Creating nanomaterials for detecting cancer earlier
The novel method may open new avenues of research beyond biosensors
- Date:
- February 26, 2020
- Source:
- University of Central Florida
- Summary:
- For the first time, a team of scientists has created functional nanomaterials with hollow interiors that can be used to create highly sensitive biosensors for early cancer detection.
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For the first time, a team of scientists at the University of Central Florida has created functional nanomaterials with hollow interiors that can be used to create highly sensitive biosensors for early cancer detection.
Xiaohu Xia, an assistant professor of chemistry with a joint appointment in the NanoScience Technology Center, and his team developed the new method and recently published their work in the journal ACS Nano.
"These advanced hollow nanomaterials hold great potential to enable high-performance technologies in various areas," says Xia. "Potentially we could be talking about a better and less expensive diagnostic tool, sensitive enough to detect biomarkers at low concentrations, which could make it invaluable for early detection of cancers and infectious diseases."
Because hollow nanomaterials made of gold and silver alloys display superior optical properties, they could be particularly good for developing better test strip technology, similar to over-the-counter pregnancy tests. Currently the technology used to indicate positive or negative symbols on the test stick is not sensitive enough to pick up markers that indicate certain types of cancer. But Xia's new method of creating hollow nanomaterials could change that.
More advance warning could help doctors save more lives.
In conventional test strips, solid gold nanoparticles are often used as labels, where they are connected with antibodies and specifically generate color signal due to an optical phenomenon called localized surface plasmon resonance. Under Xia's technique, metallic nanomaterials can be crafted with hollow interiors. Compared to the solid counterparts, these hollow nanostructures possess much stronger LSPR activities and thus offer more intense color signal. Therefore, when the hollow nanomaterials are used as labels in test strips they can induce sensitive color change, enabling the strips to detect biomarkers at lower concentrations.
"Test-strip technology gets upgraded by simply replacing solid gold nanoparticles with the unique hollow nanoparticles, while all other components of a test strip are kept unchanged," says Xia. "Just like the pregnancy test, the new test strip can be performed by non-skilled persons, and the results can be determined with the naked eye without the need of any equipment. These features make the strip extremely suitable for use in challenging locations such as remote villages."
The UCF study focused on prostate-specific antigen, a biomarker for prostate cancer. The new test strip based on hollow nanomaterials was able to detect PSA as low as 0.1 nanogram per milliliter (ng/mL), which is sufficiently sensitive for clinical diagnostics of prostate cancer. The published study includes electron microscope images of the metallic hollow nanomaterials.
"I hope that by providing a general and versatile platform to engineer functional hollow nanomaterials with desired properties, new research with the potential for other applications beyond biosensing can be launched," Xia says.
Collaborators on the study include Zhuangqiang Gao, Zheng Xi, Haihang Ye, Zhiyuan Wei and Shikuan Shao from UCF's chemistry department; Qingxiao Wang and Moon J. Kim from the University of Texas at Dallas, and Dianyong Tang from Chongqing University of Arts and Sciences in China.
Gao and Xi are postdoctoral scholars in Xia's lab, partially funded through UCF's Preeminent Postdoctoral Program.
The study was partially funded through a National Science Foundation CAREER grant (CHE-1834874).
Xia, who has a joint appointment at the NanoScience Technoloyg Center, has multiple degrees in biomedical engineering and worked at Georgia Tech as a postdoctoral fellow and at Michigan Tech as an assistant professor before joining UCF in 2018.
Story Source:
Materials provided by University of Central Florida. Original written by Zenaida Gonzalez Kotala. Note: Content may be edited for style and length.
Journal Reference:
- Zhuangqiang Gao, Haihang Ye, Qingxiao Wang, Moon J. Kim, Dianyong Tang, Zheng Xi, Zhiyuan Wei, Shikuan Shao, Xiaohu Xia. Template Regeneration in Galvanic Replacement: A Route to Highly Diverse Hollow Nanostructures. ACS Nano, 2020; 14 (1): 791 DOI: 10.1021/acsnano.9b07781
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