To highlight tumors in the body for cancer diagnosis, doctors can use tiny optical probes (nanoprobes) that light up when they attach to tumors. These nanoprobes allow doctors to detect the location, shape, and size of cancers in the body.

Most nanoprobes are fluorescent: they absorb light of a specific color, like blue, and then emit back light of a different color, like green. However, as tissues of the human body can emit light as well, distinguishing the nanoprobe light from the background light can be tough and could lead to the wrong interpretation.

Now, researchers at Imperial College London have developed new nanoprobes, named bioharmonophores and patented at Imperial, which emit light with a new type of glowing technology known as second harmonic generation (SHG).

Artistic representation of the bioharmonophore structure. (Credit: Konstantinos Kalyviotis)

After testing the nanoprobes in zebra-fish embryos, the researchers found that bioharmonophores that were modified to target cancer cells highlighted tumors more brightly and for longer periods than fluorescent nanoprobes (see Figure 1). Their light can be easily spotted and distinguished by the tissue generally emitted light, and they also attach precisely to tumor cells and no healthy cells, making them more precise in detecting tumor edges (see Figure 2). The findings are published in ACS Nano.

“Bioharmonophores uniquely combine features that could be great for cancer diagnosis and therapy in clinical practice and could eventually improve patient outcomes following further research,” says lead researcher Dr. Periklis Pantazis of Imperial’s department of bioengineering.

Bioharmonophores are both biocompatible and biodegradable because they are made of peptides. To investigate precise tumor detection, the researchers first injected zebrafish embryos with malignant cancer cells, which allowed tumor cells to proliferate unchecked. Twenty-four hours later, they injected bioharmonophores, which were modified to target p32 peptide molecules that are specifically found in tumor cells. They then used imaging techniques at Imperial’s Facility for Imaging by Light Microscopy to study how well the modified bioharmonophores detected the tumors.

They found that bioharmonophores had outstanding detection sensitivity, meaning that they attached to specific tumor cells but not to healthy ones. Fluorescence-enabled nanoprobes tend to attach less specifically, meaning they can misrepresent healthy cells as tumor cells, or vice versa.

Fig. 2 - Diagram showing assembly of bioharmonophores, alongside contrasting images of highlighted tumors using bioharmonophores and other techniques. (Credit: Pantazis Lab, Imperial College London)

They also found that, unlike fluorescence, bioharmonophores did not ‘bleach,’ meaning they did not lose their ability to emit light over time. In addition, the light emitted by bioharmonophores did not saturate as happens with fluorescent nanoprobes.

“It is very important that tumor nanoprobes highlight cells specifically and clearly for cancer diagnosis,” says Pantazis. “Our proof-of-concept study suggests that the very bright bioharmonophores could be powerful tools in diagnosing cancer and targeting treatments in the coming years.”

The manufacture of bioharmonophores is cheap, reproducible, and scalable and takes around two days at room temperature. They now need to be tested in mammals to identify how well the findings translate beyond zebrafish.

The researchers are also looking into how bioharmonophores could be used to guide surgical interventions during cancer surgery, as well as how they could generate light at different frequencies to potentially help kill tumor cells with high precision.

This work was funded by the Royal Society, Wellcome Trust, the Swiss National Science Foundation, the European Union, and the Swiss National Centre of Competence in Research.

This article was written by Caroline Broga, Communications and Public Affairs, Imperial College London. For more information, visit here .


Medical Design Briefs Magazine

This article first appeared in the May, 2021 issue of Medical Design Briefs Magazine.

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