Application Notes 2

Reversed Phase

• 1: Comparison of STYROS™ 1R and 2R with a Silica C4 Stationary Phase.
• 2: Fast Protein Separation on STYROS™ 1R and 2R.
• 3: Comparison of STYROS™ 1R/XP and 1R/XH.
• 4: Separation of Angiotensin Variants at Basic pH.
• 5: High Performance Separation of Proteins on STYROS™ 1R/NB
• 6: Ultra Fast Separation of Proteins on Narrow Bore Columns.
• 25: Fast Detection of XELODA (Capecitabine) in Urine Sample with STYROS™ 2R/XH.
• 33: ADRIAMYCIN: Detection in Urine Sample with STYROS™ 2R/XH
• 35: NAVELBINE: Fast Detection in Urine Sample with STYROS™ 2R/XH.
• 40: Hydrophobic Interaction Chromatography compared with Polymeric Reversed Phase: STYROS™ HIC-Butyl versus STYROS™ 2R.
• 49: STYROS™ 3R Simulated Monolith Polymeric Reversed Phase.
• 50: STYROS™ 3R Simulated Monolith Polymeric Reversed Phase: Standard Separation of 6 Small Molecules
• 58: STYROS™ 3R Simulated Monolith™ Polymeric Reversed Phase: Loadability Study, Comparison with Silica Reversed Phases
• 91: STYROS™ 3R Simulated Monolith™ Polymeric Reversed Phase. Protein Standard Separation at High Linear Velocity
• 108: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Comparing Narrow Bore column with a standard Bore of 4.6 mm ID
• 109: STYROS® Simulated-Monolith™ Polymeric Reversed Phase. Fast convective channels of monolith to separate different size molecules in a mixture
• 110: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Separation of 5 peptides on Narrow Bore column of 2.1 mm ID. Acidic and Basic pH’s
• 111: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Separation of 5 peptides on Micro Bore column of 1 mm ID. Acidic and Basic pH’s
• 112: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Separation of 5 proteins standard on Micro Bore column of 1 mm ID. Comparison with Narrow Bore of 2.1 mm ID
• 113: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Separation of 4 proteins standard on Capillary column of 0.5 mm ID. Comparison with Micro Bore of 1 mm ID
• 114: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Separation of 4 parabens on Capillary column of 0.5 mm ID. Comparison with Micro Bore of 1 mm ID
• 115: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase: Assessment of columns from different manufacturers
• 116: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Separation of 9 Phenones on Capillary column of 0.5 mm ID
• 117: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Separation of 9 Phenones on Micro Bore column of 1 mm ID
• 118: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Separation of 9 Phenones on Narrow Bore column of 2.1 mm ID
• 119: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Use of Micro Bore column of 1 mm ID using high and low pH’s to separate Sulfa drugs and precursor
• 120: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Use of Capillary column of 0.5 mm ID using high and low pH’s to separate Sulfa drugs and precursor
• 121: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Use of Narrow Bore column of 2.1 mm ID using high and low pH’s to separate Sulfa drugs and precursor
• 122: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Use of Narrow Bore column of 2.1 mm ID using high pH’s to separate 5 Chlorophenols
• 123: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Advantages of using Narrow Bore instead of Normal Bore columns for LC separations.
• 125: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase. Advantages of using Narrow Bore instead of Normal Bore columns for LC separations.
• 126: STYROS® 2R Simulated-Monolith™ Polymeric Reversed Phase Narrow Bore: Comparison with the narrow bore column of the leading manufacturer.

