2D disposable stochastic sensors for molecular recognition and quantification of maspin in biological samples.

Abstract

Three disposable stochastic sensors using nanolayer deposition of a graphene nanocomposite comprising graphene nanoparticles and gold nanoparticles, on different supports: silk, plastic, and paper, and modified with chitosan, were characterized and validated for molecular recognition and quantification of maspin in biological samples. Very low limits of determination (of pg mL-1 magnitude order) were recorded (5.12pgmL-1 for the sensor based on silk at pH 7.40 and on copy paper at pHs 3.00 and 7.40; 16ngmL-1 at pH 7.40 for the sensor based on plastic, 41.00pgmL-1 for the sensor based on silk at pH 3.00, and 204.00pgmL-1 for the sensor based on plastic, at pH 3.00), with wide linear concentration ranges (5.12 × 10-12-2.00 × 10-6gmL-1 for the sensors based on silk at pH 7.40, and on copy paper at pH 3.00; 5.12 × 10-12-8.00 × 10-7gmL-1 for the sensor based on copy paper at pH 7.40; 1.60 × 10-8-2.00 × 10-6gmL-1 for the sensor based on plastic at pH 7.40; 4.10 × 10-14-2.00 × 10-6gmL-1 for the sensor based on silk, at pH 3.00; and 2.04 × 10-13-8.00 × 10-7gmL-1 for the sensor based on plastic at pH 3.00) allowing the molecular recognition and quantification of maspin in healthy people and patients with gastric cancer, when a potential of 125mV vs. Ag/AgCl was applied. The recoveries of maspin in whole blood, saliva, urine, and tissue samples were higher than 95.00%, with a relative standard deviation lower than 1.0%.