Zhaopeng Hu

Evaluation of intestinal pressure-controlled colon delivery capsule containing caffeine as a model drug in human volunteers.

The delivery ability of a pressure-controlled colon delivery capsule (PCDC) containing caffeine as a test drug was evaluated after oral administration to healthy male human volunteers. The driving force causing PCDC disintegration in the intestinal tract is the physiological luminal pressure which results from peristalsis. Three kinds of PCDCs having different thickness of a water-insoluble polymer membrane was prepared by coating the inner surface of the gelatin capsules with ethylcellulose (EC). The mean thickness were 40 +/- 1 (SE) for type 1, 44 +/- 1 for type 2 and 50 +/- 1 micron for type 3 PCDC, respectively. Caffeine was dissolved with a suppository base (PEGs 400 and 1000) and the capsules were filled. Doses were 15, 45 or 75 mg. After blank saliva samples were obtained, test preparations were orally administered to the volunteers and saliva samples were collected for 1 min intervals hourly from 1 to 10 h in the fasted state study, and from 1 to 20 h and at 25 h in the fed state study. Caffeine concentrations in the saliva samples were analyzed by HPLC. The maximum salivary caffeine excretion rate increased as the oral caffeine dose increased. The maximum salivary caffeine excretion rate increased predominantly compared to the pre-dose level in 75 mg dose study. Therefore, all following studies were performed with this dose. The first appearance time of caffeine into the saliva, TI, was used as a parameter to estimate the disintegration time of test preparations in the gastrointestinal tract. The mean TI of types 1, 2, and 3 PCDCs were 3.0 +/- 0.4, 4.0 +/- 0.4 and 4.5 +/- 0.3 h, respectively. After oral administration of 75 mg caffeine in pain gelatin capsule as a reference preparation, caffeine appeared in the saliva within 0.5 h. The mean hardness of the PCDCs were 1.05 +/- 0.10 (type 1), 1.55 +/- 0.06 (type 2) and 2.08 +/- 0.15 newton (type 3), respectively. There were good correlations between three parameters: EC coating membrane thickness, hardness and TI (determination coefficient r2 = 0.935 between TI and thickness, r2 = 0.998 between thickness and hardness, r2 = 0.958 between hardness and TI). The effect of food intake on the delivery ability was examined with type 3 PCDCs. Food intake prolonged the mean TI, from 4.5 +/- 0.3 to 7.8 +/- 1.3 h. This increase is thought to be ascribed to prolonged gastric emptying time. Comparison with reported colon arrival times indicates that the type 3 PCDC functions in colon delivery of caffeine and is thought to be applicable to other drugs.

A novel emulsifier, labrasol, enhances gastrointestinal absorption of gentamicin.

Gentamicin (GM) is an important aminoglycoside antibiotic for the treatment of infections caused by a wide spectrum of aerobic gram-negative bacilli and gram-positive cocci. As a class, the aminoglycosides are poorly absorbed from the gastrointestinal (GI) tract and are commonly used as injectable and topical preparations. This study was aimed at finding the effect of a novel emulsifier, Labrasol, on the absorption of GM from the GI tract of rats. GM formulations were prepared, either as saline solution or as Labrasol microemulsions, and were administrated to rat small intestine and colon. Plasma GM levels following intestinal application were compared to those obtained with intravenous (i.v.) administration. A 5 mg/kg dose of GM preparation containing Labrasol, 1 ml/kg, administrated into colon resulted in the mean AUC of 21.179+/-1.374 microg x h/ml, compared to 7.813+/-0.105 microg x h /ml obtained with i.v. administration of GM, 1 mg/kg. The absolute bioavailability (BA) of the Labrasol preparation was 54.2%. Labrasol facilitates the transmucosal delivery of GM from rat colon by forming microemulsions, and the BA obtained with Labrasol microemulsion was higher than with other surfactants (8.4% for Tween 80 and 3.4% for Transcutol P). Additionally, in vitro permeation studies demonstrated that Labrasol also inhibited the intestinal secretory transport. The effect of Labrasol is ascribed to both (1) enhanced GM absorption from the GI lumen into the systemic circulation and (2) inhibition of efflux of GM from the enterocytes to the GI lumen.

Application of pressure-controlled colon delivery capsule to oral administration of glycyrrhizin in dogs.

