Martti Marvola

Extrusion-spheronization of pH-sensitive polymeric matrix pellets for possible colonic drug delivery.

The aim of this study was to investigate extrusion-spheronization pelletization for preparing pH-sensitive matrix pellets for colon-specific drug delivery. The effects of three independent variables (amounts of Eudragit S, citric acid and spheronizing time) on pellet size, shape (roundness and aspect ratio), and drug release were studied with central composite design. The pellets contained ibuprofen as a model drug, citric acid as a pH-adjusting agent, Eudragit S as a pH-sensitive binder and microcrystalline cellulose (MCC). The pellets were prepared with Nica extrusion-spheronizing equipment and subsequently enteric-coated using an air-suspension technique. Eudragit S as a pH-sensitive matrix former in pellets increased the pellet size and influenced pellet roundness. In small amounts Eudragit S increased pellet roundness but in larger amounts pellet roundness was reduced. Citric acid promoted the pelletization process resulting in a narrower area distribution. The pH-sensitive matrix pellet failed to delay the drug release. The combination of citric acid and enteric coating, however, delayed the drug release for 15 min in a pH 7.4 phosphate buffer.

Enteric polymers as binders and coating materials in multiple-unit site-specific drug delivery systems

The aim of this study was to develop a multiple-unit, site-specific drug formulation allowing targeting of drug release in the colon. Initially, characteristics of matrix pellets containing various enteric polymers as binders were tested. An enteric coating was then added to the formulations. Ibuprofen and furosemide were used as model drugs. The former is absorbed throughout the gastrointestinal tract, the latter only from upper parts. Methacrylate copolymers, hydroxypropyl methylcellulose acetate succinates and cellulose acetate phthalate were used as enteric polymers. The properties of the products were initially tested via dissolution studies at different pHs, then via bioavailability studies in healthy volunteers. The main conclusion was that drug release can be targeted on the distal part of the small intestine and the colon by preparing film-coated matrix pellets in which enteric polymers dissolving at pH approximately 7 have been used both as binders in the pellets and as coating material. This conclusion is based on the finding that absorption of ibuprofen from the formulations developed was adequate, with a lag-time of about 2 h and tmax values at 4-5 h, where as absorption of furosemide from the analogous products was negligible. It was also found that uncoated pellets as such could represent a slow-release formulation for furosemide, a problem drug as far as modified-release products are concerned.

In vitro release of dexmedetomidine from silica xerogel monoliths: effect of sol-gel synthesis parameters

Dexmedetomidine, an alpha 2-agonist, was incorporated as a hydrochloride salt into silica xerogel in order to evaluate the effect of sol-gel synthesis parameters: pH of the sol, water/alkoxide molar ratio, drug concentration and size of the device on the drug release rate and degradation rate of the matrix. This study showed that diffusion controlled the release of dexmedetomidine from silica xerogel prepared between pH 1 and pH 5. The drug release was, however, slowest near the zero charge of silica xerogel (pH 2-3). The burst of dexmedetomidine, a lipophilic, but in the form of hydrochloride salt water-soluble drug, was increased from the matrix prepared either below or above the isoelectric point. It follows that the optimum pH for preparing a drug delivery device for dexmedetomidine, is near the zero charge of silica xerogel, where the degradation of the matrix was also slowest. In addition to processing pH, the release rate of drugs can be controlled by changing the water/alkoxide molar ratio of the sol.

Alkyl-substituted silica gel as a carrier in the controlled release of dexmedetomidine.

The effect of alkyl substitution of the silica xerogel matrix on the release rate of dexmedetomidine was evaluated. Silica sol was processed by either casting or spray drying. When the reaction precursor tetraethylorthosilicate (TEOS) was partially substituted with tri- or dialkoxysilane, the release of dexmedetomidine and degradation of the matrix were decreased compared with 100% TEOS-based gel. Increasing the number or length of the organic groups attached to silicon, modified the silica gel structure and reduced the release rate of dexmedetomidine from monoliths. The release of dexmedetomidine from alkyl-substituted silica gel microparticles, however, showed a burst in drug release. Subcutaneously administered silica xerogel matrices (manufactured by casting, containing 25 mol% dimethyldiethoxysilane at two different doses of dexmedetomidine) were studied in dogs. Sustained delivery of dexmedetomidine was obtained for at least 48 h.

