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Imperial College London startup SPARTA Biodiscovery is offering technology to accelerate the development and production of nanoparticles used in advanced medicines.
Nanoparticles are tiny polymer or lipid capsules around 1,000 times smaller in diameter than a hair. Known in medicine as nanoformulations, they are used to deliver medicines such as cancer drugs and therapeutic genetic information into the body.
Unlike traditional formulations, nanoformulations are engineered to release active agents only where they are needed, for example at tumour sites, preventing harmful side-effects or loss of potency as they move through the body.
In many cases it is not the development of new active agents but the development of nanoparticles used to package and deliver them that is driving the development of transformative new medicines.
“It’s easy to kill cancer cells using drugs. The problem is you only want to kill the cancer and not the healthy cells around it,” explains Dr Jelle Penders, CEO and co-founder of SPARTA Biodiscovery. “You can do that by putting the drug inside a carrier that protects the healthy cells and signals it to only target the cancer cells.”
Cancer medicine is just one of the fields moving towards nanoformulations, others include small-molecule drugs, gene therapies and vaccines.
The company’s new technology, SPARTA® – Single Particle Automated Raman Trapping Analysis – could help further accelerate their development.
“There’s still a major unmet need, namely an efficient way to verify the composition of nanoparticles for R&D and quality control purposes,” says Dr Penders, who began developing the technology as a researcher in Imperial’s Department of Materials.
Analysing nanoparticles
Nanoparticle analysis is currently carried out using technologies that typically look at average characteristics of these particles and can take days to return results.
SPARTA Biodiscovery’s new spectroscopy platform, by contrast, is designed to quickly and automatically analyse populations of individual nanoparticles and provide chemical fingerprints to verify each particle’s size, composition and functionality. It achieves this by focusing a laser beam onto each nanoparticle and detecting in detail how the laser light interacts with it.
SPARTA device. Photo © SPARTA Biodiscovery.
Building on prototypes developed at Imperial, and subsequently validated in published research, the company’s SPARTA platform uses new hardware and proprietary algorithms to perform the required analyses at high throughput and deliver results via an easy to read interface.
“SPARTA is an exciting proposition for customers and investors. Ultimately what gets us going is the prospect of helping bring next-generation drugs to market and the positive impact this will have on patients.” Dr Alastair SmithChair of SPARTA Biodiscovery
The company expects the SPARTA platform to help accelerate the design of nanoparticles before they progress to clinical trials.
“One use is for R&D,” says Dr Penders. “It will help scientists to really optimise their designs because they can try one way to package their drug, analyse it with the machine, then tweak some parameters and do it again. It will make R&D cycles a lot more rapid and efficient, and save pharmaceutical developers a lot of money and risk down the line.”
Another use is quality control.
“You could measure the particles coming out of the production process and make sure that they’re all within the parameters they should be. And the benefit there is that, because SPARTA looks at these particles individually, you have much, much higher resolution to detect abnormalities and contaminations.”
Source – Imperial College London
