计算机科学
色阶
单色
超晶格
材料科学
多路复用器
假阳性悖论
人工智能
结核性脑膜炎
生物标志物
纳米技术
非线性系统
配体(生物化学)
叠加原理
亮度
计算机视觉
作者
Jie Cheng,Jianli Lin,Yibo Zhao,Ying Sun,Ruomei Teng,Ming Li,Guoxu Zhao,L L Chen,Caiping Ding,Youju Huang
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-02-06
卷期号:20 (6): 5238-5249
标识
DOI:10.1021/acsnano.5c21167
摘要
Nonlinear dynamic monitoring is crucial for assessing l-tryptophan (l-Trp) dysregulation progression in tuberculous meningitis (TBM); yet remains challenging due to conventional sensing probes' inherent nondirectionality and poor interfacial response control. Herein, we present a programmable organic-ligand-based self-assembly strategy to construct superlattice nanoprobes with structurally responsive, tunable interfaces. Precisely regulating ligand assembly integrates atomically dispersed platinum layers with organic ligand bilayers, forming an interactive nanobiosensing interface for real-time, quantitative detection of nonlinear l-Trp dynamics. The nanoplatform shows threshold-dependent colorimetric response: subtle monochromatic brightness shifts below 0.2 μM, and distinct multiphase color transitions via chromatic superposition above it, enabling visual discrimination of pathological l-Trp fluctuations in TBM. Integrated with machine learning-enhanced pattern recognition, it achieves robust self-calibration and zero false positives in complex clinical matrices. Compared to conventional methods (acid-fast staining, culture), it reduces processing time by >50%, boosts accuracy by >13%, and cuts reagent costs by >74%, establishing an effective paradigm for neuroinflammatory biomarker monitoring and enabling precise TBM diagnosis.
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