Removal of acetaldehyde from saliva by a slow-release buccal tablet of L-cysteine

High alcohol intake is an independent risk factor for upper gastrointestinal (GI)‐tract cancers. There is increasing evidence that acetaldehyde, the first metabolite of ethanol, might be responsible for ethanol‐associated carcinogenesis. Especially among Asian heavy drinkers with the ALDH2‐deficiency gene, i.e., a genetic inability to remove acetaldehyde, the risk of digestive tract cancers is markedly increased. Local acetaldehyde production from ethanol either by oral microbes, mucosal cells or salivary glands is a plausible carcinogenic agent in the saliva. The aim of our study was to examine whether is it possible to bind carcinogenic acetaldehyde from saliva with L‐cysteine, which is slowly released from a special buccal tablet. Nine healthy male volunteers took part in our study, and each subject served as his own control. A placebo or L‐cysteine‐containing tablet was fastened under the upper lip. Thereafter the volunteers ingested 0.8 g/kg of body weight of 10% (v/v) ethanol, and saliva samples were collected at 20 min intervals for 320 min. Salivary acetaldehyde and ethanol levels were analysed by headspace gas chromatography. The mean reduction of acetaldehyde concentration of the saliva with the L‐cysteine tablet compared to placebo was 59% (CL95% 43%, 76%). Area under the curve (AUC0–320min) with the L‐cysteine and placebo tablet were 54.3 ± 11 μM × hr and 162 ± 34.2 μM × hr (mean ± SEM), respectively (p = 0.003). After alcohol intake, up to two‐thirds of carcinogenic acetaldehyde can be removed from saliva with a slow‐releasing buccal L‐cysteine drug formulation. Thus, a buccal cysteine tablet could potentially be used to prevent upper GI‐tract cancers, especially among high‐risk individuals.

Eliminating Carcinogenic Acetaldehyde By Cysteine From Saliva During Smoking

Tobacco smoking is one of the strongest risk factors not only for lung cancer but also for cancers of the upper gastrointestinal tract. Acetaldehyde has been shown to dissolve into the saliva during smoking and to be a local carcinogen in the human upper digestive tract. Cysteine can bind to acetaldehyde and eliminate its toxicity. We developed a tablet that releases cysteine into the oral cavity during smoking and could therefore be a potential chemopreventive agent against toxicity of tobacco smoke. In this study, the efficacy of l-cysteine–containing tablets to reduce the carcinogenic acetaldehyde in the saliva during tobacco smoking was examined. Seven volunteers smoked five cigarettes. During every smoking period, each volunteer sucked a blinded tablet containing 0, 1.25, 2.5, 5, or 10 mg of l-cysteine. Acetaldehyde was analyzed from salivary samples gas chromatographically at 0, 5, and 10 minutes from the beginning of the smoking. All tablets containing l-cysteine reduced highly significantly the salivary acetaldehyde; 5 mg of l-cysteine was the minimum concentration to totally eliminate the acetaldehyde from saliva. The mean salivary acetaldehyde concentrations in samples collected immediately after smoking with 0, 1.25, 2.5, 5, or 10 mg of l-cysteine were 228 ± 115 μmol/L, 85 ± 42 μmol/L (P = 0.007), 9 ± 7 μmol/L, 0.09 ± 0.2 μmol/L, 0 ± 0 μmol/L (P < 0.001), respectively. In conclusion, carcinogenic acetaldehyde could be totally inactivated in the saliva during smoking by sucking tablet containing 5 mg of l-cysteine. Even a small reduction of the carcinogenicity of cigarette smoke could gain benefit at the population level. Hence, this finding warrants for further clinical trials for l-cysteine tablet in the prevention of upper digestive tract cancers in smokers. (Cancer Epidemiol Biomarkers Prev 2006;15(1):146–9)

Citric acid as excipient in multiple-unit enteric-coated tablets for targeting drugs on the colon.

