Effect of Food Intake on the Pharmacokinetics of a Novel Methylphenidate Extended-Release Oral Suspension for Attention Deficit Hyperactivity Disorder.

We conducted an open-label, single-dose, randomized, crossover study in healthy adults to assess the impact of food on the bioavailability of 60 mg methylphenidate extended-release oral suspension (MEROS; Quillivant XR™)-a long-acting stimulant for the treatment of attention deficit hyperactivity disorder-by comparing the pharmacokinetic parameters under fed and fasting conditions. When MEROS 60 mg was administered under fed conditions compared with fasting conditions, the exposure of methylphenidate (d enantiomer) was higher, with a mean area under the plasma concentration-vs-time curve (AUC)0-t of 160.2 ng·h/mL vs 140.4 ng·h/mL, and a mean AUC0-inf of 163.2 ng·h/mL vs 143.7 ng·h/mL, respectively. The ratios of the ln-transformed geometric means for methylphenidate for AUC0-t and AUC0-inf were 119.5% (90%CI, 115.7% to 123.5%) and 119.0% (90%CI, 115.2% to 122.8%), respectively, within the standard 80% to 125% bioequivalence acceptance range indicating no food effect on the overall exposure (rate and extent). There was a small increase in the peak plasma concentration (127.6% [90%CI, 119.9% to 135.8%]). However, this effect was small and not likely to be clinically significant. Overall, MEROS 60 mg was safe in both the fed and fasting condition when administered to healthy volunteers in this study.

Pharmaceutical technology management--profitable business avenue.

Growing research expenditure, regulatory framework and generic erosion have forced pharmaceutical companies globally to resort to pharmaceutical technology management (PTM). Indeed, the pharmaceutical industry has witnessed the impact of innovative drug delivery and device technologies and their influence on business. PTM has given a new business insight with greater profits and enhancement of product franchise. Promising breakthrough technologies have not been able to reach a commercial platform largely owing to lack of capital at the preliminary stages of the product development program. Intellectual property plays a considerable role in protecting innovative technologies. Joint ventures and strategic alliances also become important for commercializing a new technology. The synergy of PTM with options of in-licensing is expected to infuse newer opportunities to the pharmaceutical business.

Fabrication, characterization and in vivo studies of biodegradable gamma sterilized injectable microparticles for contraception.

A Levonorgestrel-loaded microparticulate system was developed with gelatin and bovine serum albumin using triple emulsion technique coupled with chemical cross-linking thermal rigidization method. The formulation was optimized for various formulation variables and process parameters. The microparticulate system was characterized by scanning electron microscopy, encapsulation efficiency, moisture content, IR, DSC, XRD, residual solvent content and evaluated for sterility, abnormal toxicity and absence of pyrogens. Microparticles were sterilized by gamma irradiation at 2.5 Mrad. The system was injected intramuscularly in rabbits and drug blood levels estimated using radioimmunoassay technique. An optimized drug to polymer ratio of 0.4:0.75 w/w gave drug encapsulation efficiency of about 40%. The in vitro drug release followed Higuchi square root kinetics. In in vivo studies the AUC0-t was found to be 12849.25 pg/mL.day(-1) with mean residence time calculated to be about 16 days and Kel of 0.02 day(-1). Levonorgestrel (LNG) levels were maintained between 200 and 400 pg/mL. The pharmacokinetic results indicate that LNG is released from the injectable microparticles for a period of one-month duration.

Possibility of a patch system as a new oral delivery system.

A new oral patch system has been designed to increase the residence time of model drugs within the gastrointestinal tract. The system consisted of three layers (1) water-insoluble backing layer (2) drug-carrying adhesive layer composed of a model drug, fluorescein (FL) or fluorescein isothiocyanate-dextran (FD), and gel-forming polymer and (3) pH-sensitive enteric polymer. These three layers system was prepared as 3.0 mm diameter patches. As references, tablet containing FL or FD was prepared. In vitro dissolution studies showed that the mean dissolution time (MDT) of model drugs from patch preparation was 0.739+/-0.021 h for FL and 0.407+/-0.021 h for FD, which were longer than from tablet, 0.327+/-0.008 h for FL and 0.270+/-0.019 h for FD. The two test preparations were orally administered to beagle dogs in a crossover manner at a FL dose of 30 mg/dog and the measured plasma FL concentrations were used for pharmacokinetic analysis. With FL patch preparation, area under the plasma drug concentration vs. time curve (AUC) was 2.12+/-0.24 microgh/ml and mean residence time (MRT) was 4.60+/-0.18 h, which were greater than those of tablet, AUC was 1.52+/-0.16 microgh/ml and MRT was 3.18+/-0.09 h, respectively. Oral patch preparation also increased both AUC and MRT of FD, a model macromolecular drug, which was formulated into both patches and tablets and administered to dogs (30 mg/dog). The AUC and MRT of FD from the patch preparation were 1.11+/-0.13 microgh/ml and 5.58+/-0.55 h and from tablets were 0.53+/-0.08 microg h/ml and 4.09+/-0.29 h, respectively. These results suggest that oral patch preparation has as a potential a new oral delivery system to obtain a long residence time of drug in the gastrointestinal tract.

Evaluation of gastrointestinal transit characteristics of oral patch preparation using caffeine as a model drug in human volunteers.

Salivary caffeine excretion rate test has been proposed for the evaluation of gastrointestinal transit characteristics of an oral patch preparation after administration to human volunteers instead of measuring the plasma or serum concentration in the early stages of formulation development. Patches having a diameter of 3.0 mm and containing caffeine as a model drug were prepared. The patches consisted of 1) the backing layer made of a water-insoluble polymer, 2) the drug-carrying layer composed of caffeine and a gel-forming polymer, and 3) the enteric polymer membrane. These three layer patches were filled into enteric capsules. Caffeine solution in an enteric capsule was used as the control preparation. After oral administration of each preparation to human volunteers at a dose of 50 mg of caffeine in a cross-over study with a wash-out period of two weeks, saliva samples were collected over 1 min at every sampling time for 12 h and salivary caffeine concentration was determined by a HPLC assay method. Salivary caffeine excretion rate (ER) was used for pharmacokinetic analysis. Mean residence time (MRT) and first-appearance time of caffeine into the saliva (T(i)) were determined. To characterize the pharmacokinetics of caffeine, MRT-T(i) values of patch and solution preparations were compared. Patch preparations had a T(i) value of 2.33+/-0.33 h and showed significantly longer MRT-T(i), 3.87+/-0.21 h, as compared to the control preparation (MRT-T(i)=1.04+/-0.38 h) under fasting condition (p<0.05). Food intake prolonged the gastric emptying time (GET) of the preparations with T(i) values of 5.00+/-1.15 h for control preparation and 4.67+/-1.20 h for patch preparation. The MRT-T(i) values were 0.62+/-0.20 h (control) and 2.45+/-0.73 h (patch). The results of this study indicate that the parameter, MRT-T(i), was useful in characterizing the transit characteristics of oral patch preparations than MRT itself and the presence of food affects the performance of the patch system.