Development of 3D Printed Tablets by Fused Deposition Modeling Using Polyvinyl Alcohol as Polymeric Matrix for Rapid Drug Release.

In this study, the processability of polyvinyl alcohol (PVA), a water-soluble polymer, into melt-extruded filaments and then into 3D printed tablets by fused deposition modeling was studied. PVA is semicrystalline with Tg and m.p. of ~45°C and ~190°C, respectively. After screening several plasticizers, sorbitol was selected to enhance melt extrudability of PVA. Carvedilol and haloperidol, 2 basic compounds with pH-dependent solubility, were used as model drugs. Miscibility of the drugs with PVA, with and without added sorbitol as plasticizer, was also tested to determine whether any amorphous solid dispersion was formed that would facilitate rapid and pH-independent dissolution. Finally, the drug release from physical mixtures, crushed extrudates, and printed tablets were determined. Owing to high m.p. and high melt viscosity of PVA, filaments containing 10% and 20% drug required 180°C-190°C for extrusion, which could be reduced to ~150°C by adding 10% sorbitol. The printing temperature of 210°C was, however, required. Miscibility of carvedilol and haloperidol with PVA were, respectively, ~20% and <10%. PVA provided complete drug release from 3D printed tablets with 10% and 20% carvedilol and 60% infill in ~45 min at both pH 2 and 6.8. However, despite relatively rapid dissolution rate, high processing temperature and limited drug-polymer miscibility could be potential development issues with PVA.

Effects of Surfactants on Itraconazole-Hydroxypropyl Methylcellulose Acetate Succinate Solid Dispersion Prepared by Hot Melt Extrusion III: Tableting of Extrudates and Drug Release From Tablets.

Hydroxypropyl methylcellulose acetate succinate (HPMCAS) has gained popularity as a carrier for amorphous solid dispersion because of its ability to maintain drugs in supersaturated state after dissolution in aqueous media. In part I and II of this series of articles, we have demonstrated that amorphous solid dispersions containing HPMCAS may be prepared using surfactants as plasticizers to reduce processing temperature (Solanki et al., J Pharm Sci. 2019; 108:1453-65), where surfactants also increase dissolution rate and degree of supersaturation (Solanki et al., J Pharm Sci. 2019; 108: 3063-73). The present investigation was undertaken to develop melt extrudates of itraconazole-HPMCAS and itraconazole-surfactant-HPMCAS mixtures into tablets having tensile strength ≥2 MPa, where poloxamer 407 and d-α-tocopherol polyethylene glycol 1000 succinate were used as surfactants. Milled filaments were sieved to collect <212-µm particles, which were then compressed into tablets with different excipients (silicified microcrystalline cellulose [MCC], Avicel PH-102, dicalcium phosphate, lactose, and Starch 1500). Initial screening of various diluents showed that only silicified MCC and Avicel PH-102 could provide the target tensile strength of ≥2 MPa. Tabletability (tensile strength vs. compaction pressure), compressibility (porosity vs. compaction pressure), and compactibility (tensile strength vs. porosity) were then studied for tablet formulations. The desired tensile strength could be obtained at the diluent level of 50%-70%, where silicified MCC provided better hardness than Avicel PH-102. Tablets disintegrated in <2 min, and drug release from tablets was comparable to that of milled filaments.

Effects of Surfactants on Itraconazole-Hydroxypropyl Methylcellulose Acetate Succinate Solid Dispersion Prepared by Hot Melt Extrusion. II: Rheological Analysis and Extrudability Testing.

