A spray-dried engineered particle formulation, Tobramycin Inhalation Powder (TIP), was designed through rational selection of formulation composition and process parameters. This PulmoSphere powder comprises small, porous particles with a high drug load. As a drug/device combination, TOBI Podhaler enables delivery of high doses of drug per inhalation, a feature critical for dry powder delivery of anti-infectives for treatment of cystic fibrosis. The objective of this work was to characterize TIP on both the particle and molecular levels using multiple orthogonal physical characterization techniques. Differential scanning calorimetry (DSC), X-ray powder diffraction (XRPD), electron spectroscopy for chemical analysis (ESCA), and Raman measurements show that a TIP particle consists of two phases: amorphous, glassy tobramycin sulfate with a glass transition temperature of about 100 °C and a gel-phase phospholipid (DSPC) with a gel-to-liquid-crystal transition temperature of about 80 °C. This was by design and constituted a rational formulation approach to provide Tg and Tm values that are well above the temperatures used for long-term storage of TIP. Raman and ESCA data provide support for a core/shell particle architecture of TIP. Particle surfaces are enriched with a porous, hydrophobic coating that reduces cohesive forces, improving powder fluidization and dispersibility. The excellent aerosol dispersibility of TIP enables highly efficient delivery of fine particles to the respiratory tract. Collectively, particle engineering has enabled development of TOBI Podhaler, an approved inhaled drug product that meaningfully reduces the treatment burden to cystic fibrosis patients worldwide.
Tobramycin Inhalation Powder (TIP) is a spray-dried engineered particle formulation used in TOBI Podhaler, a drug-device combination for treatment of cystic fibrosis (CF). A TIP particle consists of two phases: amorphous, glassy tobramycin sulfate and a gel-phase phospholipid (DSPC). The objective of this work was to characterize both the amorphous and gel phases following exposure of TIP to a broad range of RH and temperature. Because, in principle, changes in either particle morphology or the solid-state form of the drug could affect drug delivery or biopharmaceutical properties, understanding physical stability was critical to development and registration of this product. Studies included morphological assessments of particles, thermal analysis to measure the gel-to-liquid crystalline phase transition (T) of the phospholipid and the glass transition temperature (T) of tobramycin sulfate, enthalpy relaxation measurements to estimate structural relaxation times, and gravimetric vapor sorption to measure moisture sorption isotherms of TIP and its components. Collectively, these data enabled development of a state diagram for TIP-a map of the environmental conditions under which physical stability can be expected. This diagram shows that, at long-term storage conditions, TIP is at least 50 °C below the T of the amorphous phase and at least 40 °C below the T of the gel phase. Enthalpy relaxation measurements demonstrate that the characteristic structural relaxation times under these storage conditions are many orders of magnitude greater than that at T. These data, along with long-term physicochemical stability studies conducted during product development, demonstrate that TIP is physically stable, remaining as a mechanical solid over time scales and conditions relevant to a pharmaceutical product. This met a key design goal in the development of TIP: a room-temperature-stable formulation (3-year shelf life) that obviates the need for refrigeration for long-term storage. This has enabled development of TOBI Podhaler-an approved inhaled drug product that meaningfully reduces the treatment burden of CF patients worldwide.
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