Thermo Scientific EASY-Spray Columns and Emitters
EASY-Spray Biochromatography Columns from Thermo Scientific
Ensure robust nano and capillary flow LC-MS with Thermo Scientific EASY-Spray LC Columns. The integrated column/emitter design eliminates dead volume and is temperature-controlled for maximum reliability and performance. Rigourously tested to ensure maximum quality, these columns are designed for simplicity and ease-of-use.
Thermo Scientific EASY-Spray columns ensure robust nano and capillary flow into your LC-MS. The integrated column/emitter design eliminates dead volume and is temperature-controlled for maximum reliability and performance. Rigorously tested to ensure maximum quality, these columns deliver maximum simplicity and ease-of-use. The capillary flow HPLC columns provide sensitive protein, peptide, and monoclonal antibody (mAb) separation. They give proteomics researchers more than ever before: more throughput, more sensitivity, more separation power, and more ease of use.
Connect your nano or capillary column to your Thermo Scientific mass spectrometers (MS) more easily using Thermo Scientific EASY-Spray nano and capillary emitters. The nano and capillary emitters act as a column-independent sprayer, allowing the introduction of low flow from nano and capillary columns without troublesome handling of traditional spray needles. There are two versions of emitters available: with and without integrated transfer lines. These sprayers are ideal for protein and peptide separation using nano and capillary HPLC.
- Integrated fused-silica emitter delivers an exceptionally stable spray
- Integrated column with temperature control provides maximum reliability and performance
- A single nanoViper connection between the HPLC column and the MS ion source eliminates dead volumes
- Uncompromised performance and ease-of-use in nano LC-MS
- Ultra-sharp peaks
- Outstanding peak capacity
- Maximized peptide coverage
- Excellent column-to-column reproducibility and reliability
- Outstanding peak capacity for comprehensive proteome characterization