A Transistor-like PH Nanoprobe for Tumour Detection and Image-guided Surgery

Overview

Journal Nat Biomed Eng

Publisher Springer Nature

Specialty Biomedical Engineering

Date 2017 Oct 3

PMID 28966871

Citations 59

Authors

Tian Zhao

Gang Huang

Yang Li

Shunchun Yang

Saleh Ramezani

Zhiqiang Lin

Yiguang Wang

Xinpeng Ma

Zhiqun Zeng

Min Luo

Esther de Boer

Xian-Jin Xie

Joel Thibodeaux

Rolf A Brekken

Xiankai Sun

Baran D Sumer

Jinming Gao

Affiliations

Soon will be listed here.

Abstract

Because of profound genetic and histological differences in cancerous tissue, it is challenging to detect a broad range of malignant tumours at high resolution. Here, we report the design and performance of a fluorescent nanoprobe with transistor-like responses (transition pH = 6.9) for the detection of the deregulated pH that drives many of the invasive properties of cancer. The nanoprobe amplifies fluorescence signal in the tumour over that in the surrounding normal tissues, resulting in a discretized, binary output signal with spatial resolution smaller than 1 mm. The nanoprobe allowed us to image a broad range of tumours in mouse models using a variety of clinical cameras, and to perform real-time tumour-acidosis-guided detection and surgery of occult nodules (< 1 mm) in mice bearing head-and-neck or breast tumours, significantly lengthening mice survivability. We also show that the pH nanoprobe can be used as a reporter in a fast, quantitative assay to screen for tumour-acidosis inhibitors. The binary delineation of pH achieved by the nanoprobe promises to improve the accuracy of cancer detection, surveillance and therapy.

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