Researchers Achieved Another Breakthrough with Highly Fluorescent Gold Nanoclusters for Sub-Cellular Imaging

Researchers from Singapore's Institute of Bioengineering and Nanotechnology (IBN) have achieved another biomedical breakthrough with highly fluorescent gold nanoclusters for sub-cellular imaging. Their new invention has broad implications for biolabeling and disease diagnosis.

Red fluorescent gold nanoclusters can help to improve bioimaging and diagnostics.

Measuring less than 1 nanometer in diameter, IBN's gold clusters are much smaller than currently available nanoscale imaging technologies such as semiconducting quantum dots, which are usually at least 3 nanometers in size. Unlike quantum dots, the gold nanoclusters are suitable for use within the body as they do not contain toxic metals such as cadmium and lead. Their sub-nanometer size makes it easy to target the nucleus inside the cell for sub-cellular biolabeling and bioimaging. Tracking the cell nucleus can help scientists monitor the fundamental life processes of healthy DNA replication and any genomic changes. With improved bioimaging at the cell nucleus, scientists can also study the effectiveness of drug and gene therapies.

"Gold nanoclusters have promising characteristics for applications in vivo. Our materials are smaller, less toxic and more biocompatible than the existing inorganic fluorescent quantum dot tags. The red fluorescence of the nanoclusters enhances biomedical images of the body greatly as there is reduced background fluorescence and better tissue penetration," said IBN Postdoctoral Fellow, Dr Jianping Xie.

Synthesized via a single-step reaction at body temperature (37°C), the gold nanoclusters are formed with a commercially available common protein such as bovine serum albumin (BSA). "The protein holds and interacts with gold ions in aqueous solution. We are able to use this protein to provide a scaffold for the formation of gold nanoclusters," explained Dr Yuangang Zheng, IBN Senior Research Scientist.

IBN's gold nanoclusters are stable in aqueous solution as well as in the solid form, which facilitates their storage and distribution. Besides the low cost of the required reagents, the preparation of the gold nanoclusters also adopts an environmentally friendly method that does not involve toxic chemicals or high temperatures. In addition, the simple synthesis technique can be scaled up easily for mass production. IBN's research on gold nanoclusters has been recently published in the leading international chemistry journal, Journal of the American Chemical Society, 131 (2009) 888-889.

"We are inspired by nature's ability to create elegant and functional materials. Our process is similar to biomineralization in nature that is found in the formation of bones and shells: where functional proteins mostly interact with sequestered inorganic ions to provide scaffolds for mineral formation," Principal Investigator and IBN Executive Director Professor Jackie Y. Ying elaborated. "There is a significant potential for our technology to impact biological and medical research, where our gold nanoclusters can significantly enhance the details available for precision bioimaging in medical diagnosis and treatment."

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