A colon delivery system has been used to improve the bioavailability of glycyrrhizin, a glycoside of glycyrrhetic acid. The bioavailability of glycyrrhizin is low when administered in conventional oral galenic dosage forms because glycyrrhizin is enzymatically hydrolysed both in the stomach and in the intestine. It was reasoned that if large amounts of glycyrrhizin were directly delivered to the colon, enzymatic activity should be reduced due to saturation so that intact glycyrrhizin could be absorbed into the systemic circulation. Based on this assumption, pressure‐controlled colon delivery capsules (PCDCs) were used as a colon delivery system. Eight types of glycyrrhizin solution were prepared and were introduced into PCDCs. After oral administration of the test PCDCs to beagle dogs, blood samples were obtained over 24 h and plasma glycyrrhizin concentrations were measured by an HPLC method. With PCDCs containing aqueous glycyrrhizin and propylene glycol solutions, plasma glycyrrhizin levels were extremely low and the bioavailabilities of glycyrrhizin were 0.6% and 0.4%, respectively. When Labrasol was added to both types of glycyrrhizin solution, the bioavailability was improved to 4.6 % for aqueous solution and 3.8% for propylene glycol solution. When a surfactant, Polysorbate 80, was added in combination with Labrasol, synergistic effects were not obtained. Furthermore, dose‐dependent effects of Polysorbate 80 were not obtained. Labrasol, which is a component of self‐emulsifying drug delivery systems (SEDDS), has been shown to strongly improve the bioavailability of glycyrrhizin from the colon.

Evaluation of an intestinal pressure-controlled colon delivery capsules prepared by a dipping method

A new method for preparation of large amounts of empty pressure-controlled colon delivery capsules (PCDCs) by a dipping method has been developed. Empty PCDCs are composed of two polymer membranes. The inner one was a water-insoluble polymer membrane, ethylcellulose (EC). The outer one was an enteric polymer membrane, hydroxypropylmethylcellulose phthalate (HPMCP) or hydroxypropylmethylcellulose acetate succinate (HPMCAS). By consequently dipping into an ethanolic EC solution and an alkalized enteric polymer solution, empty PCDCs were obtained after both the capsule body and cap were adjusted to the size of #2 capsules. With each enteric polymer, two types of empty PCDCs of different thickness were prepared. Fluorescein (FL) was formulated with suppository base, PEG1000, and used as a model drug. FL/PEG1000 suspension was introduced into empty PCDCs which were then sealed with enteric polymer solution. The PCDCs were evaluated by an in vivo experiment using beagle dogs. After oral administration of the test PCDC preparations containing 30 mg of FL, blood samples were obtained from the jugular vein and serum FL levels were measured. The thickness of the EC membrane layer varied in both the capsule body and cap. HPMCAS PCDCs had 62.1+/-5.0 (S.E.) microm (body) and 49.7+/-3.3 microm (cap) with thicker ones and 55.7+/-6.6 microm (body) and 46.8+/-6.2 microm (cap) with thinner ones. HPMCP PCDCs had 28.1+/-3.3 microm (body), 30.9+/-1.0 microm (cap) with thinner ones and 43.1+/-9.8 microm (body), 42.4+/-8.2 microm (cap) with thicker ones. The mean T(i) values, the first appearance time, of FL in the serum of HPMCAS PCDCs were 2.0+/-0.7 h for thicker ones and 3.8+/-0.5 h for thinner ones, while the mean T(i) values of HPMCP PCDCs were 2.0+/-0.0 h for thinner ones and 3.5+/-0.7 h for thicker ones. Since the colon arrival time in beagle dogs was 3.5+/-0.3 h as determined by a sulfasalazine test, thinner HPMCAS PCDCs and thicker HPMCP PCDCs were thought to deliver FL to the colon.

New preparation method of intestinal pressure-controlled colon delivery capsules by coating machine and evaluation in beagle dogs

