Although the distal small intestine has less lumenal and apical proteolytic activities, it has high activities of some apical peptidases. Colonic proteolytic activities are substantial, but their nature is less understood. The small intestine has di- and tripeptide transporter, facilitating absorption, and P-glycoprotein, an efflux pump suggested to limit absorption of small peptides. Several peptide and nonpeptide drugs have higher absorption in the ileum; however, enhancement on their absorption by enhancers varies from site to site. Specific delivery systems can target drugs to the distal intestine utilizing distinct regional pHs and specific microbial enzymes, but the key is how to achieve a reliable release.
In solid dosage manufacturing, roller compaction technology plays an important role in providing cost control and a quality product. The objective of this study was to evaluate the effectiveness of fine-particle hydroxypropylcellulose (HPC) as a dry binder in roller compaction processing. The formula included acetaminophen (APAP), microcrystalline cellulose, fine-particle HPC, croscarmellose sodium, and magnesium stearate. The fine-particle HPC was incorporated into the formula at 4%, 6%, and 8% w/w levels. Three compaction pressures (30, 40, and 50 bars) were used for each formulation. The roller compaction equipment used in this study had a processing capacity of 40 to 80 kg/hr. A tablet compression profile was generated on a rotary tablet press, and compression forces used were 5, 10, 15, 20, and 25 kN. The significant criteria for tablet evaluation were capping, hardness, friability, ejection force, and drug dissolution. As the binder concentration of HPC increased, tablet capping decreased, and tablet friability improved. As the concentration of HPC increased, only slight differences were noted in tablet hardness. All the formulations pass the USP requirement of 80% APAP dissolved within 30 min. Using 8% HPC could eliminate the formula capping problem. The friability results were less than 1% at all compression forces. The minimum tablet ejection forces were found in the formulations prepared under 40 bars compaction pressure. The utility of fine-particle HPC as a roller compaction binder was established. The applicable binder concentrations and roller compaction pressures were found. Using HPC at these binder levels and operating parameters could overcome capping and friability problems and achieve the optimal tablet dosage forms.
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