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Amine modified magnetic beads (PuriMag G-NH2 beads)

2025/6/16 viewers
  • BrandPuriMag
  • TypePuriMag G Series
  • order
Introduction

Ordering information

Name

Cat. No.

Vol.

Scheme

GS-NH2

5 C spacer

PMG005-2

PMG005-5

2ml 

5ml

GL-NH2

15 C spacer

PMG006-2

PMG006-5

2ml 

5ml


1. Overview

PuriMag? G-NH?, Amino-Functionalized Magnetic Nanoparticles are uniform, polymer-coated superparamagnetic nanoparticles featuring a surface coated with a high density of amino functional groups. Their hydrophilic surface ensures excellent dispersibility, low non-specific adsorption, and easy handling in various buffers.

The reactive surface amines enable immobilization of ligands such as proteins, peptides, carbohydrates, or other specific molecules. Ligand attachment can be achieved via:

  • Reductive amination with aldehydes/ketones without pre-activating the bead surface, or

  • EDC-mediated crosslinking for ligands containing carboxyl groups.

PuriMag? G-NH? beads can be coupled to peptides, enzymes, carbohydrates, etc., to isolate diverse targets including hormones, receptors, lectins, disease markers, and bacteriophages.

Workflow:

        Incubate ligand-conjugated beads with target molecule samples.

        Affinity-capture targets via short incubation.

        Magnetically separate and remove supernatant.

        Wash target-bound beads to obtain purified samples.

        Captured targets can be directly used in bioassays or analyzed via SDS-PAGE.

2. product description

Product Specifications

Description

Polymer coated Fe3O4 nanoparticles

Particle Size

200 nm

Number of Beads

~1.7×1010 beads/mg

Matrix

Proprietary polymer

Functional group

Amine group

Group density

~300 μmole / g of Beads

Magnetization

60~70 EMU/g

Formulation

10 mg/ml suspension in DI water

Stability

pH 3.5~10, 4~80 , most organic solvents

Storage

1 year at 2~8 . Do not freeze.

3. Instructions for Use

Washing PuriMag? Amino Beads:

        1.Resuspend beads and transfer required amount to a clean microcentrifuge tube.

        2.Separate magnetically, remove supernatant.

        3.Add 200 μL coupling buffer, resuspend beads.

        4.Separate magnetically, remove supernatant.

        5.Repeat wash twice.

Protocol 1: Coupling Aldehydes/Ketones (Reductive Amination)

Ligands with aldehydes/ketones form Schiff's bases with amino beads, reduced by sodium cyanoborohydride.

Buffers:

    Coupling Buffer: 0.1 M Sodium Phosphate + 0.15 M NaCl or 100 mM Sodium Borate pH 9.5 or 100 mM Sodium Citrate pH 9.5

    Reducing Agent: 5 M Sodium Cyanoborohydride in 1 M NaOH

    Quenching Buffer: 0.1 M Ethanolamine, pH 7.4

Procedure:

        1.Dissolve ligand in coupling buffer (1–10 mg/mL).

        2.Add ligand to washed beads. Mix.

        3.Add 1 μL 5M NaCNBH? per 100 μL reaction mix. Incubate 2 h at RT. Separate, discard supernatant.

        4.Add equal volume quenching buffer. Incubate 15 min at RT. Separate, discard supernatant.

        5.Wash 3× with PBS.

Protocol 2: Activation with NHS Crosslinkers

NHS esters react with amines, thiols, carboxyls, hydroxyls, or via photoactivation. Use 10× molar excess crosslinker.

Buffers:

        Coupling Buffer: 0.1 M Sodium Phosphate + 0.15 M NaCl, pH 7.4

        Quenching Buffer: 0.05 M Tris, pH 7.0

Bead Activation:

        1.Resuspend beads in coupling buffer.

                *Avoid amine-containing buffers (Tris, glycine).*

        2.Add freshly prepared NHS crosslinker solution. Mix.

        3.Incubate 30 min at RT. Separate, discard supernatant. Wash  with coupling buffer.

Protocol 2-1: Coupling NH?-Reactive NHS-Esters
For peptides/proteins via N-terminus.

        1.Resuspend activated beads. Adjust concentration.

        2.Add calculated ligand amount. Mix.

        3.Incubate: 30 min RT or 2 h at 4°C.

        4.Separate, discard supernatant.

        5.Quench with 0.05 M Tris (pH 7.0), 15 min RT.

        6.Wash  with coupling buffer.

