A temperature-tuned electrochemiluminescence layer for reversibly imaging cell topography.
Cheng MaZejing XingXiaodan GouLi-Ping JiangJun-Jie ZhuPublished in: Chemical science (2022)
Investigating electrochemiluminescence (ECL) scenarios under different temperatures is important to expand its imaging scope near an electrode surface. Here, we develop a temperature-tuned ECL layer by recording the evolution of shadow regions of adherent cells. Finite element simulation and experimental results demonstrate that the thickness of the ECL layer (TEL) is reversibly regulated by electrode temperature ( T e ), so that single cell topography at different heights is imaged. The TEL in two ECL routes shows different regulation ranges with elevated T e , thus providing a flexible approach to adjust the imaging scope within specific heights. In addition, a heated electrode significantly improves the image quality of cell adhesion in heterogeneous electrochemical rate-determined situations. Thus, the contrast in cell regions shows a reversible response to T e . This work provides a new approach to regulate the TEL and is promising for monitoring transient heat generation from biological entities.
Keyphrases
- single cell
- high resolution
- image quality
- cell adhesion
- rna seq
- finite element
- induced apoptosis
- carbon nanotubes
- sensitive detection
- computed tomography
- climate change
- gold nanoparticles
- magnetic resonance
- high throughput
- solid state
- cell proliferation
- cell death
- oxidative stress
- magnetic resonance imaging
- heat stress
- photodynamic therapy