The development and optimisation of gastro-retentive floating tablets using fused deposition modelling 3D printing.

OBJECTIVES: To develop a robust tablet design for the manufacture of gastro-retentive tablets using fused deposition modelling three-dimensional printing (FDM-3DP) that can provide prolonged gastric residence time with instant floating and minimum influence of process and/or formulation variables. METHODS: Three different polymers, such as polyvinyl alcohol (PVA), hydroxypropyl cellulose (HPC) and Soluplus were used, separately, for the manufacture of tablets using FDM-3DP. Tablets were designed in a sandwich model that included voids in the internal structure to support buoyancy. KEY FINDINGS: Fabricated tablets from all polymers were instantly buoyant with no floating lag time. Floating duration was in the order: HPC > Soluplus > PVA which can be explained by the density of the tablets. PVA tablets exhibited significantly (P < 0.05) higher density values (0.86 ± 0.02 mg/mm3) than HPC and Soluplus (0.69 ± 0.03 and 0.72 ± 0.02 mg/mm3, respectively). HPC and Soluplus showed similar zero-order drug release profiles (f2 > 50) and were able to sustain the release of theophylline for 12 h, whereas complete drug release was achieved from PVA tablets after 3 h. CONCLUSIONS: Robust gastro-retentive tablets that show instant buoyancy regardless of the polymeric carrier type and composition were successfully manufactured utilising FDM-3DP. This allows for overcoming the restrictions posed by process/formulation parameters on the floatability of gastro-retentive tablets.

3D printing of pharmaceutical oral solid dosage forms by fused deposition: The enhancement of printability using plasticised HPMCAS.

3D printing (3DP) by fused deposition modelling (FDM) is one of the most extensively developed methods in additive manufacturing. Optimizing printability by improving feedability, nozzle extrusion, and layer deposition is crucial for manufacturing solid oral dosage forms with desirable properties. This work aimed to use HPMCAS (AffinisolTM HPMCAS 716) to prepare filaments for FDM-3DP using hot-melt extrusion (HME). It explored and demonstrated the effect of HME-filament composition and fabrication on printability by evaluating thermal, mechanical, and thermo-rheological properties. It also showed that the HME-Polymer filament composition used in FDM-3DP manufacture of oral solid dosage forms provides a tailored drug release profile. HME (HAAKE MiniLab) and FDM-3DP (MakerBot) were used to prepare HME-filaments and printed objects, respectively. Two diverse ways of improving the mechanical properties of HME-filaments were deduced by changing the formulation to enable feeding through the roller gears of the printer nozzle. These include plasticizing the polymer and adding an insoluble structuring agent (talc) into the formulation. Experimental feedability was predicted using texture analysis results was a function of PEG concentration, and glass-transition temperature (Tg) values of HME-filaments. The effect of high HME screw speed (100 rpm) resulted in inhomogeneity of HME-filament, which resulted in inconsistency of the printer nozzle extrudate and printed layers. The variability of the glass-transition temperature (Tg) of the HME-filament supported by scanning electron microscopy (SEM) images of nozzle extrudates and the lateral wall of the printed tablet helped explain this result. The melt viscosity of HPMCAS formulations was investigated using a capillary rheometer. The high viscosity of unplasticized HPMCAS was concluded to be an additional restriction for nozzle extrusion. The plasticization of HPMCAS and the addition of talc into the formulation were shown to improve thickness consistency of printed layers (using homogeneous HME-filaments). A good correlation (R2 = 0.9546) between the solidification threshold (low-frequency oscillation test determined by parallel-plate rheometer) and Tg of HME-filaments was also established. Drug-loaded and placebo HPMCAS-based formulations were shown to be successfully printed, with the former providing tailored drug release profiles based on variation of internal geometry (infill).