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Anion Exchanger

• 7: Quality Control of Proteins of Different Lots from the Same Supplier.
• 8: Assessing Proteins Across Grades and Suppliers.
• 9: Polymeric Hard Gel Media-HPLC vs. Soft Gel-FPLC in the Separation of Biomolecules.
• 10: Fast Separation of Protein Isoforms with Fully Porous Hard Gel Media: Hemoglobins.
• 11: Polymeric Gigaporous Strong Anion Exchangers: Bead Size Distribution versus Pore Size Distribution.
• 13: High Speed Resolution: Efficient Use of Long, Narrow-bore Columns.
• 16: Polymeric Gigaporous Anion Exchanger: Throughpores versus Superficial Pores.
• 17: Polymeric Gigaporous Anion Exchanger : Performance at Low Flow Rates.
• 18: Separation of Small Molecules on STYROS™ Q/XH.
• 23: Fast Separation of IgG on STYROS™ HQ: High Capacity Polymeric Gigaporous Strong Anion Exchanger.
• 24: Fast Separation of IgG, IgA and IgM on STYROS™ DEAE/NB: Narrow Bore Weak Anion Exchanger.
• 37: Separation of Aprotinin from apo-Transferrin and Hexokinase on Polymeric Hard Gel Anion Exchange Columns.
• 38: Aprotinin Purity Test on STYROS™ Anion and Cation Exchanger. Polymeric Hard Gel Stationary Phase.
• 46: Separation of Hen Egg White Proteins: STYROS™ HQ Compared with Mono Q
• 48: Low Salt Separations on Shielded Weak Anion Exchanger: STYROS™ SWAX
• 59: Quaternary Amino Methyl (HQ) Anion Exchanger: Comparison with Mono Q
• 60: Quaternary Amino Methyl (HQ) Anion Exchanger: Beyond Mono Q
• 61: Quaternary Amino Ethyl (QAE) Anion Exchanger: Column Lenght
• 62: Quaternary Amino Ethyl (QAE) Anion Exchanger: Comparison with Quaternary Amino Methl (HQ)
• 79: STYROS™ HQ Simulated Monolith™ Polymeric: Separation of Protein Mixtures
• 80: STYROS™ HQ Simulated Monolith™ Polymeric: Loading Study
• 81: Practical Use of STYROS™ HQ Simulated Monolith™ Polymeric In the Separation of Hemoglobin Variants
• 82: Separation of Soybean Trypsin Inhibitor wiht STYROS™ HQ Simulated Monolith™ Polymeric
• 83: Practical Use of STYROS™ HQ Simulated Monolith™ Polymeric In the Separation of OVA Variants
• 84: Practical Use of STYROS™ HQ Simulated Monolith™ Polymeric In the Separation of Hemoglobin and Methemoglobin
• 85: Use of STYROS™ HQ Simulated Monolith™ Polymeric in the Quality Control of Incoming Lots
• 86: STYROS™ HQ Simulated Monolith™ Polymeric. Importance of Column Length
• 87: Practical Use of STYROS™ HPA Simulated Monolith™ Polymeric In the Separation of OVA Variants
• 88: Practical Use of STYROS™ HPA Simulated Monolith™ Polymeric In the Separation of Hemoglobin Variants
• 89: Practical Use of STYROS™ HPA Simulated Monolith™ Polymeric In the Separation of Hemoglobin and Methemoglobin
• 90: Comparison of STYROS™ HPA Anion Exchanger with STYROS™ 3R Reversed Phase In the Assessment of Commercial OVA
• 97: Separation of Pancreatin on STYROS™ HPA (High Capacity Weak Anion Exchanger): Column Length
• 98: Separation of Pancreatin on STYROS™ DEAE (Weak Anion Exchanger, Diethyaminoethyl ):Simulated-Monolith™ and Column Length
• 99: Separation of Pancreatin on STYROS™ HQ (Strong Anion Exchanger ): Simulated-Monolith™ and Column Length
• 100: Separation of Pancreatin on STYROS™ QAE (Strong Anion Exchanger ): Simulated-Monolith™ and Column Length
• 101: Separation of Pancreatin on STYROS™ Q (Strong Anion Exchanger ): Simulated-Monolith™ and Column Length
• 102: Separation of Pancreatin on STYROS™ PA (Weak Anion Exchanger ): Simulated-Monolith™ andColumn Length