A new method for preparing large amounts of pressure-controlled colon delivery capsules (PCDCs) which employs a pharmaceutical coating machine, Hicoater-mini, has been developed. In contrast to our original method for preparing PCDCs where the inner surfaces of gelatin capsule were coated with the water-insoluble polymer ethylcellulose (EC), PCDC were directly prepared by coating the capsular shaped suppositories with EC. As a model drug, fluorescein (FL) was used in this study. FL powder was suspended with the suppository base, polyethylene glycol (PEG) 1000, at 50 degreesC, and was hardened in the capsular shape the sizes of which were #0 and #2. The capsular shaped suppositories were coated with 5% w/v ethanolic EC (7G grade) solution by a coating machine. By increasing the coating time from 55 to 75 min, the mean coating thickness of #0 PCDCs increased from 141+/-7 to 211+/-4 micrometer. In the case of #2 PDDCs, the mean coating thickness increased from 102+/-3 to 110+/-5 micrometer by increasing the coating time from 35 min to 40 min. Several kinds of #0 PCDCs having the mean EC coating membrane thickness of 141+/-7 micrometer (type 1), 166+/-4 micrometer (type 2), 188+/-4 micrometer (type 3), 211+/-4 micrometer (type 4) as well as #2 PCDCs having thickness of 102+/-3 micrometer (type 5) and 110+/-5 micrometer (type 6) were used for in vivo evaluation using beagle dogs. After oral administration of the test preparations containing 30 mg of FL, blood samples were obtained from the jugular vein and plasma FL levels were measured. The first appearance time, Ti, of FL in the plasma was used as a parameter for the estimation of the release time of FL from PCDCs in the gastrointestinal tract. The mean Ti of #0 PCDCs were 2.3+/-0.5 for type 1, 3.3+/-0.5 for type 2, 4.8+/-1.0 for type 3 and 7.8+/-1.7 h for type 4 preparations while the mean Ti of #2 PCDCs were 3.2+/-0.4 for type 5 and 3.8+/-0.4 h for type 6, respectively. There were good correlations between EC coatings.

Technology to Obtain Sustained Release Characteristics of Drugs after Delivered to the Colon

AbstractTo determine the necessary technology by which sustained drug release is obtained after drug is delivered to the colon, two kinds of microcapsules were prepared and were filled in a pressure-controlled colon delivery capsule (PCDC). As a model drug 5-aminosalicylic acid (5-ASA) was used, because the target site of 5-ASA is the entire large intestine. 5-ASA was microencapsulated using a water-insoluble polymer, ethylcellulose (EC) or with pH-sensitive polymers, Eudragit™ L-100 or S-100 and encased in PCDC. The particle size of these microcapsules was around 800 μm and the loading efficiencies of 5-ASA were approximately 90%. In vitro dissolution tests were performed with the prepared microcapsules. The release rate of 5-ASA from the microcapsules was significantly prolonged as compared to 5-ASA powder, although there were no significant differences in the release rates between these microcapsules. By incorporating the 5-ASA microcapsules into PCDC, sustained release PCDCs for colon delivery were pr...

Colon delivery efficiencies of intestinal pressure-controlled colon delivery capsules prepared by a coating machine in human subjects.

Large quantities of pressure‐controlled colon delivery capsules (PCDCs) were prepared by a Hicoater‐mini pharmaceutical coating machine and colon delivery efficiencies were evaluated in man. Caffeine powder as a model drug was suspended with a polyethylene glycol (PEG) 1000 suppository base at 50°C, and was hardened in no. 0‐ and no. 2‐sized capsular shapes. The capsule‐shaped suppositories were coated with 5% w/v ethanolic ethylcellulose (7G grade) solution using the coating machine.

Application of a Biomagnetic Measurement System (BMS) to the Evaluation of Gastrointestinal Transit of Intestinal Pressure-Controlled Colon Delivery Capsules (PCDCs) in Human Subjects

AbstractPurpose. For determination of the transit time through various partsof the gastrointestinal (GI) tract, we developed a method that providesthe location of disintegration and drug release. This method involves GImagnetomarkergraphy (GIMG) using a 129-channel Shimadzu vectorbiomagnetic measurement system (BMS). Methods. To magnetically label the pressure-controlled colon deliverycapsule (PCDC) containing 75.0 ± 0.5 mg of caffeine as a tracer drug,small capsule caps containing 90 mg of ferric oxide powdered magnetite(Fe2O3) were attached to PCDCs. After orally administration to fastedhuman volunteers, saliva samples were collected hourly and salivarycaffeine concentration was measured. At the same time, locations ofthe magnetic PCDC were detected by BMS just after the PCDCs weremagnetized with the coils of a magnetic resonance imaging (MRI)system. The magnetic field distributions were analyzed and theestimated positions were shown on the MRI picture of the same subjectsabdominal structure. Results. We magnetized PCDC with permanent magnets or anelectromagnet before ingestion and the estimated locations of PCDC in the GItract exhibited high estimation error. In order to increase the precision ofestimated localization of PCDCs, PCDCs were magnetized within thecoils of the MRI. As a result, these PCDCs had strong magnetic dipolesthat were parallel to the sensor unit of BMS in every measurement,and therefore the spatial resolution of the PCDCs two-dimensionalpositions in the organs of the GI tract was within a range of severalmillimeters. Conclusions. GIMG is a powerful tool for the study of colon deliveryefficiencies of PCDCs. The main advantage of GIMG is the capabilityto obtain even more detailed knowledge of the behavior and fate ofsolid pharmaceutical formulations during GI passage.