Although hydroxypropyl methylcellulose acetate succinate (HPMCAS) has been widely used as a carrier for amorphous solid dispersion of poorly water-soluble drugs, its application has mostly been limited to spray drying, and the solvent-free method of hot melt extrusion has rarely been used. This is on account of the high temperature (≥170°C) required for extrusion where the polymer and even a drug may degrade. In part 1 of this series of papers, we demonstrated that HPMCAS is miscible with surfactants such as, poloxamer 188, poloxamer 407 and d-alpha tocopheryl polyethylene glycol 1000 succinate, which may also serve as plasticizers (Solanki et al., J Pharm Sci. 2019; 108 (4):1453-1465). The present investigation was undertaken to determine plasticization effects of the surfactants and a model drug, itraconazole, in reducing melt extrusion temperatures of HPMCAS. The determination of complex viscosity as functions of temperature and also as functions of angular frequency at certain fixed temperatures showed that the surfactants and the drug greatly reduce viscosity of HPMCAS by their plasticization effects. Surfactants and drug also had synergistic effects in reducing viscosity. The torque analysis during melt extrusion demonstrated that these additives greatly enhanced extrudability of HPMCAS. Surfactant-drug-polymer mixtures were successfully extruded as stable amorphous solid dispersions at 130°C, which is much lower than the minimum extrusion temperature of 170°C for neat HPMCAS.

Effects of Surfactants on Itraconazole-HPMCAS Solid Dispersion Prepared by Hot-Melt Extrusion I: Miscibility and Drug Release.

Hydroxypropyl methylcellulose acetate succinate (HPMCAS) has been widely investigated as a carrier for amorphous solid dispersion (ASD) of poorly water-soluble drugs. However, its use has mostly been limited to ASDs prepared by spray drying using organic solvents, and the solvent-free method, hot-melt extrusion (HME), has only limited use because it requires high processing temperature where the polymer and drug may degrade. In this investigation, surfactants were used as plasticizers to reduce the processing temperature. Their effects on drug release were also determined. To determine suitability of using surfactants, the miscibility of HPMCAS with 3 surfactants (poloxamer 188, poloxamer 407, and d-alpha tocopheryl polyethylene glycol 1000 succinate) and a model drug, itraconazole (ITZ), was studied by film casting. HPMCAS was miscible with ITZ (>30%) and each surfactant (>20%), and in ternary HPMCAS-ITZ-surfactant (60:20:20) system. ASDs prepared by HME of HPMCAS-ITZ-surfactant mixtures (70:20:10 and 65:20:15) at 160°C were physically stable after exposure to 40°C and 75% relative humidity for 1 month. The presence of 15% w/w surfactant provided up to 50% drug release at pH 1 as compared to only 8% from ASDs with HPMCAS alone. On changing the pH of the dissolution medium from 1 to 6.8 in a step-dissolution process, complete drug release (90%-100%) and extremely high apparent supersaturation (∼75,000 times) of ITZ were observed when the solutions were filtered through 0.45 µm filters. The apparently supersaturated solutions consisted of colloidal particles of ∼300 nm size. The present study demonstrates that stable ASDs with improved processability and drug release may be prepared by HME.

Formulation of 3D Printed Tablet for Rapid Drug Release by Fused Deposition Modeling: Screening Polymers for Drug Release, Drug-Polymer Miscibility and Printability.

The primary aim of this study was to identify pharmaceutically acceptable amorphous polymers for producing 3D printed tablets of a model drug, haloperidol, for rapid release by fused deposition modeling. Filaments for 3D printing were prepared by hot melt extrusion at 150°C with 10% and 20% w/w of haloperidol using Kollidon® VA64, Kollicoat® IR, Affinsiol™15 cP, and HPMCAS either individually or as binary blends (Kollidon® VA64 + Affinisol™ 15 cP, 1:1; Kollidon® VA64 + HPMCAS, 1:1). Dissolution of crushed extrudates was studied at pH 2 and 6.8, and formulations demonstrating rapid dissolution rates were then analyzed for drug-polymer, polymer-polymer and drug-polymer-polymer miscibility by film casting. Polymer-polymer (1:1) and drug-polymer-polymer (1:5:5 and 2:5:5) mixtures were found to be miscible. Tablets with 100% and 60% infill were printed using MakerBot printer at 210°C, and dissolution tests of tablets were conducted at pH 2 and 6.8. Extruded filaments of Kollidon® VA64-Affinisol™ 15 cP mixtures were flexible and had optimum mechanical strength for 3D printing. Tablets containing 10% drug with 60% and 100% infill showed complete drug release at pH 2 in 45 and 120 min, respectively. Relatively high dissolution rates were also observed at pH 6.8. The 1:1-mixture of Kollidon® VA64 and Affinisol™15 cP was thus identified as a suitable polymer system for 3D printing and rapid drug release.

