Abstract
The olfactory region of the nasal cavity directly links the brain to the external environment, presenting a potential direct route to the central nervous system (CNS). However, targeting drugs to the olfactory region is challenging and relies on a combination of drug formulation, delivery device, and administration technique to navigate human nasal anatomy. In addition, in vitro and in vivo models utilized to evaluate the performance of nasal formulations do not accurately reflect deposition and uptake in the human nasal cavity. The current study describes the development of a respirable poly(lactic-co-glycolic acid) nanoparticle (PLGA NP) formulation, delivered via a pressurized metered dose inhaler (pMDI), and a cell-containing three-dimensional (3D) human nasal cast model for deposition assessment of nasal formulations in the olfactory region. Fluorescent PLGA NPs (193 ± 3 nm by dynamic light scattering) were successfully formulated in an HFA134a-based pMDI and were collected intact following aerosolization. RPMI 2650 cells, widely employed as a nasal epithelial model, were grown at the air-liquid interface (ALI) for 14 days to develop a suitable barrier function prior to exposure to the aerosolized PLGA NPs in a glass deposition apparatus. Direct aerosol exposure was shown to have little effect on cell viability. Compared to an aqueous NP suspension, the transport rate of the aerosolized NPs across the RPMI 2650 barrier was higher at all time points indicating the potential advantages of delivery via aerosolization and the importance of employing ALI cellular models for testing respirable formulations. The PLGA NPs were then aerosolized into a 3D-printed human nasal cavity model with an insert of ALI RPMI 2650 cells positioned in the olfactory region. Cells remained highly viable, and there was significant deposition of the fluorescent NPs on the ALI cultures. This study is a proof of concept that pMDI delivery of NPs is a viable means of targeting the olfactory region for nose-to-brain drug delivery (NTBDD). The cell-based model allows not only maintenance under ALI culture conditions but also sampling from the basal chamber compartment; hence, this model could be adapted to assess drug deposition, uptake, and transport kinetics in parallel under real-life settings.
Original language | English |
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Pages (from-to) | 1108-1124 |
Number of pages | 17 |
Journal | Molecular Pharmaceutics |
Volume | 21 |
Issue number | 3 |
Early online date | 9 Feb 2024 |
DOIs | |
Publication status | Published - 4 Mar 2024 |
Data Availability Statement
All relevant data are available in the published article and its Supporting Information.Funding
The authors thank the University of Bath and Prof. Raymond Schinazi for funding a scholarship for A.M. They also thank Prof. Robert Price and the scientific team at Nanopharm Ltd (Cwmbran, U.K.) for supporting this work by manufacturing the HFA134a-pMDI devices. They further thank the technical team at the University of Bath for their assistance, especially Dr. Michael Zachariadis for his support with confocal microscopy.
Funders | Funder number |
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University of Bath |
Keywords
- PLGA nanoparticles
- RPMI 2650
- air−liquid interface
- blood–brain barrier
- nose-to-brain drug delivery
- olfactory
ASJC Scopus subject areas
- Drug Discovery
- Molecular Medicine
- Pharmaceutical Science
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