Evaluation of bioequivalence after oral, intramuscular, and intravenous administration of racemic ketoprofen in pigs.

OBJECTIVE: To assess bioequivalence after oral, IM, and IV administration of racemic ketoprofen in pigs and to investigate the bioavailability after oral and IM administration. ANIMALS: 8 crossbred pigs. PROCEDURES: Each pig received 4 treatments in a randomized crossover design, with a 6-day washout period. Ketoprofen was administered at 3 and 6 mg/kg, PO; 3 mg/kg, IM; and 3 mg/kg, IV. Plasma ketoprofen concentrations were measured by use of high-performance liquid chromatography for up to 48 hours. To assess bioequivalence, a 90% confidence interval was calculated for the area under the time-concentration curve (AUC) and maximum plasma concentration (C(max)). RESULTS: Equivalence was not detected in the AUCs among the various routes of administration nor in C(max) between oral and IM administration of 3 mg/kg. The bioavailability of ketoprofen was almost complete after each oral or IM administration. Mean +/- SD C(max) was 5.09 +/- 1.41 microg/mL and 7.62 +/- 1.22 microg/mL after oral and IM doses of 3 mg/kg, respectively. Mean elimination half-life varied from 3.52 +/- 0.90 hours after oral administration of 3 mg/kg to 2.66 +/- 0.50 hours after IV administration. Time to peak C(max) after administration of all treatments was approximately 1 hour. Increases in AUC and C(max) were proportional when the orally administered dose was increased from 3 to 6 mg/kg. CONCLUSIONS AND CLINICAL RELEVANCE: Orally administered ketoprofen was absorbed well in pigs, although bioequivalence with IM administration of ketoprofen was not detected. Orally administered ketoprofen may have potential for use in treating pigs.

Formulation and in-vivo evaluation of L-cysteine chewing gums for binding carcinogenic acetaldehyde in the saliva during smoking.

Cigarette smoke contains toxic amounts of acetaldehyde that dissolves in saliva, posing a significant risk of developing oral, laryngeal and pharyngeal carcinomas. L-cysteine, a non-essential amino acid, can react covalently with carcinogenic acetaldehyde to form a stable, non-toxic 2-methylthiazolidine-4-carboxylic acid. The main aim of this study was to find out whether it is possible to develop a chewing gum formulation that would contain cysteine in amounts sufficient to bind all the acetaldehyde dissolved in saliva during the smoking of one cigarette. The main variables in the development process were: (1) chemical form of cysteine (L-cysteine or L-cysteine hydrochloride), (2) the amount of the active ingredient in a gum and (3) manufacturing procedure (traditional or novel compression method). Saliva samples were taken over 2.5 minutes before smoking and since smoking was started for 2.5 minutes periods for 10 minutes. During a five minutes smoking period with a placebo chewing gum, acetaldehyde levels increased from 0 to 150-185 microM. Once smoking was stopped, the acetaldehyde levels quickly fell to levels clearly below the in-vitro mutagenic level of 50 microM. All chewing gums containing cysteine could bind almost the whole of the acetaldehyde in the saliva during smoking. However, elimination of saliva acetaldehyde during smoking does not make smoking completely harmless. Cysteine as a free base would be somewhat better than cysteine hydrochloride due to its slower dissolution rate. Both traditional and direct compression methods to prepare chewing gums can be utilized and the dose of L-cysteine required is very low (5 mg).

Effects of urine alkalization and activated charcoal on the pharmacokinetics of orally administered carprofen in dogs.

