Pediatric drug development presents many unique challenges in the effective treatment of diseases in children, from adequate dosing information and pediatric-specific testing to palatable flavor profiles and effective delivery formats. A novel technology that masks bitter drug flavors while providing flexibility in dose design and format would enable formulation of existing adult pharmaceutical products into medications specially designed for pediatric patients. Our proposed strategy uses Precision Particle Fabrication (PPF) to develop pediatric drug-loaded microparticles that mask bitter flavors and allow for flexible dosing and formats. The central advantage of PPF technology lies in its precise control of particle size, shape, material, and release rates. Our long-term goal is to adapt this flexible, user-friendly, inexpensive technology to create a platform for microencapsulating unpalatable pediatric active pharmaceutical ingredients (API's). We hypothesize that the uniform, precisely engineered microparticles produced by PPF will create effectively taste- masked formulations for pediatric drugs while also allowing for the swift and controlled release of the active agents under digestive conditions. We further hypothesize that this robust microparticle strategy will allow for accurate, flexible dosing and adaptation to multiple drug delivery formats. Our research team will develop and characterize model bitter API-containing microparticles with precisely controlled physicochemical features that are designed to meet palatability standards (Aim 1). We will then optimize the release characteristics and taste-masking performance of these model microparticles (Aim 2). The result will be model drug-loaded microparticles that meet palatability standards based on particle size, homogeneity, and drug surface concentration and that can be tailored for desired release profiles under digestive conditions. After establishing the feasibility of precisely engineering these microparticles, Phase II will focus on the clinical evaluation of organoleptic properties of taste and mouth feel as well as demonstration of dosing accuracy, titration, and format flexibility. This PPF-based encapsulation strategy addresses issues of palatability, dosage accuracy, and format flexibility in pediatric drugs, while improving upon existing encapsulation techniques that are costly and time-consuming and produce poorly controlled, heterogeneous batches of microparticles. In adition, this PF technology is highly adaptable to multiple drugs and matrix/coating materials as well as large-scale production. The result will be an inexpensive, highly flexible pediatric platform for creating palatable, age-appropriate, and accurate dosage forms, leading to safer pediatric formulations and improved patient compliance.
Public Health Relevance: Inadequate pediatric pharmaceutical formulations impair effective treatment of diseases in children due to poor compliance, ad hoc formulations, and dangerous medication errors. At the foundation of the problem are palatability, accurate dosing, and age-appropriate dosage format challenges. Development of a user-friendly, inexpensive development platform for pediatric reformulation of existing adult drug products to administer taste-masked active pharmaceutical ingredients (APIs) with controlled release rates is needed. Using model bitter APIs, this project aims to test the feasibility of Precision Particle Fabricatio technology to produce palatable, age-appropriate, and accurate doses as a means to safer pediatric medications and better compliance.
Public Health Relevance Statement: Inadequate pediatric pharmaceutical formulations impair effective treatment of diseases in children due to poor compliance, ad hoc formulations, and dangerous medication errors. At the foundation of the problem are palatability, accurate dosing, and age-appropriate dosage format challenges. Development of a user-friendly, inexpensive development platform for pediatric reformulation of existing adult drug products to administer taste-masked active pharmaceutical ingredients (APIs) with controlled release rates is needed. Using model bitter APIs, this project aims to test the feasibility of Precision Particle Fabricatio technology to produce palatable, age-appropriate, and accurate doses as a means to safer pediatric medications and better compliance.
NIH Spending Category: Bioengineering; Dental/Oral and Craniofacial Disease; Neurosciences; Patient Safety; Pediatric
Project Terms: Address; Adult; Age; base; Biocompatible Coated Materials; Biological Assay; Caliber; capsule (pharmacologic); Chairperson; Characteristics; Child; Childhood; Cities; Clinical; Compliance behavior; controlled release; design; Development; Disease; dosage; Dosage Forms; Dose; Drug Delivery Systems; drug development; Drug Formulations; Drug Industry; effective therapy; Encapsulated; Engineering; Ensure; Evaluation; experience; Feasibility Studies; Flavoring; flexibility; Foundations; Goals; Hospitals; improved; Incentives; Industry; Kansas; large scale production; Masks; Medical Research; Medication Errors; meetings; Missouri; Modeling; new technology; Oral cavity; particle; Particle Size; Patients; pediatric pharmacology; Performance; Pharmaceutical Preparations; Pharmacologic Substance; Pharmacology; Phase; Physician Executives; Positioning Attribute; Principal Investigator; Production; Property; Proteins; Provider; Research; research clinical testing; segregation; Shapes; Solutions; success; Surface; Tablets; Taste Perception; Techniques; Technology; technology development; Testing; Thick; Time; Titrations; Universities; user-friendly; Work