Ultrasensitive analysis of miRNA-141 based on coordination-mediated lamellar nanostructures of [-TPE-(COOH)4-Al-]nLNs with highly efficient aggregation-induced electrochemiluminescence.

• [-TPE-(COOH) 4 -Al-] n with lamellar nanostructure was synthesized through strong chelate effect and π-π stacking. • The obtained [-TPE-(COOH) 4 -Al-] n LNs exhibited excellent AIECL performance. • Combining [-TPE-(COOH) 4 -Al-] n LNs and CSDA strategy with high efficiency, an ultrasensitive ECL biosensor was constructed for miRNA-141 detection. In this work, [-TPE-(COOH) 4 -Al-] n LNs with lamellar nanostructures (LNs) were conveniently synthesized through the high affinity coordination between Al3+ and carboxyl groups of 1,1,2,2-tetra(4-carboxylphenyl)ethylene (TPE-(COOH) 4). As there was a strong chelate effect and π-π stacking, the [-TPE-(COOH) 4 -Al-] n LNs could extend not only on a flat surface, but also in a spatial stack. The obtained [-TPE-(COOH) 4 -Al-] n LNs exhibited excellent aggregation-induced electrochemiluminescence (AIECL) which was much stronger than that of the TPE-(COOH) 4 monomer. Furthermore, through stacking and adjustment of Al3+, they also possessed higher electrochemiluminescence (ECL) efficiency compared to the crystal structure based on TPE-(COOH) 4 , which has a denser aggregation structure that causes aggregation-caused quenching (ACQ) phenomenon. Meanwhile, the [-TPE-(COOH) 4 -Al-] n LNs with Al3+ as the coordination center were superior to the coordination aggregation structures with heavy metal or rare metal ions as the coordination centers in terms of cost and biocompatibility. Using [-TPE-(COOH) 4 -Al-] n LNs as a luminescent material, an ultrasensitive ECL biosensor was fabricated for miRNA-141 detection combined with the cascaded strand displacement amplification (CSDA) strategy. Compared to traditional strand displacement amplification (SDA) reaction, the output DNA usually obtained in the first cycle could further return to attend multiple cycle amplification, resulting in the generation of more output DNA and an obvious signal amplification. The constructed biosensor showed excellent detection performance with a linear range from 1 × 10-18 M to 1 × 10-9 M and a detection limit of 1.2 × 10-19 M. This study provided a more convenient and effective AIECL strategy for tetraphenylethylene (TPE) derivatives and broadened the application of ECL technology in ultra-sensitive biochemical detection. [ABSTRACT FROM AUTHOR]