerations in the use of botulinum toxins in children with cerebral palsy.

The use of botulinum toxins to decrease spasticity in children with cerebral palsy has become standard of care during the past decade. In 2008 reports of severe adverse events, including death, were reported in children who received injections of these medications. The following discussion focuses on the background of these reports, the response of the U.S. Food and Drug Administration, as well as the safety profile and pharmacokinetics of botulinum toxins. Finally, the authors will offer their perspective on the safe use of botulinum toxins.

Evaluation of in vitro release and in vivo efficacy of mPEG-PLA-haloperidol conjugate micelle-like structures.

Polymeric prodrugs of mPEG-PLA-haloperidol (methoxy poly(ethylene glycol)-b-poly (lactic acid)), self-assemble into nanoscale micelle-like structures in aqueous solutions. The micelles range in size from 28 to 52 nm in diameter and have been shown to be spherical in shape using cryogenic transmission electron microscopy. In this current work there is evidence shown that suggests these micelle-like structures do not dissociate below their critical micelle concentration (CMC) when the PEG weight percent is at least 68, releasing physically entrapped drug from intact micelles over a 3-day period. However, 55 wt % PEG micelles dissociate below their CMC, and release their physically entrapped drug within 8 h. Conjugate polymer micelles most closely approach a linear release profile over a 5-day period. Conjugate micelles with free drug incorporated, known as combination micelle-like structures, release drug over 4 days. However, these combination micelles have the fastest burst release indicating that free drug was potentially dominating the first 8 h of release, after which hydrolysis of covalently linked drug took over. In vivo behavioral studies can assess haloperidol bioactivity from drug loaded micelle-like structures on ketamine induced hyperlocomotion. Results are consistent with in vitro release data, showing that conjugate and combination micelles continue to release haloperidol 4 days post injection, attenuating the effects of the ketamine induced hyperlocomotion. Furthermore, results indicate that the sedative side effects of haloperidol were reduced with the micelle delivery systems as compared to the acute haloperidol injection.

Botulinum toxin treatment of children with cerebral palsy - a short review of different injection techniques.

The intramuscular application of botulinum toxin type A (BoNT/A) has emerged to be an established treatment option to reduce muscular hyperactivity due to spasticity in children with cerebral palsy. Accurate injection is a prerequisite for efficient and safe treatment with BoNT/A. So far, treatment procedures have not been standardized. This paper is a short review of different injection techniques, i.e., manual needle placement as well as guidance by electromyography, electrical stimulation, and ultrasound. Advantages and disadvantages of the different injection techniques are discussed with a focus on needle positioning within the targeted muscle, injection close to the neuromuscular junction and diffusion of BoNT/A within the target muscles and through fascia. The additional information gained by each injection technique is weighed in terms of the clinical impact for children with cerebral palsy.

[Mode of action of botulinum neurotoxin: pathological, cellular and molecular aspect]. / Le mode d'action des neurotoxines botuliques: aspects pathologiques, cellulaires et moléculaires.

Several bacteria of the Clostridium genus (C. botulinum) produce 150 kDa di-chainal protein toxins referred as botulinum neurotoxins or BoNTs. They associate with non-toxic companion proteins and form a complex termed botulinum toxin or BoTx. The latter is used in clinic for therapeutic purpose. BoNTs affect cholinergic nerve terminals in periphery where they block acetylcholine release, thereby causing dysautonomia and motorparalysis (i.e. botulism). The cellular action of BoNTs can be depicted according to a three steps model: binding, internalisation and intraneuronal action. The toxins heavy chain mediates binding to specific receptors followed by endocytotic internalisation of BoNT/receptor complex. BoNT receptors may comprise gangliosides and synaptic vesicle-associated proteins as synaptotagmins. Vesicle recycling induces BoNT internalisation. Upon acidification of vesicles, the light chain of the neurotoxin is translocated into the cytosol. Here, this zinc-endopeptidase cleaves one or two among three synaptic proteins (VAMP-synaptobrevin, SNAP25, and syntaxin). As the three protein targets of BoNT play major role in fusion of synaptic vesicles at the release sites, their cleavage is followed by blockage of neurotransmitter exocytosis. The duration of the paralytic effect of the BoNTs is determined by 1) the turnover of their protein target; 2) the time-life of the toxin light chain in the cytosol, and 3) the sprouting of new nerve-endings that are retracted when the poisoned nerve terminal had recovered its full functionality.

Some unresolved issues with botulinum toxin.

Issues concerning botulinum toxin still need resolution in the laboratory and clinic. Assay nomenclature is unsatisfactory and attempts to establish common units and/or equivalents are misguided and dangerous. Optimum toxin concentrations for most indications are unknown. Loss of response is too readily ascribed to antibody formation. New therapeutic indications for toxin raise the possibility of additional mechanisms of action.