Protocol 2-2: Coupling SH-Reactive NHS-Esters
For thiol-containing ligands (pyridyldithiol, iodo/bromoacetyl, maleimide).

        1.Resuspend activated beads in thiol-appropriate buffer.

        2.Add free thiol ligand. Vortex.

        3.Incubate per manufacturer’s time/temperature.

        4.Quench with 5 mM cysteine, 15 min RT (optional).

        5.Wash beads.

SH-reactive group

Recommended buffer

Recommended condition

Maleimide

0.1M sodium phosphate pH 6.5-7.5

4 h at 4 or 2 h at room temp

Iodo/Bromoacetyl

0.05M sodium borate pH8.3

1h, room temp. Protect from light.

Pyridyldithio

Phosphate buffered saline (PBS) pH7.5

Over night at room temp

Protocol 2-3: Coupling Photo-Reactive NHS-Esters

For aryl azides (hydroxyphenyl, nitrophenyl, perfluorophenyl). Perform in dark.

        1.Resuspend activated beads. Adjust concentration.

        2.Add ligand. Mix.

        3.Irradiate with specified wavelength/time/temp.

        4.Optimize: Beads may quench light.

        5.Wash .

             *Note: Activation/coupling in dry organic solvents (e.g., DMF) reduces hydrolysis. Wash with water before transferring to aqueous buffers.*

Protocol 3: Coupling Carboxyl Ligands Using Amine/Carboxyl-Reactive Crosslinkers

When the ligand contains no other primary amines, EDC or EDC/NHS (or other carbodiimides) can couple carboxyl groups on the ligand to amines on the bead surface. EDC reacts with carboxyl groups to form an amine-reactive intermediate, which is unstable in aqueous solutions. NHS is introduced to stabilize this intermediate.

Buffers:

        Coupling Buffer: 0.1 M MES, 0.5 M NaCl, pH 6.0

        Reagents: 1-Ethyl-3-(3-dimethylaminopropyl) carbodiimide hydrochloride (EDC); Sulfo-NHS or N-hydroxysuccinimide (NHS)

        Blocking Buffer: 50 mM Tris, pH 8.0 or 5–10 mM Hydroxylamine

        Wash Buffer: PBS (pH 7.4)

        Note: For EDC coupling, avoid buffers containing free amines or phosphates (e.g., Tris, acetate, glycine), as they reduce efficiency. Thiol-containing buffers irreversibly bind EDC and inhibit coupling.

Procedure for Carboxyl Ligand Coupling:

        1.Wash PuriMag? beads with 0.1 M MES, pH 4.5–5 or 0.1 M MES + 0.5 M NaCl, pH 6.0. Separate magnetically, discard supernatant.

        2.Dissolve ligand in the same coupling buffer (1–10 mg/mL). Add the recommended amount to beads. Mix by pipetting.

        3.Prepare fresh:

                10 mg EDC + 15 mg NHS per mL cold deionized water

                10 mg EDC in 1 mL cold deionized water 

                Keep solutions on ice, protected from light.

        4.Add 50–100 μL EDC (or EDC/NHS) solution per mg ligand. Vortex.

        5.Incubate 2 h at RT or 2 h at 4°C.

Bead Blocking:

        1.Resuspend beads in 500 μL blocking buffer. Incubate 30 min at RT.

        2.Separate magnetically, discard supernatant.

        3.Repeat blocking step (Steps 1–2).

        4.Wash beads 2× with 500 μL PBS (pH 7.4).

        5.Resuspend in 100 μL PBS (pH 7.4). Store at 4°C.

Protocol 4: Protein or Amine Ligand Coupling via Glutaraldehyde-Activated Beads

1. Bead Activation:
a) Transfer 0.1 mL magnetic beads (10 mg/mL) to a 2 mL microcentrifuge tube. Perform magnetic separation. Wash 3× with 1 mL PBS (0.02 M, pH 7.0).
b) Disperse beads in 1 mL PBS (0.02 M, pH 7.0). Add 0.05 mL of 25% (w/v) glutaraldehyde solution. Activate at 25°C for 12 h.
c) Perform magnetic separation. Wash 3× with 1 mL PBS (0.02 M, pH 7.0) using ultrasonication to remove residual glutaraldehyde. Resuspend activated beads in 1 mL PBS (0.02 M, pH 7.0) to achieve 1 mg/mL bead suspension.