OBJECTIVE: To investigate the effects of oral administration of activated charcoal (AC) and urine alkalinization via oral administration of sodium bicarbonate on the pharmacokinetics of orally administered carprofen in dogs. ANIMALS: 6 neutered male Beagles. PROCEDURES: Each dog underwent 3 experiments (6-week interval between experiments). The dogs received a single dose of carprofen (16 mg/kg) orally at the beginning of each experiment; after 30 minutes, sodium bicarbonate (40 mg/kg, PO), AC solution (2.5 g/kg, PO), or no other treatments were administered. Plasma concentrations of unchanged carprofen were determined via high-performance liquid chromatography at intervals until 48 hours after carprofen administration. Data were analyzed by use of a Student paired t test or Wilcoxon matched-pairs rank test. RESULTS: Compared with the control treatment, administration of AC decreased plasma carprofen concentrations (mean +/- SD maximum concentration was 85.9 +/- 11.9 mg/L and 58.1 +/- 17.6 mg/L, and area under the time-concentration curve was 960 +/- 233 mg/L x h and 373 +/- 133 mg/L x h after control and AC treatment, respectively). The elimination half-life remained constant. Administration of sodium bicarbonate had no effect on plasma drug concentrations. CONCLUSIONS AND CLINICAL RELEVANCE: After oral administration of carprofen in dogs, administration of AC effectively decreased maximum plasma carprofen concentration, compared with the control treatment, probably by decreasing carprofen absorption. Results suggest that AC can be used to reduce systemic carprofen absorption in dogs receiving an overdose of carprofen. Oral administration of 1 dose of sodium bicarbonate had no apparent impact on carprofen kinetics in dogs.

Are chitosan formulations mucoadhesive in the human small intestine? An evaluation based on gamma scintigraphy.

Rapid passage through the proximal intestine can result in the low bioavailability of a drug substance with site-specific absorption characteristics in the upper gastrointestinal tract. To overcome this, there is increasing interest in developing gastro-retentive formulations and/or formulations that linger in the proximal parts of the small intestine, e.g. by using mucoadhesive polymers as excipients in formulations. In our recent study, we used neutron activation-based gamma scintigraphy to evaluate the gastro-retentive properties of formulations containing chitosan (Mw 150 kDa) in man. At the same time, we had an opportunity to monitor the transit of the formulations (40 or 95% of chitosan) in the small intestine. Gamma scintigraphic investigations revealed that although the chitosan studied had exhibited marked mucoadhesive capacities in vitro, retention of the chitosan formulations in the upper gastrointestinal tract was not sufficiently reproducible and the duration of retention was relatively short. In 3 volunteers out of 10, the formulation adhered to the gastric mucosa (retention times varied from 1.25 to 2.5 h) and in two volunteers to the upper small intestine (approximate retention time 45 min). In one case, the formulation adhered to the oesophagus. The system failed to increase the bioavailability of furosemide, a drug site-specifically absorbed in the upper gastrointestinal tract. As far as the kind of formulation studied is concerned, preparation of a system that is site-specific to the stomach and/or the upper small intestine seems difficult if the proposed mechanism of action is mucoadhesion. The results suggest that other mechanisms of action should also be studied.

Gamma scintigraphic evaluation of the fate of microcrystalline chitosan granules in human stomach.

In several reports of in vitro studies it has been suggested that the mucoadhesive chitosans could be of value in preparing gastro-retentive formulations. The aim of this study was to obtain direct in vivo evidence of whether microcrystalline chitosan (MCCh) formulations acted as gastro-retentive systems in humans. Neutron-activation-based gamma scintigraphy was used to study gastric residence times of MCCh granules in healthy male volunteers. Possible effects of neutron irradiation on the properties of the MCCh granules were studied in advance, in vitro. In vivo gamma scintigraphic evaluations were carried out with the subjects in a fasted state, using granules containing 95% (F1) or 40% (F2) of MCCh of molecular weight 150 kDa. Reference formulation (F3) was lactose granules. The reference granules passed rapidly from the stomach (mean t50% 0.5+/-0.3 h (n=5)). MCCh in granules prolonged gastric residence times of the formulations in only a few cases (in one volunteer in the F1 group (n=4) and in two volunteers in the F2 group (n=5)). Maximum individual t50% values were 2.1 h (F1) and 2.3 h (F2). It was concluded that the in vivo mucoadhesion of MCCh formulations is erratic, and that the formulations studied are not reliable gastro-retentive drug delivery systems.

