Multifunctional Screening Platform for the Highly Efficient Discovery of Aptamers with High Affinity and Specificity.

Aptamers have attracted much attention as the next generation of affinity reagents. Unfortunately, the selection efficiency remains a critical bottleneck for the widespread application of aptamers. Herein, to accelerate aptamers discovery, a multifunctional microfluidic selection platform was developed, on which the selection efficiency was greatly improved and high-affinity and -specificity aptamers were generated within two round selections. The multifunctional screening platform, precisely manipulating magnetic beads on the micrometer scale, improved selection performance based on microfluidic continuous flow and enhanced the selection process control via in situ monitoring and real-time evaluation. This method could suppress ∼50-fold nonspecific binding nucleic acids compared to the conventional methods, further eliminate weakly bound nucleic acids within 9 min, and simultaneously perform the negative selection and positive selection. And the selection effectiveness was in situ and real-time monitoring. Three aptamers showed high affinity and specificity toward mucin 1 (MUC1) with dissociation constants (Kd) in nanomolar range (from 22 to 65 nM). Furthermore, the selected aptamer was able to specially label cancer cells and efficiently capture exosomes with 64% capture efficiency. It demonstrated that the multifunctional screening platform was an efficient method to generate high-quality aptamers in a rapid and economic manner.

One-step separation-free detection of carcinoembryonic antigen in whole serum: Combination of two-photon excitation fluorescence and optical trapping.

Direct analysis of biomolecules in complex biological samples remains a major challenge for fluorescence-based approaches due to the interference of background signals. Herein, we report an analytical methodology by exploiting a single low-cost near-infrared sub-nanosecond pulse laser to synchronously actualize optical trapping and two-photon excitation fluorescence for senstive detection of carcinoembryonic antigen (CEA) in buffer solution and human whole serum with no separation steps. The assay is performed by simultaneously trapping and exciting the same immune-conjugated microsphere fabricated with a sandwich immunization strategy. Since the signal is strictly limited in the region of a three-dimensional focal volume where the microsphere is trapped, no obvious background signal is found to contribute the detected signals and thus high signal-to-background data are obtained. As a proof-of-concept study, the constructed platform exhibits good specificity for CEA and the detection limit reaches as low as 8pg/mL (45 fM) with a wide linear range from 0.01 to 60ng/mL in the both cases. To investigate the potential application of this platform in clinical diagnosis, 15 cases of serum samples were analyzed with satisfactory results, which further confirm the applicability of this method.