Botulinum toxin A and facial lines: the variable concentration.

Our improved understanding of the functional anatomy of the face and of the action of the botulinum toxin A leads us to determine a new injection procedure which consequently decreases the risk of eyebrow and eyelid ptosis, and increases the toxin injection's possibilities and efficiencies. Variable toxin injection concentrations adapted to each injected area are used. Thanks to the new procedure in the upper face, toxin A action is quite close to an endoscopic surgical action. In addition, interesting results are achievable on the nose, upper part of the nasolabial fold, jawline and neck regions. Lastly, a smoothing effect on the skin is obtained by the anticholinergic action of the toxin A on the dermal receptors.

Botulinum toxin for the treatment of cervical dystonia.

Cervical dystonia (CD) manifests clinically through involuntary spasms of neck muscles, producing abnormal head and neck movements and postures, which is often associated with pain. CD is the most common form of focal dystonia presenting to movement disorders clinics. Chemodenervation with botulinum toxin (BTX) has become the first-line treatment for CD, producing satisfactory relief of symptoms in > 80% of cases. Unresolved issues that may impact on the overall results include the method of selection for injection sites (clinical vs. electromyography), dosing, dilution and the role and relative efficacy of the different BTX serotypes. A guiding therapeutic principle of BTX injections is to achieve optimal results with the lowest possible dosage and frequency of administration. This strategy is critical in order to keep the risk of immunoresistance at a minimum. Development of antibodies that block the effects of BTX, usually associated with frequent injections of high doses, is the main reason for secondary unresponsiveness to this treatment. Although the mechanism of denervation at the neuromuscular junction by BTX is relatively well understood, the role of changes in muscle spindles and myopathic pain mechanisms, as well as secondary changes at the level of the basal ganglia, thalamus and cortex and their role in response to BTX, all need further exploration.

The benzamide tiapride: treatment of extrapyramidal motor and other clinical syndromes.

The benzamide derivative tiapride (Tiapridex, Synthelabo) has a highly selective antagonistic effect on striatal adenylate cyclase-independent dopamine-2 receptors. Its in vitro binding affinity is especially high for dopamine receptors which have been sensitized by pre-incubation with dopamine. The involvement of altered dopamine receptor sensitivity in several extrapyramidal dys- and hyperkinesia has been hypothesized. By its high affinity for these receptors, without any affinity for other neurotransmitter receptors of the brain, tiapride is especially well suited for the treatment of movement disorders related to functional dopamine hyperactivity. Even at higher doses, tiapride does not exceed a D2-receptor occupancy of 80%, which is in accordance with the finding that tiapride rarely causes acute extrapyramidal syndromes and has, up to now, never implicated in inducing tardive dyskinesias. On the contrary, clinical studies demonstrate its excellent efficacy in neuroleptic-induced tardive dyskinesia, L-Dopa-induced dyskinesias, psychomotor agitation in geriatric patients and choreatic movement disorders. Since tiapride is not available in the USA as yet, most of the studies concerning tiapride have been carried out in Europe. In a recent study, based on objective measurements, tiapride effectively controlled choreatic movements in patients suffering from Huntington's disease (HD). Tiapride is well tolerated in daily doses between 300 and 1200 mg. Adverse events are generally rare and mild.

Increased plasma concentrations of bromperidol and its reduced metabolite with levomepromazine, but not with thioridazine.

Bromperidol is a close structural analog of haloperidol. The authors studied the effects of levomepromazine and thioridazine, which are frequently added to other neuroleptics as sedatives, on plasma concentrations of bromperidol and its reduced metabolite. The subjects were 26 inpatients with schizophrenia receiving bromperidol, 12 to 24 mg/day, for 1 to 19 weeks. In 10 cases, 50 mg levomepromazine per day and in nine cases, 50 mg thioridazine per day were coadministered for 1 week. In seven cases, both drugs were coadministered with > or = 2-week intervals. Plasma concentrations of bromperidol and reduced bromperidol were measured by a high-performance liquid chromatographic method. Levomepromazine (n = 17) significantly (p < 0.001) increased plasma concentrations of bromperidol (7.3 +/- 4.1 versus 10.2 +/- 4.8 ng/ml) and reduced bromperidol (1.8 +/- 1.4 versus 4.5 +/- 3.3 ng/ml). Thioridazine (n = 16) did not significantly change plasma concentrations of bromperidol (9.1 +/- 5.7 versus 8.6 +/- 5.5 ng/ml), while those of reduced bromperidol could not be measured because of interfering peaks. The current study suggests that levomepromazine, but not thioridazine, increases plasma concentrations of bromperidol and reduced bromperidol by inhibiting the metabolism of these compounds.