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Cation Exchanger

• 12: Polymeric Gigaporous Strong Cation Exchangers: Bead Size Distribution versus Pore Size Distribution.
• 14: Polymeric Gigaporous Strong Cation Exchangers: Effect of Capacity on Protein Resolution.
• 15: Separation of IgG from Albumins in Commercial Production.
• 19: Resolving Efficiency of Longer Columns: case application with medium capacity cation exchanger.
• 22: Separation of Cytochrome c Isoform on STYROS™ SE: Strong cation exchanger.
• 38: Aprotinin Purity Test on STYROS™ Anion and Cation Exchanger. Polymeric Hard Gel Stationary Phase.
• 92: STYROS™ SP Simulated Monolith™ Strong Cation Exchangers: Loadability and Linear Velocity
• 93: STYROS™ SP Simulated Monolith™ Strong Cation Exchangers: Longer Columns for Added Resolution
• 94: STYROS™ SP Simulated Monolith™ Strong Cation Exchanger Compared to CM Simulated Monolith™ Weak Cation Exchanger
• 95: STYROS™ SP Simulated Monolith™ Strong Cation Exchanger Compared to CM Simulated Monolith™ Weak Cation Exchanger. Sequence of Protein Elution
• 96: STYROS™ Simulated-Monolith.. Choice of the Right Column.

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Affinity

• 20: Metal Chelate Liquid Chromatography on Hard Gel Gigaporous Polymeric Media: Comparison with Soft Gel.
• 21: Metal Chelate Liquid Chromatography on Hard Gel Gigaporous Polymeric Media: Tri-dentate IDA versus Five-dentate TED
• 32: Rapid isolation of IgG From Human Serum on STYROS™ rA (Immobilized Recombinant Protein A on Simulated Monolith™ Polymeric Stationary Phase).
• 34: Immobilized Protein rA on Polymeric Porous Hard Gel (STYROS™ rA): Comparison with Sepharose rA.
• 65: Quantitation of Monoclonal Antibodies with Immobilized Protein rA on Simulated Monolith™ Polymeric STYROS™
• 66: Assessing Monoclonal Antibodies (mAB) with Immobilized Protein rA on Simulated Monolith™ Polymeric STYROS™: Dynamic Capacity.

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Enzyme Columns

• 26: StyrosZyme™ TPCK-Trypsin, Immobilized Enzyme on Polymeric Hard Gel Stationary Phase: Online Digestion of Lysozyme in 5 minutes.
• 27: StyrosZyme™ TPCK-Trypsin, Immobilized Enzyme on Polymeric Hard Gel Stationary Phase: Online Digestion of Insulin Oxidized B-chain in 16 minutes.
• 28: StyrosZyme™ Pepsin, Immobilized Enzyme on Polymeric Hard Gel Stationary Phase: On line digestion of Cytochrome c From Horse Heart and Bovine Heart.
• 31: StyrosZyme™ Papain, Immobilized Enzyme on Simulated Monolith Polymeric Stationary Phase: Effect of Temperature and Linear Velocity on Online Digestion.
• 36: On Line Affinity capture of APROTININ on StyrosZyme™ TPCK-Trypsin, Immobilized Enzyme on Polymeric Hard Gel Stationary Phase.
• 39: StyrosZyme™ Pepsin. Immobilized Enzyme on Polymeric Hard Gel Stationary Phase: On line digestion at 0 °C and pH 2.5.
• 63: StyrosZyme™ Pepsin, Immobilized Enzyme on Polymeric Hard Gel Stationary Phase: On line digestion of Cytochrome c From Horse Heart and Bovine Heart. Alternative
• 64: StyrosZyme™ Pepsin, Immobilized Enzyme on Polymeric Hard Gel Stationary Phase: On line digestion of Cytochrome c and Myoglobin From Horse Heart.
• 124: StyrosZyme® Pepsin, Immobilized Enzyme on Simulated-Monolith™ Polymeric Hard Gel: Full on line digestion of a of solution of 10 µl of 10 mg/ml protein.
• 132: StyrosZyme® TPCK-Trypsin, Immobilized Enzyme on Polymeric Hard Gel Simulated-Monolith™. Automation of the Digestion and Mapping of Cytochrome c.
• 133: StyrosZyme® TPCK-Trypsin, Immobilized Enzyme on Polymeric Hard Gel Simulated-Monolith™. Effect of Different Variables on Automated Digestion.
• 134: Automated Digestion with StyrosZyme® TPCK-Trypsin, Immobilized Enzyme on Polymeric Hard Gel Simulated-Monolith™. Effect of Linear Velocity and Column Length on the Digestion of Oxidized Insulin B Chain.
• 135: Automated Digestion with StyrosZyme® TPCK-Trypsin, Immobilized Enzyme on Polymeric Hard Gel Simulated-Monolith™. Stability of the Enzyme Reactor in Yielding Reproducible Results in Automation.
• 136:Automated Digestion with StyrosZyme® TPCK-Trypsin, Immobilized Enzyme on Polymeric Hard Gel Simulated-Monolith™. Digestion and mapping of 3 µg of protein on Narrow Bore column.
• 137: Automated Digestion with StyrosZyme® TPCK-Trypsin, Immobilized Enzyme on Polymeric Hard Gel Simulated-Monolith™. Digestion and mapping of 10 µg of Lysozyme on Narrow Bore column.

