In situ coating makes it easier for children to swallow and tolerate tablets and capsules.

AIM: Getting children to swallow tablets and capsules is a challenge, and factors that influence their ability to swallow include taste, smell and texture. The aim of this study was to explore how well paediatric patients tolerated and accepted the MedCoat(®) in situ coating for tablets and capsules. METHODS: A nonrandomised intervention study was performed at the Astrid Lindgren Children's Hospital, Karolinska University Hospital, Sweden. We identified 78 paediatric patients, 43 females and 35 males, who had problems swallowing tablets and capsules and evaluated their abilities with questionnaires. The median age of the patients was nine years old, and the range was two to 17 years old. RESULTS: Swallowing ability and palatability was improved by in situ coating. The results showed that 66 of 77 paediatric patients (86%, 95% confidence interval: 76-93%) were able to take the drugs they had been prescribed after in situ coating. Swallowing improved in 87% of cases, and palatability improved in 85% of cases. CONCLUSION: A study of 77 paediatric patients with a median age of nine years, and a range of two to 17 years, found that 86% were able to take the tablets and capsules they had been prescribed after they were coated with the MedCoat.

Paediatric drug use with focus on off-label prescriptions at Swedish hospitals - a nationwide study.

AIM: To perform a nationwide investigation of paediatric drug use at Swedish hospitals, including an analysis of off-label drug use. METHODS: All paediatric hospitals in Sweden were invited to register all prescriptions to children, aged between 0 and 18, during two separate 2-day-periods in 2008. Data were reported and analysed with respect to licence status and proportion of and reasons for off-label drug use. RESULTS: Data on 11,294 prescriptions to 2947 paediatric patients were received. Drugs associated with pain relief, infection, prematurity, nutrition and surgery or anaesthesia were most commonly used. Paracetamol was the most frequently used drug on-label and also among the most commonly used off-label drugs. Nearly half (49%) of all administered prescriptions concerned unlicensed drugs, off-label drugs or extemporaneously prepared drugs. The corresponding rate among neonates was 69%. Lack of paediatric information in the Summary of Product Characteristics was the main reason for off-label classification. CONCLUSIONS: Paediatric off-label drug use is common at Swedish hospitals, and nearly half of all prescriptions were not documented for use in children. The findings emphasize a need for paediatric clinical studies as well as compilation of existing clinical experience and scattered evidence, particularly for drug treatment in infants and neonates.

In vitro topo II--DNA complex accumulation and cytotoxicity of etoposide in leukaemic cells from patients with acute myelogenous and chronic lymphocytic leukaemia.

Topoisomerase II (topo II) is the target enzyme of etoposide, and DNA--topo II complex accumulation is considered crucial for the cytotoxic effect. We used a SDS--KCl precipitation assay to determine the complex accumulation induced by etoposide in leukaemic cells isolated from 58 patients, 31 with acute myelogenous leukaemia (AML), and 27 with chronic lymphocytic leukaemia (CLL). To investigate whether the sensitivity towards etoposide was dependent on the complex accumulation in the cells, we investigated the drug-induced DNA damage using a DNA unwinding assay and the in vitro cytotoxicity of etoposide using the MTT assay. AML cells had higher complex accumulation (P=0.006) and more DNA damage (P=0.029) compared with CLL cells. The data support a relationship between etoposide-induced complex accumulation and DNA damage in leukaemic cells from AML and CLL patients. However, the induced DNA damage did not translate to in vitro cytotoxicity, suggesting that other factors, such as DNA repair and apoptosis functions, also play important roles to determine the etoposide sensitivity.

Distribution of 2-chloro-2'-deoxyadenosine, 2-chloro-2'-arabino-fluoro-2'-deoxyadenosine, fludarabine and cytarabine in mice: a whole-body autoradiography study.

The distribution characteristics of tritiated nucleoside analogs, 2-chloro-2'-deoxyadeonosine (CdA), 2-chloro-2'-arabino-fluoro-2'-deoxyadenosine (CAFdA), 2-fluoroarabinosyladenine (F-ara-A) and cytosine arabinoside (ara-C) were compared in mice using whole-body autoradiography. CdA, CAFdA and F-ara-A have quite similar molecular structures, but they differ substantially in clinical activity as well as the side effects. Eight mice were injected intravenously in couples. One mouse from each pair was killed 20 min postinjection and the other mouse from each pair 4 h after the injection. The distribution of the label was then analyzed by whole-body autoradiography. The distribution of the nucleoside analogs was rapid and uniform. High concentrations were found in highly perfused organs. After 4 h the overall concentration had decreased but relatively high activities were found in the skin for CdA and CAFdA, in the thymus for ara-C and the bone marrow for CdA. Both CdA and CAFdA were found in the brain, but the concentration was surprisingly lower after 4 h for CAFdA, a lipophilic and more stable analog as compared to CdA. There was an uptake of CdA, F-ara-A and CAFdA in the skin. There were signs of retention of ara-C in parts of the thymus. The present investigations indicate that the nucleoside analog transport to the brain in mice is not primarily dependent upon passive diffusion over a lipophilic barrier, but suggestive of a specific transport mechanism.

