Provided is a high-loading and alkali-resistant protein A magnetic bead. The magnetic bead can maintain chemical stability under pH 2-14 and has an immunoglobulin G (IgG) binding capacity greater than 50 mg/mL. Further provided is a method for purifying and/or detecting an immunoglobulin, comprising a step of contacting a sample containing the immunoglobulin with the high-loading and alkali-resistant protein A magnetic bead. The alkali-resistant protein A magnetic bead can realize rapid purification of immunoglobulin, saving about 80% of treatment time and reducing total purification costs by 50%. In addition, the alkali-resistant protein A magnetic bead has high alkali resistance. An alkaline method for in situ cleaning can be performed to regenerate the magnetic bead after use. The magnetic bead has rapid magnetic response and good dispersiveness, realizing rapid magnetic bead enrichment, cleaning, and elution. The magnetic bead facilitates automated, high-throughput, and large volume purification of a sample.

Coated Ferromagnetic Density Particles or Density Particles with binding agents bound thereto capable of binding biological molecules and methods of use and apparatus for means are disclosed. Coated particles coupled to specific binding agents can be used for molecular biology and proteomic applications in research and diagnostics.

The present invention relates to compositions comprising magnetic particles, the methods of using these compositions in processing animal sperm, the resulting sperm and embryo products, and the methods of use of these compositions to increase the efficiency, efficacy and/or speed of cell processing and artificial insemination techniques.

Devices and methods for analysing extracellular vesicle glycans are described. According to an embodiment, a microfluidic device comprises an inlet portion configured to receive a fluid sample; a mixing portion fluidically coupled to the inlet portion and configured to facilitate mixing between the fluid sample and magnetic nanoparticles functionalized to bind with extracellular vesicles and aggregate to vesicle glycans in the fluid sample; a magnetic separation portion fluidically coupled to the mixing portion and configured to separate clusters of magnetic nanoparticles from the fluid sample; and a magnetic sensor configured to measure magnetic properties of the fluid sample after it has passed through the magnetic separation portion. The magnetic nanoparticles may configured to aggregate in the presence of respective lectins when bound with extracellular vesicles carrying target glycans. In a specific embodiment, the magnetic particles comprise a magnetic polycore coated with polydopamine.

A method for cellular separation, including: combining sperm with magnetic particles comprising a negative zeta potential charge to form an admixture, each magnetic particle being no greater than 1,000 nm; binding a subpopulation of said sperm to said magnetic particles through an electrical charge interaction to provide a bound subpopulation; and magnetically separating said bound subpopulation from unbound sperm.

A biomagnetic microsphere and a preparation method and a method for protein isolation and purification therefor. The outer surface of a magnetic microsphere body of the biomagnetic microsphere has at least one liner polymer with a branched chain; one end of the linear polymer with a branched chain is covalently coupled to the outer surface of the magnetic microsphere body, and other parts are free on the outer surface of the magnetic microsphere body; a backbone of the linear polymer is a polyolefin backbone, and no cross-linking agent is required in the backbone forming process of the linear polymer. The prepared biomagnetic microsphere can implement efficient elution of target proteins and effectively reduce the retention time and retention ratio of the target proteins, and it is easy to operate and widely used.

The present disclosure in some aspects provides methods for the controlled merging of emulsion droplets, which can be used to assemble useful compositions such as droplets (e.g., stabilized micelles) containing a precise combination of analytes and/or analytical reagents. In some embodiments, disclosed herein is a method, e.g., for detecting the presence/absence, a level or amount, and/or an activity of an analyte in a sample, comprising merging two or more emulsion droplets such that an interaction between an analyte and an analyte-interacting reagent occurs in the merged droplet. The two or more emulsion droplets may be merged using a method for the controlled merging of emulsion droplets disclosed herein.

The present invention relates to compositions comprising magnetic particles, the methods of using these compositions in processing animal sperm, the resulting sperm and embryo products, and the methods of use of these compositions to increase the efficiency, efficacy and/or speed of cell processing and artificial insemination techniques.

A method for magnetic cellular manipulation may include contacting a composition with a biological sample to form a mixture. The composition may include a plurality of particles. Each particle in the plurality of particles may include a magnetic substrate. The magnetic substrate may be characterized by a magnetic susceptibility greater than zero. The composition may also include a chargeable silicon-containing compound. The chargeable silicon-containing compound may coat at least a portion of the magnetic substrate. The biological sample may include cells and/or cellular structures. The method may also include applying a magnetic field to the mixture to manipulate the composition.

Provided in the present invention are a magnetic nanosphere coated with modified cardiolipin, and manufacturing method thereof. The magnetic nanosphere coated with modified cardiolipin comprises a modified cardiolipin, a biotin derivative, and a streptavidin magnetic bead. The modified cardiolipin is coupled to the biotin derivative via an —NH—CO structure. The streptavidin magnetic bead is a magnetic nanosphere coupled to streptavidin, and the biotin derivative is coupled to the streptavidin.