Instant Minimally Invasive Detection of Lung Cancer Through Fiber Optical Generation and Detection of Plasmonic Nanobubbles Around TiN Nanoparticles.

IF 2.3

Journal of biophotonics Pub Date : 2025-10-03 DOI:10.1002/jbio.202500326

Dmitri Lapotko, Ekaterina Lukianova

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Abstract

Plasmonic nanobubbles (PNB) are on-demand transient vapor nanobubbles generated around laser pulse-heated plasmonic nanoparticles (NP). Despite promising in vivo tests, their clinical translation is delayed by complex lasers, bulky optical guides, and thermally fragile gold NPs with low PNB generation efficacy. In clinics, there is an unmet demand for in vivo real-time detection of microscopic cancers. Here, we resolve these limitations with an all-new combination of long and safe infrared laser pulses, small biocompatible titanium nitride (TiN) NPs for cancer targeting, and an optical fiber probe for minimally invasive PNB generation and detection in vivo. In water suspensions, tissue, and human lung cancer animal models, TiN NPs efficiently generated PNBs with 325 ps/1064 nm laser pulses. A PNB combination device instantly diagnosed lung cancer in animals with close to 100% sensitivity and specificity. The developed PNB combination device will support minimally invasive clinical applications for real-time high-sensitivity cancer diagnosis during biopsy and surgery.

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通过光纤产生和检测TiN纳米粒子周围等离子体纳米气泡的肺癌即时微创检测。

等离子体纳米气泡（PNB）是在激光脉冲加热等离子体纳米粒子（NP）周围产生的随需应变的瞬态蒸汽纳米气泡。尽管在体内测试很有希望，但由于复杂的激光器、笨重的光学导片和热脆的金NPs，它们的临床转化受到延迟，PNB生成效率低。在临床上，对显微肿瘤的活体实时检测的需求尚未得到满足。在这里，我们通过一种全新的组合来解决这些限制，该组合包括长而安全的红外激光脉冲，用于癌症靶向的小型生物相容性氮化钛（TiN） NPs，以及用于微创PNB产生和体内检测的光纤探针。在水悬浮液、组织和人肺癌动物模型中，TiN NPs在325 ps/1064 nm激光脉冲下有效产生PNBs。PNB联合装置在动物中立即诊断肺癌，灵敏度和特异性接近100%。开发的PNB联合装置将支持微创临床应用，在活检和手术过程中实时进行高灵敏度的癌症诊断。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of biophotonics

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