F. W. H. M. Merkus scite author profile

Dapsone (DDS) has for about 4 decades been the most important antileprosy drug. Concentrations of dapsone and its monoacetyl metabolite, MADDS, can be determined in biological media by high-performance liquid chromatography. After oral administration, the drug is slowly absorbed, the maximum concentration in plasma being reached at about 4 hours, with an absorption half-life of about 1.1 hours. However, the extent of absorption has not been adequately determined. The elimination half-life of dapsone is about 30 hours. The drug shows linear pharmacokinetics within the therapeutic range and the time-course after oral administration fits a 2-compartment model. The concentration-time profile of dapsone after parenteral administration is reviewed. Of clinical importance is the development of a new long acting injection, which permits monthly supervised administration as recommended by the World Health Organization. Following dapsone injection in gluteal subcutaneous adipose tissue, a sufficiently sustained absorption for this purpose has been reported. Dapsone is about 70 to 90% protein bound and its monoacetylated metabolite (MADDS) is almost completely protein bound. The volume of distribution of dapsone is estimated to be 1.5 L/kg. It is distributed in most tissues, but M. leprae living in the Schwann cells of the nerves might be unaffected. Dapsone crosses the placenta and is excreted in breast milk and saliva. Dapsone is extensively metabolised. Dapsone, some MADDS and their hydroxylated metabolites are found in urine, partly conjugated as N-glucuronides and N-sulphates. The acetylation ratio (MADDS:dapsone) shows a genetically determined bimodal distribution and allows the definition of 'slow' and 'rapid' acetylators. As enterohepatic circulation occurs, the elimination half-life of dapsone is markedly decreased after oral administration of activated charcoal. This permits successful treatment in cases of intoxication. The daily dose of dapsone in leprosy is 50 to 100mg, but varies from 50 to 400mg in the treatment of other dermatological disorders. In malaria prophylaxis, a weekly dose of 100mg is used in combination with pyrimethamine. Side effects are mostly not serious below a daily dose of 100mg and are mainly haematological effects. The dapsone therapeutic serum concentration range can be defined as 0.5 to 5 mg/L. Alcoholic liver disease decreases the protein binding of dapsone; coeliac disease and dermatitis herpetiformis may delay its oral absorption and severe leprosy has been reported to affect the extent of absorption.(ABSTRACT TRUNCATED AT 400 WORDS)

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Nasal mucociliary clearance as a factor in nasal drug delivery

Marttin

Schipper

Verhoef

et al. 1998

Advanced Drug Delivery Reviews

357

134

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Can Nasal Drug Delivery Bypass the??Blood-Brain Barrier?

Merkus

Berg

2007

Drugs in R & D

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The connection between the nasal cavity and the CNS by the olfactory neurones has been investigated extensively during the last decades with regard to its feasibility to serve as a direct drug transport route to the CSF and brain. This drug transport route has gained much interest as it may circumvent the blood-brain barrier (BBB), which prevents some drugs from entering the brain. Approximately 100 published papers mainly reporting animal experiments were reviewed to evaluate whether the experimental design used and the results generated provided adequate pharmacokinetic information to assess whether the investigated drug was transported directly from the olfactory area to the CNS. In the analysis the large anatomical differences between the olfactory areas of animals and humans and the experimental conditions used were evaluated. The aim of this paper was to establish the actual evidence for the feasibility of this direct transport route in humans. Twelve papers presented a sound experimental design to study direct nose to CNS transport of drugs based on the authors' criteria. Of these, only two studies in rats were able to provide results that can be seen as an indication for direct transport from the nose to the CNS. No pharmacokinetic evidence could be found to support a claim that nasal administration of drugs in humans will result in an enhanced delivery to their target sites in the brain compared with intravenous administration of the same drug under similar dosage conditions.

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Direct access of drugs to the human brain after intranasal drug administration?

Merkus¹,

Guchelaar²,

Bosch³

et al. 2003

Neurology

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It has been suggested that intranasal (IN) drug delivery could be used to administer drugs directly to the brain, bypassing the blood-brain barrier. Conclusive evidence of this proposed route of drug transport has not been observed by IN-IV comparison. In eight neurosurgery patients with a CSF drain, the uptake in CSF and plasma after IN and IV drug administration was compared. No evidence of direct access of the drugs from the nose to the CSF was found.

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F. W. H. M. Merkus

Clinical Pharmacokinetics of Dapsone

Nasal mucociliary clearance as a factor in nasal drug delivery

Can Nasal Drug Delivery Bypass the??Blood-Brain Barrier?

Direct access of drugs to the human brain after intranasal drug administration?

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