Characterization of norfloxacine release from tablet coated with a new pH-sensitive polymer, P-4135F.

A new pH-sensitive polymer, P-4135F, was evaluated as a colon delivery device for norfloxacine (NFLX) which is used for the therapy of patients with Vero toxin-producing Escherichia coli gastroenteritis. P-4135F has a dissolution threshold pH of 7.2 which is higher than the conventional pH-sensitive polymers, Eudragit S100 and L100. To compare the dissolution site of P-4135F coated tablets with other enteric polymer coatings, mini-tablets containing sodium fluorescein (FL) as a model drug were prepared by coating them with the three polymers. After oral administration of FL mini-tablets to rats, the first-appearance time, Ti, of FL into the systemic circulation was measured. The Tis were 0.7+/-0.2 h for Eudragit L100, 1.8+/-0.4 h for S100 and 2.0+/-0.3 h for P-4135F. Direct inspection of the dissolution process of the FL mini-tablets after oral administration to rats was performed by abdominal incision studies. All of the coated FL mini-tablets started to dissolve in the rat ileum. The dissolution sites were identified to be proximal to the ileocecal junction for P-4135F, at the middle part of the ileum for Eudragit S100 and at the proximal part of the ileum for Eudragit L100. NFLX tablets with different membrane thicknesses of P-4135F were prepared and were orally administered to beagle dogs. The colon delivery efficiency was evaluated by measuring the Ti of NFLX into the systemic circulation. The mean Tis were 1.33+/-0.33 h for 56.8+/-0.5 microm membranes, 3.75+/-0.25 h for 64.6+/-0.7 microm membranes, 4.00+/-1.00 h for 70.5+/-0.5 microm membranes and 3.00+/-1.00 h for 74.9+/-0.4 microm membranes. By comparing the Ti, 4.33+/-0.33 h, obtained after oral administration of NFLX in a pressure-controlled colon delivery capsule, and the colon arrival time, 3.5+/-0.3 h, determined by a sulfasalazine test in beagle dogs. P-4135F coated NFLX tablets appeared to dissolve and disintegrate before reaching the colon. Studies using rats and beagle dogs have suggested that P-4135F dissolves in the lower part of the small intestine, i.e., the ileum. These studies also suggest that this new polymer will be useful for the delivery of NFLX to the lower part of the small intestine.

Diethyl ether fraction of Labrasol having a stronger absorption enhancing effect on gentamicin than Labrasol itself

In our previous study, we had reported that Labrasol has a good gastrointestinal (GI) absorption enhancing effect on poorly absorbable drugs. In order to improve further absorption enhancing effect of Labrasol on gentamicin (GM), which is a representative water-soluble, poorly absorbable drug, Labrasol was fractionated with hexane, diethyl ether, ethyl acetate and water. The absorption enhancing effect of each fraction of Labrasol and Labrasol alone were evaluated in vivo using rats. Each test formulation of GM was administered into the rat colon at a dose of 5.0 mg/kg and plasma GM concentrations were measured by a HPLC method. Among the four fractions of Labrasol and Labrasol, diethyl ether fraction showed the strongest absorption enhancing effect on GM. When the doses of diethyl ether fraction were 1.0, 0.5 and 0.1 ml/kg, the Cmax values were 8.95 +/- 1.46, 8.02 +/- 2.14 and 7.41 +/- 1.25 microg/ml, respectively. Moreover, AUC(0-6) values were also maintained at high level, i.e. 27.28 +/- 5.90, 20.32 +/- 3.79 and 19.61 +/- 2.09 microg h/ml. Based on the AUC(0-6) values obtained with each fraction, the rank order of absorption enhancing effect on GM was diethyl ether > ethyl acetate=hexane > aqueous fraction.