Delivery of drugs to the large bowel has been extensively investigated during the last decade. The aim of this study was to investigate whether enteric-coated tablets could be made from enteric-coated matrix granules and drug release targeted to the colon. Whether in vitro drug release rate and in vivo absorption could be delayed by adding citric acid to the granules and/or to the tablet matrix was also studied. Ibuprofen was used as model drug because it is absorbed throughout the gastrointestinal tract. Eudragit S and Aqoat AS-HF were used as enteric polymers. Drug release rates were studied at different pH levels and drug absorption was studied in bioavailability tests. The conclusion was that citric acid retarded in vitro drug release when used in multiple-unit tablets. In vivo absorption of ibuprofen was markedly delayed when citric acid was included in both granules and tablet matrix. Further studies are needed to determine the optimal amount of citric acid in formulations.

Effect of synthesis parameters of the sol-gel-processed spray-dried silica gel microparticles on the release rate of dexmedetomidine.

The objective of this study was to evaluate the possibilities to control the release rate of dexmedetomidine (DMED) from different spray-dried silica gel microparticle formulations. Microparticles were prepared by spray drying a silica sol polymer solution containing the drug. Drug release was investigated both in vitro and in vivo. The influence of sol-gel synthesis parameters, like pH and the water/alkoxide ratio (r) of the sol, on the release behaviour of the drug was studied. Silica gel microparticles had a smooth surface. Microparticles prepared from diluted sol, however, were more aggregated and clustered. The drug release conformed to zero order release from microparticles prepared near the isoelectric point of silica (pH 2.3 and pH 3) and to the square root of time kinetics from microparticles prepared at pH 1 and pH 5. The release also showed a dual-phasic profile with an initial burst and after that a slower release period. The dexmedetomidine release conformed to zero order kinetics from microparticles prepared at water/ alkoxide ratios between r = 6 and r = 35 (at pH 2.3). The release rate was the slowest from microparticles prepared with water/ alkoxide ratio 35. The bioavailability of dexmedetomidine in dogs showed that the release was sustained from silica gel microparticles as compared with a subcutaneously administered reference dose of 0.1 mg.

Organic acids as excipients in matrix granules for colon-specific drug delivery.

Interest exists in developing site-specific systems for release of a drug in the lower part of the small intestine or in the colon. The aim of this study was to investigate whether drug release rates from enteric matrix granules could be influenced by using organic acids as excipients. Ibuprofen was used as a model drug and Eudragit S and Aqoat AS-HF as enteric polymers. The dissolution rates of the drug were investigated at different levels of pH (5.8, 6.8 and 7. 4). Drug absorption was studied in bioavailability tests in healthy volunteers. In vitro/in vivo correlation was also investigated. It was concluded that although inclusion of an organic acid in a formulation retarded in vitro release of the model drug, no corresponding effect was evident in in vivo studies. Bioavailability tests are therefore important early on during development of new dosage forms or formulations. Although no correlation between in vitro and in vivo results was generally evident correlation could be demonstrated for individual formulations following mathematical transformation of data.

Morning versus evening dosing of ibuprofen using conventional and time-controlled release formulations.

Many functions of the human body vary considerably during a day. These variations can lead to changes in drug plasma concentrations. In the study on healthy volunteers described here it was determined whether ibuprofen plasma levels following single oral doses of immediate-release and press-coated time-controlled release tablet formulations depend on time of drug administration (08:00 or 22:00 h). The difference between morning and evening dosing of the immediate-release formulation was minimal. The results with the press-coated formulation were unexpected having regard to results of previous studies on non-steroidal anti-inflammatory analgesics. Time to peak concentration was 6 h after morning administration, 4 h after evening administration. Both the rate and extent of bioavailability of ibuprofen were lower when dosing took place at 08:00 h than when dosing took place at 22:00 h. The influence of food on the pharmacokinetic profile of an evening dose of the press-coated formulation was also studied. When tablets were administered with a meal the ratio C(max)/AUC and t(max) and AUC values indicated that bioavailability was reduced. The main conclusion was that the chronopharmacokinetic behaviour of the press-coated ibuprofen tablet is related to the formulation, not the drug substance as such.