核酸のポリアニリンベースのセンサ

Conjugated polymers provide many options for molecular sensors. This includes fluorescence, electronic, and colorimetric responses¹. There have been many efforts to incorporate conjugated polymers in nucleic acid sensors. However, most systems require secondary detection, limiting sensing options². Recently, we reported a conjugated polymer-based sensor platform built on polyaniline (PANI) that exploits properties of this polymer, creating a label-free system³. PANI is an extensively conjugated electro-active polymer with properties such as fluorescence and resistance that are suitable for measuring biological systems⁴. The excitons within the structure are not localized leading to mobility of the positive charge between monomeric subunits. This provides a flexible scaffold of positive charges that can interact with the negatively charged backbone of DNA^5,6. Importantly, electrostatically attached DNA is orientated such that nitrogenous bases can participate in base pairing. Association with DNA alters the electronic properties of PANI, an effect that can be enhanced by UV irradiation (Figure 1)³. Using this system, oligonucleotides complementary to target nucleic acids can be immobilized on PANI. Multiple studies have demonstrated that upon hybridization electrostatically adsorbed oligonucleotides dissociate from PANI or other cationic matrices due to conformational changes caused by the switch to a double-stranded DNA structure^3,5,7.

In a sensor system where probe attachment modulates conjugated polymer properties, hybridization events can be transduced without labels or enzymatic modification of probes or target nucleic acids. Conjugated polymers offer great flexibility in detection methods, one of which is fluorescence. Through monitoring PANI fluorescence, concentrations of target nucleic acids as low as 10^-11 M (10 pM) can be detected³. Detection is rapid, occurring within 15 minutes of hybridization, and specific where a single mismatch in a target molecule can be differentiated³.

Fabrication of PANI-sensors is straightforward. High molecular weight PANI can be generated that is well-dispersed in water using standard synthesis procedures involving aniline monomer, surfactant, and controlled addition of an oxidant. Yield can be very high and unreacted oxidant removed by washing with water, ensuring no further PANI growth. PANI-probe association occurs spontaneously upon mixture, and complex formation is enhanced by mild UV exposure. Hybridization can be carried out immediately, and the changes in PANI fluorescence assayed following a short incubation. The simplicity of this technology makes it highly accessible to many laboratories.