Recently, a collaborative research team led by Professor WANG Hui and Professor ZHANG Xin from the Hefei Institutes of Physical Science of the Chinese Academy of Sciences, successfully developed a novel carbon-coated nickel ferrite (NFN@C) nanocatalyst with significant potential in cancer therapy.
The results have been published in Advanced Functional Materials.
Cancer therapy has always struggled with targeting tumor cells effectively while minimizing damage to healthy tissue. Traditional treatments like chemotherapy and radiation often have limited precision and serious side effects. This has led to increased interest in advanced nanomaterials with enhanced catalytic and therapeutic properties, such as nanocatalysts, which can improve cancer treatment through methods like chemical dynamic therapy (CDT) and photothermal therapy (PTT).
In this study, researchers introduced nickel to the nanocatalyst, which changes its electronic structure and improves its catalytic properties. This enhancement helps the nanocatalyst convert hydrogen peroxide (H2O2) into hydroxyl radicals (·OH) in the tumor environment, making CDT more effective. Using electron paramagnetic resonance technology, the team saw a noticeable increase in the ·OH signal, indicating that nickel boosts the efficiency of the Fenton reaction.
Additionally, NFN@C shows excellent ability to convert near-infrared (NIR-II) light into heat, allowing a combined effect of PTT and CDT. This synergy further strengthens its potential in fighting cancer.
Theoretical calculations revealed that the addition of nickel also changes the electronic properties of the catalyst, lowering the activation energy for the Fenton reaction and improving its efficiency and selectivity. These insights could help optimize similar nanomaterials for other uses.
In experiments, NFN@C showed strong anticancer effects in lab tests and successfully reduced tumors in animal models. When exposed to NIR-II light, NFN@C significantly increased tumor cell death, demonstrating its powerful therapeutic effect. This enhanced catalytic activity could overcome the limitations of traditional treatments, offering a promising new approach for cancer therapy.
This research provides valuable insights into the design and optimization of nanocatalysts, particularly through innovative regulation of the nanocatalysts' electronic structures. "It holds promising implications for other cancer therapies and precision medicine," said Dr. ZHAO Jiaping, a member of the team.
Synthesis of NFN@C Catalyst and Schematic Illustration of Tumor Catalytic Therapy. (Image by ZHAO Jiaping)