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HIC (Hydrophobic Interaction Chromatography)

• 29: SIMULATED MONOLITH™: Fast Separations with HIC (Hydrophobic Interaction Chromatography)
• 30: SIMULATED MONOLITH™: Comparison With Non Covalently Coated Polymeric Hard Gel.
• 40: Hydrophobic Interaction Chromatography compared with Polymeric Reversed Phase: STYROS™ HIC-Butyl versus STYROS™ 2R.
• 41: Hydrophobic Interaction Chromatography : Comparison of STYROS™ HIC-Phenyl with Shodex HIC PH-818.
• 42: Reversed Phase Polymeric: Comparison of STYROS™ 2R with Commercial Non Porous Polymeric.
• 43: Hydrophobic Interaction Chromatography: Comparison of STYROS™ HIC-Phenyl with TSKgel Phenyl-5PW from TOSOH.
• 44: Hydrophobic Interaction Chromatography: Comparison of STYROS™ HIC-Butyl with TSKgel Butyl-NPR from TOSOH.
• 45: Hydrophobic Interaction Chromatography: Comparison of STYROS™ HIC-Ether with TSKgel Ether-5PW from TOSOH.
• 67: Hydrophobic Interaction Chromatography: Facts
• 68: Hydrophobic Interaction Chromatography: With Limited Sample.
• 69: Hydrophobic Interaction Chromatography: Desalting and Concentration
• 70: Hydrophobic Interaction Chromatography: Separation of Various Snake Venom.

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HILIC & Amino-HILIC (Hydrophylic Interaction Liquid Chromatography)

• 51: STYROS™ Amino HILIC Simulated Monolith Polymeric Normal Phase: Standard Separations.
• 52: STYROS™ Amino HILIC Simulated Monolith™ Polymeric: Separation of Benzoic Acid and Derivatives
• 53: STYROS™ Amino HILIC Simulated Monolith™ Polymeric: Effect of Ionic Strength and Temperature on the Separation of Aromatic Acids
• 54: STYROS™ Amino HILIC Simulated Monolith™ Polymeric: Separation of Angiotensins I, II and III
• 55: STYROS™ HILIC Simulated Monolith™ Polymeric Normal Phase: Standard Separations
• 56: STYROS™ HILIC Simulated Monolith Polymeric Normal Phase: Separation of Aliphatic and Aromatic Acids
• 57: STYROS™ HILIC Simulated Monolith Polymeric Normal Phase: Separation of Nucleotides
• 71: STYROS™ HILIC Simulated Monolith™ Polymeric Normal Phase: Separation of Nucleotdes Intended for MS. No Bleed
• 72: STYROS™ Amino-HILIC Simulated Monolith™ Polymeric Normal Phase: Separation of Purines and Pyrimidines Intended for MS. No Bleed
• 73: STYROS™ Amino-HILIC Simulated Monolith™ Polymeric Normal Phase: Separation of Purines and Pyrimidines on Narrow Bore Columns Intended for MS. No Bleed
• 74: STYROS™ Amino-HILIC Simulated Monolith™ Polymeric Normal Phase: Separation of Uracil and 5-Fluorouracil. Narrow Bore and Normal Bore Columns
• 75: STYROS™ Amino-HILIC Simulated Monolith™ Polymeric Normal Phase: Separation Nucleosides Intended for MS. No Bleed
• 76: STYROS™ HILIC Simulated Monolith™ Polymeric Normal Phase: Separation of Adrenaline and Noradrenaline Intended for MS. No Bleed
• 77: STYROS™ HILIC Simulated Monolith™ Polymeric Normal Phase: Separation of Dopamine and L-Dopa for MS. No Bleed
• 78: STYROS™ HILIC Simulated Monolith™ Polymeric Normal Phase: Separation of Methyladrenaline and Methyldopa Intended for MS.No Bleed

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