In a new study researchers from the School of Biomedical Engineering & Imaging Sciences, in collaboration with the Noninvasive Surgery & Biopsy Laboratory led by Dr James Choi at Imperial College London, have found that applying rapid short pulses (RaSP) of ultrasound can non-invasively deliver liposomes to the brain, across the blood-brain barrier. This is a specialised barrier between the brain and blood which restricts the entry of molecules to the brain, including over 90 percent of drugs. Their results were published in the Journal of Controlled Release. 

There are currently no non-invasive ways to minimise the damage to the blood-brain barrier and there is a big demand for methods to deliver large macromolecules to the brain safely to treat brain diseases.

Liposomal nanomedicines carry high concentrations of drugs and target drug release at the sites of inflammation and infection, in particular to deliver multiple drugs that cannot cross the brain and treat neurodegenerative diseases as well as brain tumours.

Liposomes are important for multiple treatments as they have shown promise in cancer, inflammation and infection treatment by delivering high concentrations of drugs. Clinically approved liposome formulations include Pfizer/BioNTech’s BNT162b2 COVID vaccine.

Focused ultrasound is a method of delivering high frequency sound waves concentrated onto a specific area to deliver a large amount of controlled energy to cause temporary or permanent disturbance in the target area depending on the duration and frequency of the sound wave.

Previous studies have delivered liposomes to the brain but have shown this delivery to be invasive and damaging to brain vasculature.

Delivery of liposomes with RaSP sequences shows promise with a diffused delivery and larger spread. Liposomes can reach inside certain (neuronal) cells in the brain. These sequences were found to be safer by investigating with microscopy techniques whether any brain damage was observed compared to conventionally used long pulses of focused ultrasound.

In this study, the researchers used a mouse model where the ultrasound waves were focused on the left side of the mouse brain. Microbubbles, gas filled bubbles which oscillate (expand and contract) in sync with ultrasound waves – and liposomes – lipid balls filled with medicine – were then injected into the bloodstream through the tail.

The ultrasound waves make the microbubbles oscillate which opens the brain’s barrier around the bubbles leading to entry of liposomes.