Streptavidin

micromer®-M-Partikel sind erhältlich mit kovalent gebundenem Streptavidin auf der Oberfläche im Größenbereich von 2 µm bis 10 µm. Streptavidin bindet biotinylierte Moleküle einfach und mit hoher Affinität. Die Streptavidin-beschichteten Partikel werden als Suspension in PBS-Puffer (pH=7,4) mit 0,02 % Natriumazid geliefert.
Steptavidin- oder Avidin-beschichtete micromer®-M-Partikel wurden umfangreich zur Entwicklung von Biosensoren und entsprechenden Immunoassays verwendet (Graham et al., 2003; Ferreira et al., 2003; Lagae et al., 2005; Wirix-Speetjens et al., 2006; Liu et al., 2007; Svedlindh et al., 2010).

Zeigt alle 8 Ergebnisse

Referenzen
  • Banerjee, S., Seul, M., and Li, A.X., Arrays of magnetic particles, US 0272049, 2005;
  • Chandramohanadas, R., Park, Y., Lui, L., Li, A., Quinn, D., Liew, K., Diez-Silva, M., Sung, Y., Dao, M., and Lim, C.T., Biophysics of malarial parasite exit from infected erythrocytes, PloS one, 2011, 6(6), e20869;
  • Ferreira, H., Graham, D., Freitas, P., and Cabral, J., Biodetection using magnetically labeled biomolecules and arrays of spin valve sensors, Journal of Applied Physics, 2003, 93(10), 7281-6;
  • Graham, D., Ferreira, H., Bernardo, J., Freitas, P., and Cabral, J., Single magnetic microsphere placement and detection on-chip using current line designs with integrated spin valve sensors: Biotechnological applications, Journal of Applied Physics, 2002, 91(10), 7786-8;
  • Graham, D.L., Ferreira, H.A., and Freitas, P.P., Magnetoresistive-based biosensors and biochips, Trends in Biotechnology, 2004, 22(9), 455-62;
  • Graham, D.L., Ferreira, H.A., Freitas, P.P., and Cabral, J.M.S., High sensitivity detection of molecular recognition using magnetically labelled biomolecules and magnetoresistive sensors, Biosensors and Bioelectronics, 2003, 18(4), 483-8;
  • Lagae, L., Wirix-Speetjens, R., Das, J., Graham, D., Ferreira, H., Freitas, P., Borghs, G., and De Boeck, J., On-chip manipulation and magnetization assessment of magnetic bead ensembles by integrated spin-valve sensors, Journal of Applied Physics, 2002, 91(10), 7445-7;
  • Lagae, L., Wirix-Speetjens, R., Liu, C.-X., Laureyn, W., Borghs, G., Harvey, S., Galvin, P., Ferreira, H., Graham, D., and Freitas, P., Magnetic biosensors for genetic screening of cystic fibrosis, IEE Proceedings-Circuits, Devices and Systems, 2005, 152(4), 393-400;
  • Liu, C., Lagae, L., Wirix-Speetjens, R., and Borghs, G., On-chip separation of magnetic particles with different magnetophoretic mobilities, Journal of applied physics, 2007, 101(2), 024913;
  • Liu, C., Stakenborg, T., Peeters, S., and Lagae, L., Cell manipulation with magnetic particles toward microfluidic cytometry, Journal of Applied Physics, 2009, 105(10), 102014;
  • Liu, Y., Jin, W., Yang, Y., and Wang, Z., Micromagnetic simulation for detection of a single magnetic microbead or nanobead by spin-valve sensors, Journal of applied physics, 2006, 99(8), 08G102;
  • Llandro, J., Palfreyman, J.J., Ionescu, A., and Barnes, C.H.W., Magnetic biosensor technologies for medical applications: a review, Med Biol Eng Comput, 2010, 48, 977-98 (81);
  • Murthy, S.S., Dulgartulloch, A.J., Bray, W.J., Chandrasekaran, S., and Tiwari, A.K., High throughput magnetic isolation technique and device for biological materials, US 0024331, 2011;
  • Skottrup, P.D., Fought Hansen, M., Moresco Lange, J., Deryabina, M., Svendsen, W.E., Havsteen Jakobsen, M., and Dufva, M., Superparamagnetic bead interactions with functionalized surfaces characterized by an immunomicroarray, Acta Biomater, 2010, 6, 3936-46;
  • Svedlindh, P., Gunnarsson, K., Strömberg, M., and Oscarsson, S., Bionanomagnetism, Nanomagnetism And Spintronics: Fabrication, Materials, Characterization And Applications, 2010;
  • Wirix-Speetjens, R., Magnetoresistive biosensors based on manipulation and detection of magnetic particles, University Leuven, 2006;