about
Development and standardization of multiplexed antibody microarrays for use in quantitative proteomicsEmerging protein array technologies for proteomicsSynthetic antibodies for specific recognition and crystallization of structured RNAThe use of proteomics to identify novel therapeutic targets for the treatment of disease.Detection and quantification of protein biomarkers from fewer than 10 cells.RPPAML/RIMS: a metadata format and an information management system for reverse phase protein arrays.Analysis of glycans on serum proteins using antibody microarrays.Sensitive single-molecule protein quantification and protein complex detection in a microarray format.Design of surfaces for liquid crystal-based bioanalytical assays.Proteomics: challenges, techniques and possibilities to overcome biological sample complexityTumor-associated autoantibody signature for the early detection of gastric cancer.Mass-transport limitations in spot-based microarraysThe current state of proteomics in GI oncology.Simultaneous detection of eight analytes in human serum by two commercially available platforms for multiplex cytokine analysis.Clinical proteomics: present and future prospects.Label-free quantification of microRNAs using ligase-assisted sandwich hybridization on a DNA microarraySerial analysis of 38 proteins during the progression of human breast tumor in mice using an antibody colocalization microarray.In vitro affinity maturation and characterization of anti-P24 antibody for HIV diagnostic assay.Development of an ELISA-array for simultaneous detection of five encephalitis viruses.Antibody arrays in cancer research.Evaluation of surface chemistries for antibody microarrays.Multiplex array proteomics detects increased MMP-8 in CSF after spinal cord injury.Multiplex approaches in protein microarray technology.Studying cellular processes and detecting disease with protein microarrays.ELISA microarray technology as a high-throughput system for cancer biomarker validation.Multiplexed and microparticle-based analyses: quantitative tools for the large-scale analysis of biological systems.Phospho-proteomic immune analysis by flow cytometry: from mechanism to translational medicine at the single-cell level.High-throughput antibody microarrays for quantitative proteomic analysis.Proteomics as a tool for the modelling of biological processes and biomarker development in nutrition research.Analysis of oxidative stress biomarkers using a simultaneous competitive/non-competitive micromosaic immunoassay.Proteomic analysis of human plasma and blood cells in nutritional studies: development of biomarkers to aid disease prevention.Fiber-optic microsphere-based antibody array for the analysis of inflammatory cytokines in saliva.Biomarkers of apoptosis.Development of fluorescent polymerization-based signal amplification for sensitive and non-enzymatic biodetection in antibody microarraysInvited Review Article: Review of centrifugal microfluidic and bio-optical disks.Personalized medicine in oncology: tailoring the right drug to the right patient.Electrochemical Biosensors - Sensor Principles and Architectures.From multimarker approach to multiplex assays in acute coronary syndromes: what are we searching for?A multiplex ELISA-based protein array for screening diagnostic antigens and diagnosis of Flaviviridae infection.Immobilization staphylococcal protein a on magnetic cellulose microspheres for IgG affinity purification.
P2860
Q24802636-06927B66-A993-4C4F-A831-9B849D0E3ECBQ26824107-173547C1-E170-468E-940A-6B9736F2F8D0Q27649448-7B4870EE-42DB-4210-8FD3-E1498681B9BFQ30361936-F17B0569-512B-4572-A52B-ADCAF4DFE096Q33234340-F2BAA545-3200-4012-B5EC-CDE4A051A39EQ33395131-5F4C0357-5A8E-4FAF-AC84-B0916F6C3855Q33432980-F3C9ECCF-CB75-4AEC-90EE-11B87683DBC7Q33577774-31D5D9EB-63FA-498B-A7F8-5B819DA29A91Q33821626-BBD09B70-9DAF-4ED9-8ED1-76340D338644Q34177041-38E313A5-5DD0-48F6-BB59-163B58F2EA9DQ34299043-47FBF5B5-C0B0-4838-B470-B2366BEFC337Q34476169-38A7E8A9-9F0F-4392-BFCB-A33BE2EAE02DQ34608851-AA9482EF-2A32-4FC7-BD50-C5239CCCB7A7Q34713720-E93F74EC-7503-43D9-A2D1-8D64A542B8FDQ35053674-D1440CDB-F92A-4FB9-A2E4-0DB84CD168DFQ35116338-78F82720-B15F-46BC-8FDE-5D37D53CE2C4Q35325472-5E628FC6-026D-4693-8309-2CA51541BC77Q35688643-B18E58D6-A9F7-4B97-B4A0-CD0F8DB00074Q35834122-D65073C2-EFF0-4512-88BB-C2BCD63C073CQ36020258-28F0B8D7-C380-44D0-824A-1E40E28471E3Q36122874-AAAC4F80-B861-4B85-BADC-BD0BE3D038BDQ36226698-37730A3A-7290-4DA3-BB41-CAE1FF5DB6D3Q36227932-98F08ED8-29A8-4116-B3D9-689EC6AE03C7Q36300803-3C6662C7-91F7-4C34-A04F-3C5774B48C33Q36381228-52D53688-97D8-4EDD-B763-9C0B93540E01Q36384804-FD152769-8380-4B81-94E7-81863F972AE1Q36453377-80B46CCE-536C-4432-8DD3-7C7932B8C398Q36913048-57D80D49-51A3-4BB7-B2EE-5A3449DD379BQ37206350-95FEF4B6-E86F-4CE9-A6D5-3415F201C5B3Q37207994-FE9427FF-21F6-4B1E-B6E6-C7E3D3F6F7F8Q37352025-4ECF1830-6243-465C-AF64-3B69703F493EQ37395866-F7C60B88-859E-4377-A871-D8FEEF721771Q37400048-947D8674-E38E-48F8-AE85-B30E52F6A4E6Q37457240-6692521C-8ECB-44BE-BAFB-8132D156CB82Q37628655-E6415ED6-13CC-4093-8836-DA241D21B34EQ37779306-19FA95E2-B57C-42FD-B5C6-1CA7A4542AF6Q39018116-489A8BA3-52F6-4549-B41E-D855822E741BQ39895236-76785D7A-BEFB-4E91-97C1-3F6C41C2687FQ40164185-48F34FD3-053F-4BD1-9F56-B64904686CE2Q40166431-46446B13-D50E-4B10-97A5-75FE3185F738
P2860
description
2004 nî lūn-bûn
@nan
2004年の論文
@ja
2004年論文
@yue
2004年論文
@zh-hant
2004年論文
@zh-hk
2004年論文
@zh-mo
2004年論文
@zh-tw
2004年论文
@wuu
2004年论文
@zh
2004年论文
@zh-cn
name
Multiplexed sandwich assays in microarray format.
@ast
Multiplexed sandwich assays in microarray format.
@en
type
label
Multiplexed sandwich assays in microarray format.
@ast
Multiplexed sandwich assays in microarray format.
@en
prefLabel
Multiplexed sandwich assays in microarray format.
@ast
Multiplexed sandwich assays in microarray format.
@en
P1476
Multiplexed sandwich assays in microarray format.
@en
P2093
Bernhard H Geierstanger
Ulrik B Nielsen
P304
P356
10.1016/J.JIM.2004.04.012
P577
2004-07-01T00:00:00Z