Bacteria extraction


Ideal for bacteria extraction


Save Time, Effort and Get Superior Results with

Bullet Blender Homogenizer
  • Consistent Results
  • Samples Stay Cool
  • No Cross Contamination
  • Easy and Convenient
  • Risk Free
Do you spend lots of time and effort extracting bacteria from plant or animal tissue? The Bullet Blender® is a multi-sample homogenizer that delivers superior results. No other homogenizer comes close to delivering the Bullet Blender’s winning combination of top-quality performance and budget-friendly affordability.
  • Consistent and High Yield Results
    Run up to 24 samples at the same time under microprocessor-controlled conditions, ensuring experimental reproducibility and high yield. Process samples from 10mg or less up to 3.5g.
  • No Cross Contamination
    No part of the Bullet Blender® ever touches the tissue – the sample tubes are kept closed during homogenization. There are no probes to clean between samples.
  • Samples Stay Cool
    Homogenizing causes only a few degrees of heating. Our “Blue” model comes with a fan to maintain ambient temperatures.
  • Easy and Convenient to Use
    Just place beads and buffer along with your bacteria-containing sample in standard tubes, load tubes directly in the Bullet Blender, select time and speed, and press start.
  • Risk Free Purchase
    The Bullet Blender® comes with a 30 day money back guarantee and a 2 year warranty, with a 3 year warranty on the motor. The simple, reliable design enables the Bullet Blenders to sell for a fraction of the price of ultrasonic or other agitation based instruments, yet provides an easier, quicker technique.



Bullet Blender settings for Bacterial Extraction

Sample size

See the Protocol

microcentrifuge tube model (up to 300 mg) Small Organs for bacterial extraction


Selected publications for Bacterial Extraction

See all of our Bullet Blender publications!