Scintigraphic verification of adherence of a chitosan formulation to the human oesophagus.

It is well known that adherence of a drug product, e.g. a gelatine capsule, to the oesophagus can cause oesophageal injury, which can be severe if the medicinal agent has corrosive properties. In a recent study we investigated by means of gamma scintigraphy whether chitosan granules dispensed in gelatine capsules had gastro-retentive properties. In one of ten volunteers the formulation lodged in the oesophagus. This case is reported here. The capsule adhered initially to the distal oesophagus. The capsule shell had started to disintegrate within 5 min, with some radioactivity detectable in the stomach. However, about two thirds of the radioactivity remained detectable in the oesophageal region for 1.75 h. This could be explained on the basis that there had been adherence not only of the gelatine shell but also of chitosan granules to the oesophageal mucosa. In evaluating potential for causing oesophageal injury it is not enough to consider only the mucoadhesive properties of the outermost layer of a drug product, because the filler may also have such properties. When new excipient materials are introduced, evaluation of their mucoadhesive tendencies is important.

Evaluation of microcrystalline chitosans for gastro-retentive drug delivery.

In vivo absorption studies were carried out in human volunteers to evaluate whether microcrystalline chitosan (MCCh) granules would be gastro-retentive. Furosemide, which is site-specifically absorbed from the upper gastrointestinal tract, was used as model drug. The rate of release of furosemide in vitro could be prolonged by increasing the molecular weight (M(w)) or amount of MCCh (150 to 240 kDa; 80 to 95%) in the granules, and also by addition of acidic excipients to the formulations. No marked changes in the in vivo absorption rate (t(max)) were noted, but the amounts of furosemide absorbed (AUC(0- infinity ) and C(max)) decreased as the in vitro release rate decreased, although this was not statistically significant in the case of AUC. The highest AUC(0- infinity ) (3050 micro g l(-1) h) for furosemide (40 mg) was achieved with granules containing 80% MCCh of 150 kDa M(w). With MCCh of 240 kDa M(w) AUC(0- infinity ) was 1890 micro g l(-1) h. This kind of pharmacokinetic profile of furosemide suggests that the gastric retention time of the granules is too short in relation to the release rate, and a large amount of the drug passes its "absorption window" before being released. The in vivo study produced no evidence that the chitosan formulations studied can be used as mucoadhesive gastro-retentive drug delivery systems. The results of in vitro mucoadhesion studies did not predict the results of in vivo studies.

In vitro evaluation of microcrystalline chitosan (MCCh) as gel-forming excipient in matrix granules.

Although much research has been carried out into the effects of chitosan and its chemical properties on drug release, less attention has been paid to the effects of its physical properties. The aim of this study was to characterize microcrystalline chitosan (MCCh) as a gel-forming excipient. Matrix granules containing chitosans of differing physicochemical properties (crystallinity, molecular weight, degree of deacetylation) and ibuprofen or paracetamol as model drugs were prepared. Gel formation by the chitosans in the granules and subsequent effects on drug release were studied at pH 1.2 and pH 5.8. The chitosan granules acted as slow-release formulations in the case of ibuprofen (a class-II drug in the Biopharmaceutics Classification System) but with paracetamol (class-I) no controlled-release formulation could be developed. Microcrystalline grades of chitosan had the most marked retardant effects on drug release, with the efficacy of gel formation by MCCh explaining the results. The kinetic constant for ibuprofen release (at pH 5.8) ranged from 22%.h(-1) (MCCh) to 31%.h(-1) (unmodified chitosan). The release rate was easily controlled by varying the amount or molecular weight of MCCh, and to a lesser extent by the degree of deacetylation. The effects were most pronounced when pH was markedly acidic, suggesting that MCCh granules might be particularly useful in preparing stomach-specific slow-release dosage forms.