Magnetic beads (or superparamagnetic particles) are versatile little tools for easy and effective isolation of biomolecules Use this guide to compare the different surface chemistries and find the type for your application.
What are magnetic beads?
Magnetic beads are made up of tiny (20 to 30 nm) particles of iron oxides, such as magnetite (Fe3O4), which give them superparamagnetic properties.
Superparamagnetic beads are different to more common ferromagnets in that they exhibit magnetic behavior only in the presence of an external magnetic field. This property is dependent on the small size of the particles in the beads, and enables the beads to be separated in suspension, along with anything they are bound to. Since they don’t attract each other outside of a magnetic field, they can be used without any concern about unwanted clumping.
There are many types of magnetic beads available. Different surface coatings and chemistries give each type of bead its own binding properties, which can be used for magnetic separation (isolation and purification) of nucleic acids, proteins, or other biomolecules in an easy, effective, and scalable way.
This ease-of-use makes them automation friendly and well suited for a range of applications, including sample preparation for next generation sequencing (NGS) and PCR, protein purification, molecular and immunodiagnostics, and even magnetic activated cell sorting (MACS), among many others. They also ease some of the challenges associated with extracting nucleic acids from different sample types.
What is magnetic separation?
Magnetic separation uses a magnetic field to separate micrometer-sized paramagnetic particles from a suspension. In molecular biology, magnetic beads provide a simple and reliable method of purifying various types of biomolecule, including genomic DNA, plasmids, mitochondrial DNA, RNA, and proteins.
For example, under optimized conditions, DNA selectively binds to an appropriately-coated bead surface, leaving contaminants in solution. You can then use this purified DNA directly in molecular biology applications.
A key advantage to using magnetic beads is that you can isolate nucleic acids and other biomolecules directly from a crude sample, and from a variety of different types of sample, with minimal processing. This sets magnetic beads apart from other methods of nucleic acid isolation, which might have different protocols for different types of sample, and involve more hands-on time.
How does magnetic bead DNA extraction work?
Magnetic beads have been around in one form or another for decades. Their potential in nucleic acid purification was recognized in the 1990’s, as demonstrated by the US patent: “DNA purification and isolation using magnetic particles”. The approach, largely unchanged since, relies on using magnetic beads with a coating that can bind nucleic acids reversibly by just adjusting buffer conditions (Fig 1).
Fig 1. Overview of magnetic bead-based DNA extraction using Sera-Mag beads.
After binding DNA, an external magnetic field attracts the beads to the outer edge of the containing tube, immobilizing them. While the beads are immobilized, the bead-bound DNA is retained during the washing steps. Adding elution buffer, and removing the magnetic field then releases the DNA as a purified sample, ready for quantitation and analysis.
This approach removes the need for vacuum or centrifugation, which minimizes stress or shearing forces on the target molecules, requires fewer steps and reagents than other DNA extraction protocols, and is amenable to automation in 24, 96, and 384-well plates.
So, it’s no wonder that magnetic beads are gaining in popularity. Indeed, manufacturers have now developed numerous commercial nucleic acid isolation kits based on magnetic beads. They have options for various surface chemistries and a range of applications. The ligand-binding properties can range from being indiscriminate to sequence- or tag-specific, all of which can be a challenge to keep up with!
Table 1 gives an overview of the latest range of magnetic bead types, with their key properties and applications.
Table 1. Comparison of magnetic bead surface chemistries and applications
|Carboxylate-modified magnetic beads||
||Conjugation or direct binding applications:
||High-speed version available|
|Amine-blocked magnetic beads||
||Conjugation applications, similar to carboxylate-modified beads.||High-speed version available|
|Oligo(dT)-coated magnetic beads||
||mRNA binding applications:
|Streptavidin-coated magnetic beads||
||Immunoassay and molecular biology applications:
||High-speed version available
Biotin binding ranges:
|Streptavidin-blocked magnetic beads||
||High-specificity biotin binding applications
||High-speed version available|
|NeutrAvidin™-coated magnetic beads||
||Alternative to Streptavidin in immunoassay and molecular biology applications:
||High-speed version available
Biotin binding range:
|Protein A/G magnetic beads||
||Antibody isolation applications:
|Silica-coated magnetic beads||
||Applications with low sample amounts
||Convenient alternative to sepharose columns, with protein purification applications including:
Custom bead conjugation
Even with all these surface chemistry options, it’s impossible to cover every need and eventuality. That’s where custom conjugation comes in.
Do you need to conjugate a custom ligand? Or need a custom particle size?
At GE Healthcare Life Sciences, we make it possible to customize all our Sera-Mag magnetic beads . Our dedicated customization experts can help you every step of the way, from defining the product specifications to delivery completion.
We provide custom conjugations of enzymes or antibodies , as well as a range of custom ligands that we can develop in parallel with your projects. We also offer lyophilization of the customized microspheres as part of our Lyo-Stable services , based on Ready-To-Go stabilization technology.
Drawing on our R&D and manufacturing resources, and history of supplying magnetic beads to kit manufacturers, we will provide custom magnetic bead technology that is ready to use with little or no need for further modification. From completing complex conjugations, to performing your quality control tests before the beads leave our factory, we are equipped to meet your needs.
At GE Healthcare, we provide a broad range of magnetic beads for molecular biology applications such as NGS and PCR. Read more about optimizing your research or clinical workflows in our other blogs. For support in any aspect of your workflow, contact our Scientific Support team or your local GE Healthcare representative.