Otwell, A. E., Callister, S. J., Zink, E. M., Smith, R. D., & Richardson, R. E. (2016). Comparative Proteomic Analysis of Desulfotomaculum reducens MI-1: Insights into the Metabolic Versatility of a Gram-Positive Sulfate- and Metal-Reducing Bacterium. Frontiers in Microbiology, 7.
Tranchemontagne, Z. R., Camire, R. B., O’Donnell, V. J., Baugh, J., & Burkholder, K. M. (2016). Staphylococcus aureus Strain USA300 Perturbs Acquisition of Lysosomal Enzymes and Requires Phagosomal Acidification for Survival inside Macrophages. Infection and Immunity, 84(1), 241–253.
Wilde, A. D., Snyder, D. J., Putnam, N. E., Valentino, M. D., Hammer, N. D., Lonergan, Z. R., Hinger, S. A., Aysanoa, E. E., Blanchard, C., Dunman, P. M., Wasserman, G. A., Chen, J., Shopsin, B., Gilmore, M. S., Skaar, E. P., & Cassat, J. E. (2015). Bacterial Hypoxic Responses Revealed as Critical Determinants of the Host-Pathogen Outcome by TnSeq Analysis of Staphylococcus aureus Invasive Infection. PLOS Pathogens, 11(12), e1005341.
Danka, E. S., & Hunstad, D. A. (2015). Cathelicidin Augments Epithelial Receptivity and Pathogenesis in Experimental Escherichia coli Cystitis. Journal of Infectious Diseases, 211(7), 1164–1173.
Merkley, E. D., Wrighton, K. C., Castelle, C. J., Anderson, B. J., Wilkins, M. J., Shah, V., Arbour, T., Brown, J. N., Singer, S. W., Smith, R. D., & Lipton, M. S. (2015). Changes in Protein Expression Across Laboratory and Field Experiments in Geobacter bemidjiensis. Journal of Proteome Research, 14(3), 1361–1375.
de la Torre, A., Metivier, A., Chu, F., Laurens, L. M. L., Beck, D. A. C., Pienkos, P. T., Lidstrom, M. E., & Kalyuzhnaya, M. G. (2015). Genome-scale metabolic reconstructions and theoretical investigation of methane conversion in Methylomicrobium buryatense strain 5G(B1). Microbial Cell Factories, 14(1).
Pekar, H., Westerberg, E., Bruno, O., Lääne, A., Persson, K. M., Sundström, L. F., & Thim, A.-M. (2015). Fast, rugged and sensitive ultra high pressure liquid chromatography tandem mass spectrometry method for analysis of cyanotoxins in raw water and drinking water—First findings of anatoxins, cylindrospermopsins and microcystin variants in Swedish source waters and infiltration ponds. Journal of Chromatography A.
Ranjan, R., Rani, A., Metwally, A., McGee, H. S., & Perkins, D. L. (2015). Analysis of the microbiome: Advantages of whole genome shotgun versus 16S amplicon sequencing. Biochemical and Biophysical Research Communications.
Sanchez-Ingunza, R., Guard, J., Morales, C. A., & Icard, A. H. (2015). Reduction of Salmonella Enteritidis in the Spleens of Hens by Bacterins That Vary in Fimbrial Protein SefD. Foodborne Pathogens and Disease, 12(10), 836–843.
Orellana, R., Hixson, K. K., Murphy, S., Mester, T., Sharma, M. L., Lipton, M. S., & Lovley, D. R. (2014). Proteome of Geobacter sulfurreducens in the presence of U(VI). Microbiology, 160(Pt_12), 2607–2617.
Lakritz, J. R., Poutahidis, T., Levkovich, T., Varian, B. J., Ibrahim, Y. M., Chatzigiagkos, A., Mirabal, S., Alm, E. J., & Erdman, S. E. (2014). Beneficial bacteria stimulate host immune cells to counteract dietary and genetic predisposition to mammary cancer in mice: Probiotic bacteria protect against mammary cancer. International Journal of Cancer, 135(3), 529–540.
Amidan, B. G., Orton, D. J., LaMarche, B. L., Monroe, M. E., Moore, R. J., Venzin, A. M., Smith, R. D., Sego, L. H., Tardiff, M. F., & Payne, S. H. (2014). Signatures for Mass Spectrometry Data Quality. Journal of Proteome Research, 13(4), 2215–2222.
Scherr, T. D., Lindgren, K. E., Schaeffer, C. R., Hanke, M. L., Hartman, C. W., & Kielian, T. (2014). Mouse Model of Post-arthroplasty Staphylococcus epidermidis Joint Infection. In P. D. Fey (Ed.), Staphylococcus Epidermidis (Vol. 1106, pp. 173–181). Humana Press.
Tong, K., Zhang, Y., Liu, G., Ye, Z., & Chu, P. K. (2013). Treatment of heavy oil wastewater by a conventional activated sludge process coupled with an immobilized biological filter. International Biodeterioration & Biodegradation, 84, 65–71.
Nicora, C. D., Anderson, B. J., Callister, S. J., Norbeck, A. D., Purvine, S. O., Jansson, J. K., Mason, O. U., David, M. M., Jurelevicius, D., Smith, R. D., & Lipton, M. S. (2013). Amino acid treatment enhances protein recovery from sediment and soils for metaproteomic studies. PROTEOMICS, n/a-n/a.
Liu, G., Ye, Z., Tong, K., & Zhang, Y. (2013). Biotreatment of heavy oil wastewater by combined upflow anaerobic sludge blanket and immobilized biological aerated filter in a pilot-scale test. Biochemical Engineering Journal, 72, 48–53.
Diaz-Campos, D. V. (2012). Molecular Epidemiology and Genetic Analysis of Staphylococcus species in Companion Animal Medicine. Auburn University.
Hanke, M. L., Angle, A., & Kielian, T. (2012). MyD88-Dependent Signaling Influences Fibrosis and Alternative Macrophage Activation during Staphylococcus aureus Biofilm Infection. PLoS ONE, 7(8), e42476.
Kim, J. E., Eom, H.-J., Kim, Y., Ahn, J. E., Kim, J. H., & Han, N. S. (2012). Enhancing acid tolerance of Leuconostoc mesenteroides with glutathione. Biotechnology Letters, 34(4), 683–687.
Thai, K. H., Thathireddy, A., & Hsieh, M. H. (2010). Transurethral Induction of Mouse Urinary Tract Infection. Journal of Visualized Experiments, 42.

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