Development of mechanistic models to identify critical formulation and process variables of pastes for 3D printing of modified release tablets.

The future of pharmaceutical manufacturing may be significantly transformed by 3-dimensional (3D) printing. As an emerging technology, the indicators of quality for materials and processes used in 3D printing have not been fully established. The objective of this study was to identify the critical material attributes of semisolid paste formulations filled into cartridges for 3D printing of personalized medicine. Nineteen semisolid formulations were prepared per a fractional factorial design with three replicates of the center point. The variables investigated included percent loading of API and various soluble and insoluble excipients. Pastes were characterized for viscoelastic characteristics during the 3D printing process including creep recovery, cross-modulus and extrudability models. Packing efficiency of pastes into 3D printing cartridges was also evaluated by X-ray tomography. Changes in composition of 3D printing pastes resulted in significant variations in their viscoelastic parameters, namely their elastic deformation, flow and relaxation behaviors. The percent of soluble excipients incorporated was the most significant factor affecting the creep behavior of pastes. Cross-over stresses were assessed to indicate the minimum pressure needed for the pastes to initiate flow. Increasing solid and swellable contents of the pastes from 7% to 63% w/w increased significantly (p < 0.05) the cross-over stress from 0.93 × 10-3 Pa to 9.47 × 10-3 Pa. Increasing soluble ingredients of paste from 30% to 80% w/w was found to increase flow of the paste from 0.41 × 10-3 to 3.85 × 10-3 %/s. X-ray tomography images revealed inclusion of air bubbles during packing of pastes into cartridges. These bubbles may affect the relaxation behavior of the pastes; hence bubbles should be eliminated. This study unveiled the critical material attributes that could be controlled for consistent 3D printing by microextrusion.

Leachable diphenylguanidine from rubber closures used in pre-filled syringes: A case study to understand solid and solution interactions with oxytocin.

Leachables derived from multi-component drug-device syringe systems can result in changes to the quality of drug products. Diphenylguanidine (DPG), a leachable released from styrene butadiene rubber syringe plungers, interacts with Oxytocin to form protein-adducts. This study investigated the mechanism and kinetics of this interaction in both solid and solution states through in-vitro tests and spectroscopic methods For solid state interaction, the protein-adducts with DPG were characterized using SEM, XRD, DSC, FTIR, 13C ss NMR, and dissolution analysis. For solution state interaction, LC-HRMS was used to assess stability of Oxytocin solutions in presence of various concentrations of DPG at 25°C and 40°C for 4 weeks. Moreover, molecular docking analysis was used to identify possible molecular configurations of the interaction.Results were consistent with the formation of a new solid state with distorted surface morphology for oxytocin-DPG adducts, in which the oxytocin carbonyl group(s) and the secondary amine groups of DPG interact. This interaction was also confirmed by molecular docking analysis through hydrogen bonding (2.31Å) and Van der Waal attraction (3.14Å). Moreover, LC-HRMS analysis revealed an increase in Oxytocin stability and suppression of Oxytocin dimerization by DPG. A potential reduction in the rate of Oxytocin dissolution from the formed adducts was indicative of its strong association with DPG. Hence, the leaching potential of DPG from rubber closures and plungers should be monitored and controlled to maintain the quality and stability of the pharmaceutical product.