Login / Signup

iBCS: 3. A Biopharmaceutics Classification System for Orally Inhaled Drug Products.

Jayne E HastedtPer BäckmanAntonio CabalAndy ClarkCarsten EhrhardtBen ForbesAnthony J HickeyGuenther HochhausWenlei JiangStavros KassinosPhilip J KuehlDavid PrimeYoen-Ju SonSimon TeagueUlrika TehlerJennifer Wylie
Published in: Molecular pharmaceutics (2023)
In this article, we specify for the first time a quantitative biopharmaceutics classification system for orally inhaled drugs. To date, orally inhaled drug product developers have lacked a biopharmaceutics classification system like the one developed to navigate the development of immediate release of oral medicines. Guideposts for respiratory drug discovery chemists and inhalation product formulators have been elusive and difficult to identify due to the complexity of pulmonary physiology, the intricacies of drug deposition and disposition in the lungs, and the influence of the inhalation delivery device used to deliver the drug as a respirable aerosol. The development of an inhalation biopharmaceutics classification system (iBCS) was an initiative supported by the Product Quality Research Institute (PQRI). The goal of the PQRI iBCS working group was to generate a qualitative biopharmaceutics classification system that can be utilized by inhalation scientists as a "rule of thumb" to identify desirable molecular properties and recognize and manage CMC product development risks based on physicochemical properties of the drug and the deposited lung dose. Herein, we define the iBCS classes quantitatively according to the dose number and permeability. The proposed iBCS was evaluated for its ability to categorize marketed inhaled drugs using data from the literature. The appropriateness of the classification of each drug was assessed based on published development, clinical and nonclinical data, and mechanistic physiologically based biopharmaceutics modeling. The inhaled drug product development challenges for each iBCS classification are discussed and illustrated for different classes of marketed inhaled drugs. Finally, it is recognized that discriminatory laboratory methods to characterize regional lung deposition, dissolution, and permeability will be key to fully realizing the benefits of an iBCS to streamline and derisk inhaled drug development.
Keyphrases
  • cystic fibrosis
  • adverse drug
  • systematic review
  • drug discovery
  • randomized controlled trial
  • deep learning
  • pulmonary hypertension
  • quality improvement
  • data analysis
  • artificial intelligence