2. Protein Immobilization:
a) Transfer 1 mL activated beads (1 mg/mL) to a 2 mL tube. Add 0.1 mL target protein (~4 mg/mL). React with rotation at 25°C for 4 h.
b) Perform magnetic separation, discard supernatant. Wash 3× with 1 mL PBS (0.02 M, pH 7.0).
c) Disperse immobilized protein in 5 mL PBS (0.02 M, pH 7.0) to achieve 1 mg/mL concentration. Store at 4°C.

Note: The PBS buffer used in reactions and storage may be substituted with any buffer that maintains optimal activity of the target protein, provided its concentration remains consistent.


Appendix: Immobilization of Carboxyl-Containing Small Molecules onto Amino Beads in Organic Phase (NHS Method)

For screening purposes, initial optimization of ligand loading density on the beads is essential. Varying ligand concentration allows control over immobilization density. This protocol demonstrates ligand immobilization at four concentrations (0 mM, 0.4 mM, 2 mM, and 10 mM).

1. Materials

1.1 Beads & Ligand
    PuriMag? G-NH? Beads: 10 mg (Functional group density: ~200 nmol/mg)
    Ligand: ~5 mg

1.2 Reagents
    N,N-Dimethylformamide (DMF): 25 mL
    N-Hydroxysuccinimide (HOSu), M.W. 115.09: 5 mg
    1-Ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC), M.W. 155.24: 5 mg
    Triethylamine: 200 μL
    Acetic anhydride, M.W. 102.09: 80 μL
    Methanol (MeOH): 5 mL

1.3 Equipment
    Centrifuge, Vortex Mixer, Rotating Mixer, Ultrasonic Disperser, Magnetic Stand

2. Method
2.1 Mechanism



2.2 Procedure

    1.Dissolve ligand in DMF to prepare 500 μL of 20 mM solution (final concentration: 10 mM).

    2.Prepare 100 μL of 200 mM NHS solution in DMF.

    3.Prepare 100 μL of 200 mM EDC solution in DMF.

    4.Mix:

        400 μL DMF

        50 μL 200 mM NHS

        50 μL 200 mM EDC

        500 μL ligand solution (20 mM)

        Vortex at RT for 2 h (equimolar reaction).

20 mM ligand (compound) (μL)

500 (10μmol)

200mM succinimide (μL)

50 (10μmol)

200mM EDC (μL)

50 (10μmol)

DMF (μL)

400

Total (μL)

1000

    5.Aliquot 2.5 mg NH? beads into four 1.5 mL centrifuge tubes.

    6.Magnetically separate at RT, discard supernatant.

    7.Add 500 μL DMF, disperse beads ultrasonically.

    8.Magnetically separate at RT, discard supernatant.

    9.Repeat Steps 7–8 twice (total 3 washes).

    10.Add DMF to each tube for dilution.

    11.Add activated ligand solution (10 mM final), disperse ultrasonically.

        *Note: Add ligand solution after DMF to prevent localized high concentration.*

    12.Incubate with vortex mixing at RT for 16–20 h.

Concentration (mM)

0

0.4

2

10

NH2 beads (mg)

2.5

2.5

2.5

2.5

DMFμL

500

480

400

0

Activated 10 mM ligand (μL)

0

20

100

500

Total (μL)

500

500

500

500

    13.Magnetically separate at RT, discard supernatant.

    14.Add 500 μL DMF, disperse ultrasonically.

    15.Magnetically separate at RT, discard supernatant.

    16.Repeat Steps 14–15 twice (total 3 washes).

    17.Resuspend in 430 μL DMF via ultrasonication.

    18.Add 50 μL triethylamine + 20 μL acetic anhydride (0.2 mmol).

    19.Vortex at RT for 2 h (blocks unreacted amines).

    20.Magnetically separate at RT, discard supernatant.

    21.Add 500 μL DMF, disperse ultrasonically.

    22.Magnetically separate at RT, discard supernatant.

    23.Repeat Steps 21–22 twice (total 3 washes).

        If ligand contains OH groups (risk of acetylation):Deacetylate in 500 μL 0.1 M NaOH, 30 min RT.Wash 3× with 500 μL ultrapure water (centrifugation/ultrasonication).

    24.Add 500 μL 50% MeOH, disperse ultrasonically.

    25.Magnetically separate at RT, discard supernatant.

    26.Repeat Steps 24–25 twice (total 3 washes).

    27Resuspend in 100 μL 50% MeOH. Store at 4°C.

        *Ligand-immobilized bead concentration: 0.5 mg/20 μL*




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