DNA-built nanoparticles safely target cancer tumours
A team of researchers at the ÖŰżÚζSM has discovered a method of assembling âbuilding blocksâ of gold nanoparticles as the vehicle to deliver cancer medications or cancer-identifying markers directly into cancerous tumors.
The study, led by Professor Warren Chan, of U of T's Institute of Biomaterials & Biomedical Engineering (IBBME) and the Donnelly Centre for Cellular & Biomolecular Research, appears in an article in this week.
âTo get materials into a tumor they need to be a certain size,â explained Chan. âTumors are characterized by leaky vessels with holes roughly 50 â 500 nanometers in size, depending on the tumor type and stage. The goal is to deliver particles small enough to get through the holes and âhang outâ in the tumorâs space for the particles to treat or image the cancer.
"If particle is too large, it canât get in, but if the particle is too small, it leaves the tumor very quickly.â
Chan and his researchers solved this problem by creating modular structures âgluedâ together with DNA.
âWeâre using a âmolecular assemblyâ model - taking pieces of materials that we can now fabricate accurately and organizing them into precise architectures, like putting LEGO blocks together,â said Leo Chou, a fifth-year PhD student at IBBME and first author of the paper. Chou (pictured right) was awarded a 2012-13 Canadian Breast Cancer Foundation Ontario Region Fellowship for his work with nanotechnology.
âThe major advantage of this design strategy is that it is highly modular, which allows you to âswapâ components in and out," Chou said. "This makes it very easy to create systems with multiple functions, or screen a large library of nanostructures for desirable biological behaviors."
The long-term risk of toxicity from particles that remain in the body, however, has been a serious challenge to nanomedical research.
"Imagine youâre a cancer patient in your 30s,â said Chan. âAnd youâve had multiple injections of these metal particles. By the time youâre in your mid-40s these are likely to be retained in your system and could potentially cause other problems.â
DNA, though, is flexible, and over time, the bodyâs natural enzymes cause the DNA to degrade, and the assemblage breaks apart. The body then eliminates the smaller particles safely and easily. But while the researchers are excited about this breakthrough, Chan cautioned that a great deal more needs to be known.
"We need to understand how DNA design influences the stability of things, and how a lack of stability might be helpful or not,â he said. âThe use of assembly to build complex and smart nanotechnology for cancer applications is still in the very primitive stage of development.
"Still, it is very exciting to be able to see and test the different nano-configurations for cancer applications."
The project was funded by the Canadian Institutes of Health Research, Natural Sciences and Engineering Research Council of Canada, Canadian Breast Cancer Foundation and Canada Foundation for Innovation.
Erin Vollick is a writer with IBBME at the ÖŰżÚζSM.