Traditional magnetic separators, however, present a challenge: they generate a magnetic force that is very high near the side of the vessel closest to the magnet and decreases rapidly with distance.

Understanding the process and anticipating the problems can help ensure successful separations. The use of magnetic beads for capturing biological molecules has become commonplace in the life sciences ...

Magnetic beads (or superparamagnetic particles) can be used for the isolation and purification of cells, nucleic acids, proteins or any other biomolecules. The surface of magnetic beads can be coated ...

Enzyme-linked immunosorbent assays (ELISAs) continue to evolve to meet increased user demands. One such advancement stemming from traditional ELISA technology is the use of microspheres (beads) as a ...

Researchers from the National Institute of Standards and Technology (NIST) and University of Colorado Boulder (CU) have developed a low-power microchip that uses a combination of microfluidics and ...

Magnetic beads (or superparamagnetic particles) are highly versatile and automation-friendly tools used to purify, enrich or deplete most biological targets, including cells, exosomes, proteins and ...

INTEGRA Biosciences created the MAG and HEATMAG modules with scientists in mind. These state-of-the-art methods simplify the purification of magnetic beads in various proteomics and molecular ...

Several methods of allodepletion are being explored for their efficacy in reducing the risk of GvHD following allogeneic haematopoietic stem cell transplantation (allo-SCT). 1, 2 Because ...

Scientists have successfully applied magnetic assist recording to magnetic-holographic memory to reduce recording energy consumption and achieve error-free data reconstruction. This new technology is ...