BioHPLC Column Selection Guide Cover - Agilent Technologies

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Appendices PLRP-S Citations (Continued) PL-SAX Citations Hudak, J., Yu, H. & Bertozzi, C. (2011) Protein Glycoengineering Enabled by the Versatile Synthesis of Aminooxy Glycans and the Genetically Encoded Aldehyde Tag. Journal of the American Chemical Society, 133(40): 16127-16135 Schneider, N. et al. (20111) Prevalence and stability of lysozyme in cheese. Food Chemistry, 128(1): 145-151 Yan, B. & Boyd, D. (2011) Breaking the Light and Heavy Chain Linkage of Human Immunoglobulin G1 (IgG1) by Radical Reactions. The Journal of Biological Chemistry, 286: 24674-24684 Landau, M. et al. (2011) Towards a Pharmacophore for Amyloid. PLoS Biology, 9(6): e1001080 Kerkaert, B. et al. (2011) Use of lysozyme as an indicator of protein cross-contact in fresh-cut vegetables via wash waters. Food Research International, 45(1): 39-44 Schneider, N., Werkmeister, K. & Pischetsrieder, M. (2011) Analysis of nisin A, nisin Z and their degradation products by LCMS/MS. Food Chemistry, 127(2): 847-854 Quenee, L. et al. (2011) Prevention of pneumonic plague in mice, rats, guinea pigs and non-human primates with clinical grade rV10, rV10-2 or F1-V vaccines. Vaccine, 29(38): 6572-6583 152 www.agilent.com/chem/biohplc Pratto, F. et al. (2008) Streptococcus pyogenes pSM19035 requires dynamic assembly of ATP-bound ParA and ParB on parS DNA during plasmid segregation. Nucleic Acids Research, 3 (11): 3676-3689 Sendovski, M. et al. (2010) Crystallization and preliminary X-ray crystallographic analysis of a bacterial tyrosinase from Bacillus megaterium. Acta Crystallographica, 66(9): 1101-1103 Bunger, MK. et al. (2008) Automated Proteomics of E. coli via Top-Down Electron-Transfer Dissociation Mass Spectrometry. Analytical Chemistry, 80(5): 1459-1467 Vantourout, P. et al. (2009) Specific Requirements for Vγ9Vδ2 T Cell Stimulation by a Natural Adenylated Phosphoantigen. The Journal of Immunology, 183(6): 3848-3857 Scaboo, AM. et al. (2009) Confirmation of Molecular Markers and Agronomic Traits Associated with Seed Phytate Content in Two Soybean RIL Populations. Crop Science, 49(2): 426-432 PL-SCX Citations Zhang, W. & Czupryn, M. (2003) Analysis of isoaspartate in a recombinant monoclonal antibody and its charge isoforms. Journal of Pharmaceutical and Biomedical Analysis, 30(5): 1479-1490 Collinge, J. et al. (2005) Differential Proteomics via Probabilistic Peptide Identification Scores. Analytical Chemistry, 77(2): 596-606 Schönleben, S. et al. (2007) Proteome analysis of Apis mellifera royal jelly. Analytical and Bioanalytical Chemistry, 389(4): 1087-1093 Lohaus, C. et al. (2007) Multidimensional Chromatography: a Powerful Tool for the Analysis of Membrane Proteins in Mouse Brain. Journal of Proteome Research, 6(1): 105-113 Zahedi, RP. et al. (2007) Phosphoproteome of Resting Human Platelets. Journal of Proteome Research, 7(2): 526-534 Boehm, A. et al. (2007) Precise protein quantification based on peptide quantification using iTRAQ. BMC Bioinformatics, 8: 214 Heller, M. et al. (2003) Trypsin catalyzed 16O-to- 18O exchange for comparative proteomics: tandem mass spectrometry comparison using MALDI-TOF, ESI-QTOF, and ESI-ion trap mass spectrometers. Journal of the American Society for Mass Spectrometry, 14(7): 704-718
<strong>Agilent</strong> 1260 Infinity Bio-inert Quaternary LC Infinitely Better for Biomolecule Analysis Proteins are susceptible to many interactions during analysis, so use the <strong>Agilent</strong> 1260 Infinity Bio-inert Quaternary LC for a completely interference-free flow path with your biochromatography. The pump head and mixing devices are titanium based which means no corrosion will occur. The autosampler is completely metal-free, as well as the capillaries, connections, detector flow cells and heating elements. The pH range extends to pH 13, active sealwash is included, and also low-pressure applications are possible. You can expand the capability of your 1260 Bio-inert system by adding optional extras. When you want to purify your target protein the bio-inert fraction collector can be used for flows up to 10 mL/min, with a cooling option and sophisticated peak trigger options. The manual injector is ideal for larger volume injections. Bio-inert flow cells are avaliable for diode array detectors, multi-wavelength detectors and fluorescence detectors. Learn more at www.agilent.com/chem/bio-inert
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Agilent BioHPLC Column Selection Gu
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BIOCOLUMN SELECTION GUIDELINES From
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Column Selection Flow Chart Biocolu
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Protein Column Selection Guide Appl
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Separation of charge variants of hu
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Increased resolution for peptide ma
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Preparative scale purification of L
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DNA and RNA Oligonucleotide Column
