A floating 3D printed polypill formulation for the coadministration and sustained release of antihypertensive drugs.

Polypharmacy is a common issue, especially among elderly patients resulting in administration errors and patient inconvenience. Hypertension is a prevalent health condition that frequently leads to polypharmacy, as its treatment typically requires the co-administration of more than one different Active Pharmaceutical Ingredients (API's). To address these issues, floating hollow torus-shaped dosage forms were developed, aiming at providing prolonged gastric retention and sustained drug release. The dosage forms (polypills) containing three anti-hypertensive API's (diltiazem (DIL), propranolol (PRP) and hydrochlorothiazide (HCTZ)) were created via Fused Deposition Modelling 3D printing. A multitude of the dosage forms were loaded into a capsule and the resulting formulation achieved prolonged retention times over a 12-hour period in vitro, by leveraging both the buoyancy of the dosage forms, and the "cheerios effect" that facilitates the aggregation and retention of the dosage forms via a combination of surface tension and shape of the objects. Physicochemical characterization methods and imaging techniques were employed to investigate the properties and the internal and external structure of the dosage forms. Furthermore, an ex vivo porcine stomach model revealed substantial aggregation, adhesion and retention of the 3D printed dosage forms in porcine stomach. In vitro dissolution testing demonstrated almost complete first-order release of PRP and DIL (93.52 % and 99.9 %, respectively) and partial release of HCTZ (65.22 %) in the 12 h timeframe. Finally, a convolution-based single-stage approach was employed in order to predict the pharmacokinetic (PK) parameters of the API's of the formulation and the resemblance of their PK behavior with previously reported data.

Cereal-Based 3D Printed Dosage Forms for Drug Administration During Breakfast in Pediatric Patients within a Hospital Setting.

In an effort to combine a child-friendly dosage form for medication administration in hospitalized pediatric patients and a user-friendly automated process for its preparation by health-care providers, the current study proposes a method for drug administration with breakfast using semi-solid extrusion 3D printing. Cereal was used as the platform carrier of the hydrophobic ibuprofen and the hydrophilic paracetamol to develop the drug loaded cereal ink. Rheological analysis was performed to identify the cereal ink with optimum viscosity for extrusion printing. Drug distribution and crystallinity within the printed cereal were assessed with confocal Raman microscopy and thermal and X-ray diffraction analysis, respectively, indicating molecular dispersion of both drugs within the cereal. High cereal porosity was associated with a higher milk absorption capacity and a decrease in their flexural force upon immersion in milk. Dissolution studies were performed in biorelevant media under fasted and fed state conditions and in the presence of full-fat and low-fat milk showing dissolution enhancement of the poorly soluble ibuprofen in the presence of the higher fat content milk. Concealing drug administration under the auspice of this essential daily eating habit is expected to facilitate overcoming adherence barriers to medication intake by pediatric patients within a hospital setting.