Abstract
Supersaturated lipid-based drug delivery systems are increasingly being explored as a bio-enabling formulation approach, particularly in preclinical evaluation of poorlywater-soluble drugs. While increasing the drug load through thermally-induced supersaturation resulted in enhanced in vivo exposure for some drugs, for others, such as cinnarizine, supersaturated lipid-based systems have not been found beneficial to increase the in vivo bioavailability. We hypothesized that incorporation of precipitation inhibitors to reduce drug precipitation may address this limitation. Therefore, pharmacokinetic profiles of cinnarizine supersaturated lipid-based drug delivery systems with or without precipitation inhibitors were compared. Five precipitation inhibitors were selected for investigation based on a high throughput screening of twenty-one excipients. In vivo results showed that addition of 5% precipitation inhibitors to long chain monoglyceride (LCM) or medium chain monoglyceride (MCM) formulations showed a general trend of increases in cinnarizine bioavailability, albeit only statistically significantly increased for Poloxamer 407 + LCM system (i.e. 2.7-fold increase in AUC0-24h compared to LCM without precipitation inhibitors). It appeared that precipitation inhibitors mitigated the risk of in vivo precipitation of cinnarizine from sLBDDS and overall, bioavailability was comparable to that previously reported for cinnarizine after dosing of non-supersaturated lipid systems. In summary, for drugs which are prone to precipitation from supersaturated lipid-based drug delivery systems, such as cinnarizine, inclusion of precipitation inhibitors mitigates this risk and provides the opportunity to maximize exposure which is ideally suited in early efficacy and toxicology evaluation.
Highlights
Lipid-based drug delivery systems (LBDDS) have been intensively investigated as bio-enabling technologies and suggested as drug delivery solutions for poorly water-soluble drugs (PWSDs) based on their increased apparent solubilization capacity upon dilution in the gastro intestinal (GI) fluids (O’Driscoll and Griffin, 2008), (Feeney et al, 2016)
In vivo results showed that addition of 5% precipitation inhibitors to long chain monoglyceride (LCM) or medium chain monoglyceride (MCM) formulations showed a general trend of increases in cinnarizine bioavailability, albeit only statistically significantly increased for Poloxamer 407 + LCM system (i.e. 2.7-fold increase in AUC0-24h compared to LCM without precipitation inhibitors)
In the case of SDS and Kolliphor® EL, while it may appear these two excipients are potentially suitable precipitation in hibitors (PIs) based on high differences of area under the plasma concentration-time curve (AUC) profiles relative to reference conditions, these differences were mainly based on increased drug solubilisation in media containing 1% of each excipient rather than the extent a precipitation inhibition effect (i.e. ratio AUCpp profiles/AUCsolubility were lower (SDS = 0.9) or comparable to FaSSIF (Kolliphor® EL = 1.77))
Summary
Lipid-based drug delivery systems (LBDDS) have been intensively investigated as bio-enabling technologies and suggested as drug delivery solutions for poorly water-soluble drugs (PWSDs) based on their increased apparent solubilization capacity upon dilution in the gastro intestinal (GI) fluids (O’Driscoll and Griffin, 2008), (Feeney et al, 2016). Improved or equivalent drug exposure was demonstrated when administered as supersaturated LBDDS (sLBDDS) compared to conventional non-supersaturated LBDDS for a number of drugs, including: venetoclax (Koehl et al, 2020), celecoxib (Ilie et al., 2020c), halofantrine (Thomas et al, 2012), (Michaelsen et al, 2016), simvastatin (Thomas et al, 2013), fenofibrate (Thomas et al, 2014), (Michaelsen et al, 2019) and R3040 (Siqueira Jørgensen et al, 2018) Such supersaturated systems, where the drug concentration in the lipid system exceeds the thermodynamic solubility, can be obtained by heating the drug and lipid excipients at 60 ◦C followed by cooling to ambient temperature (Ilie et al, 2020b).
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