The biological technique of ‘optogenetics’ uses light to control cells within living tissues that have been genetically modified to be light-sensitive. However, there is limited control of processes like this, as the light can activate several genes at once, and deeply penetrating light is often needed to reach the genes in living tissues.
Now, researchers from NUS have developed a method to give more control to this process, by using specially designed nanoparticles and nanoclusters (dubbed ‘superballs’). These nanoparticles and superballs can emit different colours of light when excited by lasers at different wavelengths. These different colours of light can then be used to trigger specific biological processes.
To activate light-sensitive genes, the team led by Professor Zhang Yong from NUS Biomedical Engineering used the nanoparticles and superballs to ‘upconvert’ near-infrared (NIR) light to higher energies of visible light. Since NIR light is deeply penetrating, this approach may be used for many deep-seated tissue treatments.
Nanoparticles to control heartrate
Prof Zhang and his team invented new nanoparticles that emit either red or green light, depending on the wavelength of the NIR radiation used to excite them. The nanoparticles radiate red light when excited by a laser beam with a wavelength of 980 nanometres, and green light when the laser beam’s wavelength is decreased to 808 nanometres.
In addition to being two different colours, the light emitted from these nanoparticles can be used for bi-directional activation. This is different from current optogenetic therapies using nanoparticles, which can only activate in a monodirectional fashion. “As such, we can intricately manipulate a biological process, or some steps in the process, in different directions or programmatically,” explained Prof Zhang.
The researchers showed that it was possible to use these particles to control the beating rate in modified heart-muscle cells. By optically controlling two light-activated channels known as Jaws and VChR1 in the same cell, they were able to alter the speed of the heartbeat. The red light slowed down the heartrate, and the green light sped it up.
These nanoparticles consist of an inner core which is rich in erbium, surrounded by layers of ytterbium and neodymium-doped materials. “For generating such orthogonal fluorescence emissions, we usually need to dope multiple lanthanide ions into the nanocrystals. In our study, this is achieved by using one ion only.” This innovation from the researchers ensures that the orthogonal emissions all come from erbium ions.
In regards to this material breakthrough and application innovation, Prof Zhang said, “This demonstration provides a major step forward towards programmable multi-directional pathway control, and also offers intriguing opportunities for applications in many other synergistically interactive biological processes such as diagnostics and therapies.”
Superballs to activate anticancer drugs
In addition to the novel nanoparticles, Prof Zhang and his team recently synthesised clusters of two different nanoparticles which they named ‘superballs’. In a similar way to the novel nanoparticles, these superballs emit different coloured light when excited with different wavelengths of NIR radiation. They radiate red light when excited by a laser beam with a wavelength of 980 nanometres, and UV/blue light when the laser beam’s wavelength is decreased to 808 nanometres.
These novel superballs were then used to enhance a photodynamic cancer treatment procedure.
When the superballs were energetically excited to radiate red light, they were able to enter a cell. Next, they were excited to radiate UV/blue light to increase cell’s sensitivity to reactive oxygen species. Finally, they were excited to radiate red light again to activate photosensitive drugs to produce reactive oxygen species. These reactive oxygen species can then induce the killing of tumour cells.
With this research breakthrough, the NUS scientists have developed a simple, user-friendly method for synthesising these superballs. The shape, size and even the excitation/emission wavelengths of the superballs can be modified depending on the application needed.