The integration of multi-facet thinking – solar technology and cancer therapy

Light-activated theranostics ofer promising opportunities for disease diagnosis, image-guided surgery,and site-specifc personalized therapy. In a special study, from Michigan State University, the researchers have developed a optoelectronic tuning method for cancer therapy. The researchers on the project said that the inspiration of the method came from a long walk every evening. Optoelectronic tuning enables decoupled control over the cytotoxicity and phototoxicity of fuorescent organic salts by selective generation of mitochondrial reactive oxygen species that control cell viability. The method can also avoid shortcomings of the current fuorescent dyes--low brightness, high cytotoxicity, poor tissue penetration, and unwanted side efects. There is growing interest in developing noninvasive cancer theranostic agents that can detect and target a wide range of tumor types with minimal toxic side efects. This work develops a platform for tuning the toxicity of theranostic agents through counterion pairings for applications in both enhanced imaging and efective therapy.

solar technology and cancer therapy

The findings have been published in the Journal of Scientific Reports.

This article is licensed under a Creative Commons Attribution 4.0 International License.

The married couple's step-by-step approach has revealed a new way to detect and attack cancer cells using technology traditionally reserved for solar power. The results, published in the current issue of Scientific Reports, showcases dramatic improvements in light-activated fluorescent dyes for disease diagnosis, image-guided surgery and site-specific tumor treatment.

"We've tested this concept in breast, lung cancer and skin cancer cell lines and mouse models, and so far it's all looking remarkably promising," said Sophia, MSU biochemistry and molecular biologist.

While the cancer applications hold the most possibility, their findings have potential beyond the field of oncology, said Richard, the Johansen Crosby Endowed Professor of chemical engineering and materials science.

"This work has the potential to transform fluorescent probes for broad societal impact through applications ranging from biomedicine to photocatalysis -- the acceleration of chemical reactions with light," he said. "Our solar research inspired this cancer project, and in turn, focusing on cancer cells has advanced our solar cell research; it's been an amazing feedback loop."

Prior to the Lunts' combined effort, fluorescent dyes used for therapeutics and diagnostics, aka "theranostics," had shortcomings, such as low brightness, high toxicity to cells, poor tissue penetration and unwanted side effects.

By optoelectronically tuning organic salt nanoparticles used as theranostics, the Lunts were able to control them in a range of cancer studies. Coaxing the nanoparticles into the nontoxic zone resulted in enhanced imaging, while pushing them into the phototoxic -- or light-activated -- range produced effective on-site tumor treatment.

The key was learning to control the electronics of their photoactive molecules independently from their optical properties and then making the leap to apply this understanding in a new way to a seemingly unrelated field.

Richard had recently discovered the ability to electronically tune these salts from his work in converting photovoltaics into solar glass. Sophia had long studied metabolic pathways unique to cancer cells. It was when the Lunts were discussing solar glass during a walk that they made the connection: Molecules active in the solar cells might also be used to more effectively target and kill cancer cells.

A journey of 1,000 miles

Their walks had rather unscientific beginnings. Shortly after the Lunts met at Princeton University, Richard moved to another university. To maintain their long-distance relationship, they scheduled daily phone calls. Upon their arrival at MSU, individual academic career demands replaced geographic distance as a challenge to their busy lives.

To connect daily, they take CEO-style walks together every evening. The two-mile saunters take place rain or shine, and they often engage in scientific discussions. The three keys to their walks are intentional curiosity, perseverance and the merging of different fields and perspectives, Sophia said.

"We talk science, strategic plans for our careers and our various grants," she said. "We ping ideas off each other. Our continual conversations brainstorming ideas on a particular topic or challenge often lead to those exciting 'aha' moments."

Their walks have helped them push through many challenges.

"Our first experiments did not turn out as expected; I'm surprised that we didn't give up given how crazy the idea seemed at first," Richard said. "Figuring out how to do this research took many walks."

Obviously, the results were worth the hike. Today, Richard designs the molecules; Babak Borhan, MSU chemist, synthesizes and improves them; and Sophia tests their photoactive inventions in cancer cell lines and mouse models.

Future research will work to improve the theranostics' effectiveness, decrease toxicity and reduce side effects. The Lunts have applied for a patent for their work, and they're looking forward to eventually pushing their photoactive molecule findings through clinical trials.

"Though that will take many more walks," Richard said with a smile.

Additional MSU researchers contributing to the paper include: Deanna Broadwater, Matthew Bates, Mayank Jayaram, Margaret Young, Jianzhou He, Austin Raithel, Thomas Hamann and Wei Zhang.

This research was funded in part by the National Science Foundation and an MSU Strategic Partnership Grant.

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Source: Science Daily

Original title: Can solar technology kill cancer cells?

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