Development of a compounded propofol nanoemulsion using multiple non-invasive process analytical technologies
Publication date
2023-06-10
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Abstract
Propofol is the preferred anaesthetic for induction and maintenance of sedation in critically ill mechanically ventilated COVID-19 patients. However, during the outbreak of the COVID-19 pandemic, regular supply chains could not keep up with the sudden increase in global demand, causing drug shortages. Propofol is formulated as an oil-in-water emulsion which is administered intravenously. This study explores the extemporaneous preparation of a propofol emulsion without specialized manufacturing equipment to temporally alleviate such shortages. A commercially available lipid emulsion (IVLE, SMOFlipid 20 %), intended for parenteral nutrition, was used to create a propofol loaded nanoemulsion via addition of liquid propofol drug substance and subsequent mixing. Critical quality attributes such as mean droplet size and the volume-weighted percentage of large-diameter (>5µm) droplets were studied. The evolution of droplet size and propofol distribution was monitored in situ and non-destructively, maintaining sterility, using Spatially Resolved Dynamic Light Scattering and Near Infrared Spectroscopy, respectively. Using response surface methodology, an optimum was found for a 4 % w/v propofol formulation with a ∼15 min mixing time in a flask shaker at a 40° shaking angle. This study shows that extemporaneous compounding is a viable option for emergency supply of propofol drug product during global drug shortages.
Keywords
Compounding, COVID-19, Drug shortage, Parenteral lipid nano-emulsion, Propofol, Pharmaceutical Science, Journal Article
Citation
Rooimans, T, Damen, M, Markesteijn, C M A, Schuurmans, C C L, de Zoete, N H C, van Hasselt, P M, Hennink, W E, van Nostrum, C F, Hermes, M, Besseling, R & Vromans, H 2023, 'Development of a compounded propofol nanoemulsion using multiple non-invasive process analytical technologies', International Journal of Pharmaceutics, vol. 640, 122960. https://doi.org/10.1016/j.ijpharm.2023.122960