Improved Olfactory Deposition of Theophylline Using a Nanotech Soft Mist Nozzle Chip.

Currently, nasal administration of active pharmaceutical ingredients is most commonly performed using swirl-nozzle-based pump devices or pressurized syringes. However, they lead to limited deposition in the more active regions of the nasal cavity, especially the olfactory region, which is crucial for nose-to-brain drug delivery. This research proposes to improve deposition in the olfactory region by replacing the swirl nozzle with a nanoengineered nozzle chip containing micrometer-sized holes, which generates smaller droplets of 10-50 µm travelling at a lower plume velocity. Two nanotech nozzle chips with different hole sizes were tested at different inhalation flow rates to examine the deposition patterns of theophylline, a hyposmia treatment formulation, using a nasal cavity model. A user study was also conducted and showed that the patient instructions influenced the inhalation flow rate characteristics. Targeted flow rates of between 0 and 25 L/min were used for the in vitro deposition study, yielding 21.5-31.5% olfactory coverage. In contrast, the traditional swirl nozzle provided only 10.8% coverage at a similar flow rate. This work highlights the potential of the nanotech soft mist nozzle for improved intranasal drug delivery, particularly to the olfactory region.

Regulatory strategies for early device development and approval.

The development of new technology to treat unmet clinical needs is an important component of modern cardiovascular disease. The need for this has been emphasized in the past several years beginning with the Food and Drug Administration (FDA) guidance document on Early Feasibility Studies in 2012 and then the 21st Century Cures legislation. A number of steps need to be considered in this process by the stakeholders involved including physician innovators and scientists, professional societies such as Society for Cardiovascular Angiography & Interventions, regulatory agencies, and medical device companies. This article focuses on the early iterative steps required to optimize the process and achieve the goal of timely efficient innovation and device development in cardiovascular disease.