Pharmacokinetics of cladribine in plasma and its 5'-monophosphate and 5'-triphosphate in leukemic cells of patients with chronic lymphocytic leukemia.

The pharmacokinetic parameters of cladribine (CdA) in patient plasma and its intracellular nucleotides CdA 5'-monophosphate (CdAMP) and CdA 5'-triphosphate (CdATP) were delineated in circulating leukemia cells in 17 patients with chronic lymphocytic leukemia, after the last dose intake and up to 72 h thereafter. Patients were treated with 10 mg/m2 CdA p.o. on 3 consecutive days. A novel and specific ion-pair liquid chromatographic method, which separates the intracellular CdA nucleotides, was used. The area under the concentration versus time curve (AUC) of CdAMP in leukemia cells was generally higher (median, 47 micromol/liter x h) than the AUC of CdATP (median, 22 micromol/liter x h); however, in some patients (3 of 17), the reverse relationship was seen. The median ratio between the AUC values for CdATP and CdAMP was 0.60 (95% confidence interval, 0.4-1.0). The median half-life (t(1/2)) of CdAMP was 15 h, and that of CdATP was 10 h. The median terminal t(1/2) of CdA in plasma was 21 h. A significant correlation was found between the maximum plasma CdA and cellular CdAMP concentrations (r = 0.56, P = 0.02). There was no correlation between the AUC values of cellular CdAMP and CdATP (r = 0.224, P = 0.55). No correlation was found between deoxycytidine kinase activity and intracellular pharmacokinetic parameters of CdAMP or CdATP. The response to treatment was not significantly related to intracellular concentration of CdAMP or active metabolite CdATP. There is great heterogeneity among patients in terms of AUC and t(1/2) of CdAMP and CdATP. Furthermore, the results emphasize the differences between the pharmacokinetics of plasma CdA and those of the metabolites in circulating leukemic cells.

Relationship between cladribine (CdA) plasma, intracellular CdA-5'-triphosphate (CdATP) concentration, deoxycytidine kinase (dCK), and chemotherapeutic activity in chronic lymphocytic leukemia (CLL).

Seventeen patients with CLL were treated with oral 2-chloro-2'-deoxyadenosine (cladribine, CdA, 10 mg/m2) on 3 consecutive days and the pharmacokinetic parameters of CdA in patient plasma and its intracellular nucleotides (CdAMP, CdATP) in circulating leukemic cells were studied after the last dose intake and up to 72 h thereafter. The median terminal half life (t1/2) of CdA in plasma was 21.1 h and the area under the curve (AUC) was median 1.2 microMh. The median t1/2 was 14.6 h for CdAMP and 9.7 h for CdATP. The AUC of CdATP in leukemic cells is lower than the AUC of CdAMP (median ratio 0.60). There was no correlation between cellular CdATP and plasma CdA concentrations or dCK activity. The clinical response was related to higher Cmax values for plasma CdA (p = 0.05) and higher products of dCK activity and CdA Cmax of plasma (p = 0.02). The activity of dCK alone was not related to the clinical outcome in this patient group. The results suggest that further steps in the mechanism of action of CdA beyond its bioactivation may be more important, e.g. the extent of DNA fragmentation or the ability of the leukemic cell to go into apoptosis, than the concentration of CdA nucleotides alone.

Stability and analysis of 2-chloro-2'-deoxyadenosine, 2-chloro-2'-arabino-fluoro-2'-deoxyadenosine and 2-chloroadenine in human blood plasma.

Cladribine (2-chloro-2'-deoxyadenosine, CdA) is a purine nucleoside analog with activity against lymphoproliferative and autoimmune disorders. 2-Chloro-2'-arabino-fluoro-2'-deoxyadenosine (CAFdA), a derivative of CdA with better acid stability, shows a similar in vitro spectrum of activity as CdA. 2-Chloroadenine (CAde) is the major catabolite of both CdA and CAFdA. We have developed a high performance liquid chromatography method to measure CdA, CAFdA and their metabolite CAde in plasma. This method employees an internal standard, chloroadenosine (CAdo), and a C8 solid-phase extraction to isolate and concentrate the substances. Chromatographic separation was achieved using a C8 reverse-phase column, with UV detection at 265 nm, which gives a limit of detection of 1 nmol/l for all substances. The method was reproducible with intra- and inter-assay coefficients of variations below 6% at 50 nmol/l and at 5 nmol/l below 23%. The average recoveries of CdA, CAde, CAFdA and the internal standard were higher than 70%. Stability studies of authentic patient samples show that samples containing CdA should be kept in a refrigerator or on ice to prevent degradation. Plasma containing CAde should not be kept at -20 degrees C for longer than 10 weeks before analysis. CdA and CAFdA remain almost stable during storage at -20 degrees C for 12 weeks.