Rheological analysis of itraconazole-polymer mixtures to determine optimal melt extrusion temperature for development of amorphous solid dispersion.

The objective of this investigation was to develop a systematic method for the determination of optimal processing temperatures of drug-polymer mixtures for the development of amorphous solid dispersion (ASD) by melt extrusion. Since melt extrusion is performed at high temperature, it is essential that the processing temperature should be as low as possible to minimize degradation of drug and polymer, and yet the temperature should be high enough that the drug-polymer mixture attains certain viscosity that is extrudable and the drug dissolves in the molten polymer. By using itraconazole (ITZ) and polyvinyl caprolactam-polyvinyl acetate-polyethylene glycol graft co-polymer (Soluplus®, BASF) as, respectively, the model drug and the polymeric carrier, melt viscosities of drug-polymer mixtures with 5, 10, 20 and 30% ITZ were studied as functions of temperature and angular frequency. All these concentrations were below the miscibility limit as it was shown separately by film casting that ITZ was miscible with the polymer up to 40%. Since the angular frequency of a rheometer may not be high enough to simulate the shear rate within an extruder, torque analysis as a function of temperature during melt extrusion of selected drug-polymer mixtures was also conducted. The presence of dissolved ITZ had a plasticizing effect on the polymer used, and an intersection point around 150-155°C was observed, above which viscosities of drug-polymer mixtures were lower than that of polymer itself. Drug-polymer mixtures with 5 to 30% ITZ were extrudable at 150°C, and torque analysis showed that the mixture with 20% ITZ can be extruded even at 145°C. These temperatures were 17 to 22°C below the melting point of ITZ (167°C). ITZ dissolved due to the drug-polymer miscibility, the viscosity attained, and the shear rate generated. It was confirmed by PXRD and DSC that the extrudates were amorphous. Viscosity and miscibility of drug-polymer mixtures during melt extrusion were identified as critical factors in determining optimal processing temperature.

Investigation of Thermal and Viscoelastic Properties of Polymers Relevant to Hot Melt Extrusion, IV: Affinisol™ HPMC HME Polymers.

Most cellulosic polymers cannot be used as carriers for preparing solid dispersion of drugs by hot melt extrusion (HME) due to their high melt viscosity and thermal degradation at high processing temperatures. Three HME-grade hydroxypropyl methylcelluloses, namely Affinisol™ HPMC HME 15 cP, Affinisol™ HPMC HME 100 cP, and Affinisol™ HPMC HME 4 M, have recently been introduced by The Dow Chemical Co. to enable the preparation of solid dispersion at lower and more acceptable processing temperatures. In the present investigation, physicochemical properties of the new polymers relevant to HME were determined and compared with that of Kollidon(®) VA 64. Powder X-ray diffraction (PXRD), modulated differential scanning calorimetry (mDSC), thermogravimetric analysis (TGA), moisture sorption, rheology, and torque analysis by melt extrusion were applied. PXRD and mDSC showed that the Affinisol™ polymers were amorphous in nature. According to TGA, the onset of degradation for all polymers was >220°C. The Affinisol™ polymers exhibited less hygroscopicity than Kollidon(®) VA 64 and another HPMC polymer, Methocel™ K100LV. The complex viscosity profiles of the Affinisol™ polymers as a function of temperature were similar. The viscosity of the Affinisol™ polymers was highly sensitive to the shear rate applied, and unlike Kollidon(®) VA 64, the viscosity decreased drastically when the angular frequency was increased. Because of the very high shear rate encountered during melt extrusion, Affinisol™ polymers showed capability of being extruded at larger windows of processing temperatures as compared to that of Kollidon(®) VA 64.

Steric Control of the Electronic Ground State in Six-Coordinate Copper(II) Complexes.

Replacing the 3- and 3''-protons of the ligand 2,6-di(pyrazol-1-yl)pyridine L by mesityl groups changes the electronic ground state of [Cu(L)2 ]2+ complexes from {d x 2-y 2}1 to {d z 2}1 . This is the best example so far for a "homoleptic" Jahn-Teller-compressed six-coordinate CuII complex.