Functional
photothermal nanomaterials have gained widespread attention
in the field of precise cancer therapy and early disease diagnosis
due to their unique photothermal conversion properties. However, the
relatively narrow temperature response range and the outputable accuracy
of commercial thermometers limit the accurate detection of biomarkers.
Herein, we designed a liposome-embedded Cu2–xAgxS amplification-based photothermal
sensor for the accurate determination of cardiac troponin I (cTnI)
in health monitoring and point-of-care testing (POCT). The combinable
3D-printing detecting device monitored and visualized target signal
changes in the testing system under the excitation of near-infrared
(NIR) light, which was recorded and evaluated for possible pathogenicity
by a smartphone. Notably, we predicted the potentially efficient thermal
conversion efficiency of Cu2–xAgxS from the structure and charge density distribution,
calculated by the first-principles and density functional theory (DFT),
which provided a theoretical basis for the construction of novel photothermal
materials, and the experimental results proved the correctness of
the theoretical projections. Under optimal conditions, the photothermal
immunoassay showed a dynamic linear range of 0.02–10 ng mL–1 with a detection limit of 11.2 pg mL–1. This work instructively introduces promising theoretical research
and provides new insights for the development of sensitive portable
photothermal biosensors.