Infrared-glowing nanoparticle gives researchers a view inside a living mouse's brain

lab mouse
Credit: CC0 Public Domain

Stanford chemists have developed a new deep-tissue imaging technique that can see beneath the skin of living subjects to illuminate buried tumors with unparalleled clarity.

In a new study published in the September 30 issue of the journal Nature Biotechnology, the researchers demonstrate how their technique can be used to predict the response of cancer patients to immunotherapy and to track their progress following treatment.

"We call this for non-invasively peering into biological tissues," said study leader Hongjie Dai, the J.G. Jackson and C.J. Wood Professor in Chemistry in Stanford's School of Humanities and Sciences.

The technique relies on nanoparticles containing the element erbium, which belongs to a class of so-called rare-earth minerals prized by chemists for their unique ability to glow in the infrared.

The team covered the nanoparticles in a chemically engineered coating that helps the particles dissolve in the bloodstream and also makes them less toxic and exit the body quicker. In addition, the coating provides anchoring points for molecules that that act like guided missiles to locate and attach to specific proteins on cells.

Clearing the fog

Under a low-powered LED light, the erbium particles bask targeted tissues or even in a bright infrared glow that can be seen deeper and with finer resolution than conventional imaging techniques, the researchers say. "It is like seeing while driving on a highway before and after the fog evaporates on a winter day," said study co-first author Yeteng Zhong, a postdoctoral researcher in Dai's lab. "The combined imaging depth, molecular specificity and multiplicity, and spatial and temporal resolution are unattainable by previous techniques."

The brain vessels of a live mouse are illuminated in infrared light by erbium nanoparticle probes. Credit: Stanford University

In a video highlighting the power of their nanoprobes, the branching blood vessels of a brain inside a living mouse are limned in a teal light and shift as the creature moves its head. "Our approach allows for seeing into an intact mouse brain while conventional approaches see only the scalp," said study co-first author Zhuoran Ma, a graduate student in Dai's lab.

In the study, the researchers show their technique can identify tumors in mice carrying a protein that makes them vulnerable to cancer drugs that activate the body's own immune system. This approach could provide a noninvasive way of identifying patients who would respond well to those drugs without needing to take a sample, or biopsy, of the tumor, as they currently need to do.

Similarly, erbium nanoparticles can monitor patients' responses following cancer therapy to track whether they are responding to the drugs and if their tumors have shrunk.

As a demonstration, Dai and his colleagues combined their erbium nanoparticles with another infrared imaging technique to simultaneously image two molecular targets –cancer cells and T-cells—simultaneously. The result is a layered, multi-colored snapshot showing T-cells homing in on a from elsewhere in the mouse's body.

The researchers said their technique could also enable surgeons to more precisely excise tumors and aid biologists and medical researchers in studying fundamental processes within cells.

More information: Yeteng Zhong et al. In vivo molecular imaging for immunotherapy using ultra-bright near-infrared-IIb rare-earth nanoparticles, Nature Biotechnology (2019). DOI: 10.1038/s41587-019-0262-4

Journal information: Nature Biotechnology

Citation: Infrared-glowing nanoparticle gives researchers a view inside a living mouse's brain (2019, October 3) retrieved 28 March 2024 from https://phys.org/news/2019-10-infrared-glowing-nanoparticle-view-mouse-brain.html
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.

Explore further

New optical imaging system could be deployed to find tiny tumors

134 shares

Feedback to editors