The Medicines Discovery Catapult (MDC) have partnered with the University of Leeds to develop a therapeutic microbubble (ThMb) platform as an innovative drug delivery system.  The platform has the potential to selectively deliver drugs, thereby increasing the therapeutic window.  It is hypothesised that the ThMb platform will enable higher concentrations of drugs to reach their target, thereby increasing efficacy whilst minimising toxicity. 

Our ThMb platform consists of µm-sized gas filled phospholipid bubbles that form the core of a therapeutic microbubble drug complex. Targeting molecules and drug payload are attached to the microbubbles and injected into the body. An ultrasound trigger causes the therapeutic drug complex to release its drug payload and cause localised release of drug. 

MDC are conducting studies to prove and differentiate the ThMb delivery platform as a superior method to conventional formulation techniques. Our initial focus is on a therapeutic intervention for colorectal carcinoma and uses liposome encapsulated SN38 (LE-SN38). SN38 is a very potent drug and cannot be given via conventional formulation. 

In this study we aimed to understand the pharmacokinetic distribution and dynamic time-course of LE-SN38 using the radioactive label zirconium (⁸⁹Zr) as a marker of accumulation. We wanted to understand the pharmacokinetic profile changes once incorporated into microbubbles and show superiority against conventional liposome formulation and understand the physical mechanism of controlled drug release with our ultrasound platform.

⁸⁹Zr labelled liposome PET scans were performed in CD1 nude mice in the SW480 (colorectal cancer cell line) xenograft model. Mice were injected with either ⁸⁹Zr LE-SN38 alone, ⁸⁹Zr LE-SN38 ThMb complex with an ultrasound destruction pulse applied or ⁸⁹Zr LE-SN38 ThMb’s without the ultrasound destruction pulse applied. Mice were imaged longitudinally 1hr, 24hr and 72hr post ⁸⁹Zr injection. At each imaging time point a satellite group of animals were euthanised and a series of organs taken for biodistribution analysis.

Results showed that distribution and degradation of LE-SN38 was through the reticuloendothelial system (RES). Greatest accumulation of ⁸⁹Zr LE-SN38 was in the liver and spleen. Results were expressed as %ID/g. %ID/g in all other organs was <2%. ⁸⁹Zr LE-SN38 tumour accumulation was also measureable and was observed to be 0.83 ± 0.13; 0.96 ± 0.21 and 0.73 ± 0.14 %ID/g at each imaging time point respectively. A 2-fold increase in tumour accumulation was observed following administration of ThMb SN38 loaded liposomes with significantly increased accumulation in the blood at 1 hour post administration. In addition, application of the ultrasound in combination with the ThMbs caused transient and localised permeability to the tumour tissues with a significant difference in tumour uptake at 1 hour post treatment when ultrasound was applied. 

We showed that ⁸⁹Zr labelled LE-SN38 can be reproducibly tracked in a series of body organs across time. We showed that ThMB’s demonstrated greater accumulation than liposomal formulation alone, thus overcoming the caveat of liposome formulations of an inability to get sufficiently high enough dose of therapeutic compound to achieve efficacious effect in the target organ.  Following successful validation we will now investigate where this platform could be beneficial with other candidate compou