Biospecific interaction (affinity) CEC and affinity nano-LC

Fluorescent measurement of affinity binding between thrombin and its aptamers using on-chip affinity monoliths

A microfluidic chip with integrated 2mm long monoliths incorporated with poly(ethylene glycol) (PEG) groups was developed for thrombin-aptamer interaction study. The non-G quartet forming oligonucleotide coated monoliths was compared to a 15 mer thrombin-binding aptamer, in which affinity binding and elution processes were real-time monitored fluorescently. The results showed that the fluorescence intensity of aptamer stationary phase is approximately 10 times higher than that of the control column, which is probably due to the successful suppression of nonspecific adsorption between thrombin and aptamers/monoliths by using PEG-monolith. The experiment was repeated using human serum albumin (HSA) and green fluorescence protein (GFP) as interferences, it was double confirmed that thrombin was selectively retained by PEG-monolith. An elution efficiency of 75% was achieved with an elute of 200mM acetic acid and 2M NaCI, and the eluted thrombin was successfully separated in an ionic buffer system of 20mM NaHCO3 (pH 9.5) with 3% PEG. The hydrophilic and antifouling properties of PEG-monolith greatly decrease nonspecific adsorption and enhance detection sensitivity, which provided an alternative method to perform on-chip fluorescent measurement of bioaffinity binding.

Review: Aptamers in microfluidic chips

This review, covering reports published from 2002 to August 2010, shows how aptamers have made significant contributions in the improvements of microfluidic chips for affinity extraction, separations and detections. Furthermore, microfluidic chip methods for studying aptamer-target interactions and performing aptamer selections have also been summarized. Accordingly, research vacancies and future development trends in these areas are discussed.

Aptamers and molecularly imprinted polymers as artificial biomimetic receptors in affinity capillary electrophoresis and electrochromatography

Artificial biomimetic receptors, such as aptamers and molecular-imprinted polymers, show antibody-like properties which are due to molecular recognition phenomena characterized by high affinity and selectivity. These binding features have made them suitable in all those application fields in which selective recognition is required. Thus, it is not surprising that they are finding applications in affinity CE as well. Recently, a variety of ACE methods have shown themselves to be suitable tools to provide a detailed quantitative characterization of the thermodynamic and kinetic aspects of binding. At the same time, affinity CE can exploit the peculiarities of these binding interactions to set up CE-based analytical tools for the separation and the determination of specific target molecules in microscale formats. This review will provide a detailed description of affinity CE methods recently reported in the literature and related to these topics.

New technologies in affinity assays to explore biological communication

The language that cells use to communicate consists of the small molecules, peptides, and proteins that are released into the extracellular environment. To decipher this language, analytical assays are needed that have high selectivity, high sensitivity, and fast temporal resolution. Affinity assays are a group of analytical methodologies that are adept at studying this communication. In this overview, we highlight several examples from the literature on various types of affinity assays used in different platforms to monitor biological communication of peptides and proteins.

Immunoaffinity capillary electrophoresis as a powerful strategy for the quantification of low-abundance biomarkers, drugs, and metabolites in biological matrices

In the last few years, there has been a greater appreciation by the scientific community of how separation science has contributed to the advancement of biomedical research. Despite past contributions in facilitating several biomedical breakthroughs, separation sciences still urgently need the development of improved methods for the separation and detection of biological and chemical substances. In particular, the challenging task of quantifying small molecules and biomolecules, found in low abundance in complex matrices (e.g., serum), is a particular area in need of new high-efficiency techniques. The tandem or on-line coupling of highly selective antibody capture agents with the high-resolving power of CE is being recognized as a powerful analytical tool for the enrichment and quantification of ultra-low abundance analytes in complex matrices. This development will have a significant impact on the identification and characterization of many putative biomarkers and on biomedical research in general. Immunoaffinity CE (IACE) technology is rapidly emerging as the most promising method for the analysis of low-abundance biomarkers; its power comes from a three-step procedure: (i) bioselective adsorption and (ii) subsequent recovery of compounds from an immobilized affinity ligand followed by (iii) separation of the enriched compounds. This technology is highly suited to automation and can be engineered to as a multiplex instrument capable of routinely performing hundreds of assays per day. Furthermore, a significant enhancement in sensitivity can be achieved for the purified and enriched affinity targeted analytes. Thus, a compound that exists in a complex biological matrix at a concentration far below its LOD is easily brought to well within its range of quantification. The present review summarizes several applications of IACE, as well as a chronological description of the improvements made in the fabrication of the analyte concentrator-microreactor device leading to the development of a multidimensional biomarker analyzer.

Microfluidic immunoaffinity separations for bioanalysis

Microfluidic devices often rely on antibody-antigen interactions as a means of separating analytes of interest from sample matrices. Immunoassays and immunoaffinity separations performed in miniaturized formats offer selective target isolation with minimal reagent consumption and reduced analysis times. The introduction of biological fluids and other complicated matrices often requires sample pretreatment or system modifications for compatibility with small-scale devices. Miniaturization of external equipment facilitates the potential for portable use such as in patient point-of-care settings. Microfluidic immunoaffinity systems including capillary and chip platforms have been assembled from basic instrument components for fluid control, sample introduction, and detection. The current review focuses on the use of immunoaffinity separations in microfluidic devices with an emphasis on pump-based flow and biological sample analysis.