phosphopeptide elution Search Results


phosphopeptide elution  (Hamilton Company)
98
Hamilton Company phosphopeptide elution
The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and <t>phosphopeptide</t> enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.
Phosphopeptide Elution, supplied by Hamilton Company, used in various techniques. Bioz Stars score: 98/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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Average 98 stars, based on 1 article reviews
phosphopeptide elution - by Bioz Stars, 2026-04
98/100 stars
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c18 stagetip  (Thermo Fisher)
90
Thermo Fisher c18 stagetip
The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and <t>phosphopeptide</t> enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.
C18 Stagetip, supplied by Thermo Fisher, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/c18 stagetip/product/Thermo Fisher
Average 90 stars, based on 1 article reviews
c18 stagetip - by Bioz Stars, 2026-04
90/100 stars
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sequential elution from imac—simac  (SIMAC Electronics)
90
SIMAC Electronics sequential elution from imac—simac
The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and <t>phosphopeptide</t> enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.
Sequential Elution From Imac—Simac, supplied by SIMAC Electronics, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/sequential elution from imac—simac/product/SIMAC Electronics
Average 90 stars, based on 1 article reviews
sequential elution from imac—simac - by Bioz Stars, 2026-04
90/100 stars
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phosphopeptide elution  (Eppendorf AG)
95
Eppendorf AG phosphopeptide elution
The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and <t>phosphopeptide</t> enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.
Phosphopeptide Elution, supplied by Eppendorf AG, used in various techniques. Bioz Stars score: 95/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/phosphopeptide elution/product/Eppendorf AG
Average 95 stars, based on 1 article reviews
phosphopeptide elution - by Bioz Stars, 2026-04
95/100 stars
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c18 spin tips  (Thermo Fisher)
90
Thermo Fisher c18 spin tips
The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and <t>phosphopeptide</t> enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.
C18 Spin Tips, supplied by Thermo Fisher, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/c18 spin tips/product/Thermo Fisher
Average 90 stars, based on 1 article reviews
c18 spin tips - by Bioz Stars, 2026-04
90/100 stars
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lobind eppendorf tube  (Eppendorf AG)
99
Eppendorf AG lobind eppendorf tube
The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and <t>phosphopeptide</t> enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.
Lobind Eppendorf Tube, supplied by Eppendorf AG, used in various techniques. Bioz Stars score: 99/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/lobind eppendorf tube/product/Eppendorf AG
Average 99 stars, based on 1 article reviews
lobind eppendorf tube - by Bioz Stars, 2026-04
99/100 stars
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nano elute hplc system  (Bruker Corporation)
90
Bruker Corporation nano elute hplc system
The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and <t>phosphopeptide</t> enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.
Nano Elute Hplc System, supplied by Bruker Corporation, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/nano elute hplc system/product/Bruker Corporation
Average 90 stars, based on 1 article reviews
nano elute hplc system - by Bioz Stars, 2026-04
90/100 stars
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hplc system bruker nano elute  (Bruker Corporation)
90
Bruker Corporation hplc system bruker nano elute
The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and <t>phosphopeptide</t> enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.
Hplc System Bruker Nano Elute, supplied by Bruker Corporation, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/hplc system bruker nano elute/product/Bruker Corporation
Average 90 stars, based on 1 article reviews
hplc system bruker nano elute - by Bioz Stars, 2026-04
90/100 stars
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hewlett packard-1090 microbore pump system  (Hewlett-Packard)
90
Hewlett-Packard hewlett packard-1090 microbore pump system
The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and <t>phosphopeptide</t> enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.
Hewlett Packard 1090 Microbore Pump System, supplied by Hewlett-Packard, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/hewlett packard-1090 microbore pump system/product/Hewlett-Packard
Average 90 stars, based on 1 article reviews
hewlett packard-1090 microbore pump system - by Bioz Stars, 2026-04
90/100 stars
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graphite spin column  (Thermo Fisher)
97
Thermo Fisher graphite spin column
The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and <t>phosphopeptide</t> enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.
Graphite Spin Column, supplied by Thermo Fisher, used in various techniques. Bioz Stars score: 97/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/graphite spin column/product/Thermo Fisher
Average 97 stars, based on 1 article reviews
graphite spin column - by Bioz Stars, 2026-04
97/100 stars
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tio 2 affinity purification high select tio 2 kit  (Thermo Fisher)
90
Thermo Fisher tio 2 affinity purification high select tio 2 kit
The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and <t>phosphopeptide</t> enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.
Tio 2 Affinity Purification High Select Tio 2 Kit, supplied by Thermo Fisher, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
https://www.bioz.com/result/tio 2 affinity purification high select tio 2 kit/product/Thermo Fisher
Average 90 stars, based on 1 article reviews
tio 2 affinity purification high select tio 2 kit - by Bioz Stars, 2026-04
90/100 stars
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Image Search Results


The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and phosphopeptide enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.

Journal: Methods in molecular biology (Clifton, N.J.)

Article Title: Phosphopeptide Enrichment Using Offline Titanium Dioxide Columns for Phosphoproteomics

doi: 10.1007/978-1-62703-360-2_8

Figure Lengend Snippet: The principle of assembling the TiO2 cartridge column, setup of the syringe pump, and phosphopeptide enrichment. (A) A TiO2 column, a cartridge holder, 1/16” OD PEEK tubing, 1/16” OD fittings, a Rheodyne® needle port adapter, a polymer tubing cutter, and 2-3 syringes are needed to assemble the TiO2 cartridge column device for phosphopeptide enrichment. (B) The TiO2 column is assembled in a cartridge holder by finger-tightening. (C) A ~2 inches of 1/16” OD PEEK tube is cut using a polymer tubing cutter. (D) Insert the tube into a 1/16” ferrule, and connect the tube to the outlet of the TiO2 column using a 1/16” nut by finger-tightening. (E) Connect the Rheodyne® needle port adapter to the inlet the TiO2 column by finger-tightening. (F) Insert the needle of a syringe into the needle port adapter of the assembled TiO2 cartridge column and place them onto the syringe pump. The device is ready for phosphopeptide enrichment. (G) Schematic diagram showing the principle of TiO2 enrichment of phosphopeptides with a column wash of 200 mM NH4Glu, pH 2.0.

Article Snippet: Syringes: 1-2 syringes of 5 mL (22 gauge needle) capacity for column washing, 2-3 syringes of 2.5 mL (22 gauge needle) capacity for sample loading, column washing, and phosphopeptide elution (Hamilton Company, Part No. 81516 and 81416).

Techniques: Polymer