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Broad Distribution Biomolecules Car
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ReveRseD-PHase HPLC Confidently per
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Sterically Protected 300StableBond
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Improved reproducibility of monoclo
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Short-chain ZORBAX 300SB-C3 is stab
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ZORBAX 300Å StableBond Hardware De
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LC/MS analysis of angiotensin on Ex
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Tips & Tools ZORBAX 300Å Extend-C1
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Poroshell 300 columns separate prot
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Monoclonal IgG1 chains: Separation
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Poroshell 120 • 120Å pore size f
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0 µm 0 µm 0 µm A B C Scanning el
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Exploiting chemical stability - TFA
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Temperature as a tool to enhance ma
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ZORBaX amino acid analysis (aaa) Co
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High resolution of 24 amino acids u
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Ion-Exchange Column Selection Appli
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Consistent ion-exchange MAb separat
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Column Specifications Tips & Tools
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Weak cation-exchange chromatography
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PL-SAX Strong Anion-Exchange Column
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Analysis of representative whey pro
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Standard protein separation Column:
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Agilent Bio-Monolith HPLC Column Se
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Baseline expansion of a separation
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size exclusion Chromatography (seC)
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Column Specifications Agilent Bio S
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Comparison of Agilent Bio SEC-3 and
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Column Length size exclusion Chroma
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Column Specifications Agilent Bio S
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Calibration curves - Bio SEC-5 Colu
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ProSEC 300S • Mechanically robust
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Overlay of UV and light scattering
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Retention volume versus log (MW) fo
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Agilent PL aquagel-OH SEC Columns f
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Heparin Column: 2 x PL aquagel-OH 3
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Polyethylene Glycol/Oxide standards
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aFFiniTY CHROMaTOGRaPHY Agilent Bio
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Rapid human polyclonal IgG quantifi
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Multiple Affinity Removal System af
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Illustration of high abundance prot
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mRP-C18 High-Recovery Protein Colum
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MeTHOD DeveLOPMenT ZORBAX Column Me
Page 103 and 104: Reversed-Phase LC/MS Methods Method
Page 105 and 106: Method Development Ionic Strength:
Page 107 and 108: Method Development After the initia
Page 109 and 110: Tips & Tools Agilent offers a varie
Page 111 and 112: Human serum: Low abundance protein
Page 113 and 114: 2-D LC/MS Analyses Using ZORBAX Cap
Page 115 and 116: ZORBAX Bio-SCX Series II Capillary
Page 117 and 118: ZORBAX HPLC Capillary Columns (glas
Page 119 and 120: Microbore HPLC for sensitive peptid
Page 121 and 122: BioPharmaceutical Lifecycle Reverse
Page 123 and 124: ZORBAX 300Å StableBond ZORBAX Prep
Page 125 and 126: PLRP-S Prep to Process Application
Page 127 and 128: Prep to Process PLRP-S Size (mm) Pa
Page 129 and 130: PL-SAX AND PL-SCX FOR PREP TO PROCE
Page 131 and 132: Prep to Process PL-SAX and PL-SCX D
Page 133 and 134: Crude peptide screen Column: VariTi
Page 135 and 136: CARTRIDGE COLUMN SYSTEMS Cartridge
Page 137 and 138: USP DESIGNATIONS - BIOHPLC COLUMNS
Page 139 and 140: BioHPLC Columns Literature Title Ag
Page 141 and 142: BioHPLC Columns Literature Title An
Page 143 and 144: BioHPLC Columns Literature Title Co
Page 145 and 146: BIOPHARM DEFINITIONS A active start
Page 147 and 148: dimer A polymer made up of two iden
Page 149 and 150: K-L ligase An enzyme that causes mo
Page 151 and 152: S secondary structure In proteins,
Page 153: Poroshell 300 Citations Matilainen,
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