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Capillary electrophoresis with laser-induced fluorescence detection for laboratory diagnosis of galactosemia.Extrinsic Fabry-Perot interferometry for noncontact temperature control of nanoliter-volume enzymatic reactions in glass microchips.Glass microfluidic devices with thin membrane voltage junctions for electrospray mass spectrometry.Advances in polymerase chain reaction on microfluidic chips.On-chip pressure injection for integration of infrared-mediated DNA amplification with electrophoretic separation.Rapid DNA amplification in glass microdevices.Chitosan as a polymer for pH-induced DNA capture in a totally aqueous system.Infrared temperature control system for a completely noncontact polymerase chain reaction in microfluidic chips.Rapid and inexpensive fabrication of polymeric microfluidic devices via toner transfer maskingMeasurement of microchannel fluidic resistance with a standard voltage meter.Creating biocompatible oil-water interfaces without synthesis: direct interactions between primary amines and carboxylated perfluorocarbon surfactants.Self-regulated, droplet-based sample chopper for microfluidic absorbance detection.A reusable electrochemical proximity assay for highly selective, real-time protein quantitation in biological matrices.A microfluidic interface for the culture and sampling of adiponectin from primary adipocytes.Quantifying Aptamer-Protein Binding via Thermofluorimetric Analysis.Protein quantification using controlled DNA melting transitions in bivalent probe assemblies.Automated Microfluidic Droplet-Based Sample Chopper for Detection of Small Fluorescence Differences Using Lock-In Analysis.Optical lock-in detection of FRET using synthetic and genetically encoded optical switches.Quantitation of femtomolar protein levels via direct readout with the electrochemical proximity assay.Quantitative measurement of zinc secretion from pancreatic islets with high temporal resolution using droplet-based microfluidics.Isothermal DNA amplification in bioanalysis: strategies and applications.A simple and rapid approach for measurement of dissociation constants of DNA aptamers against proteins and small molecules via automated microchip electrophoresis.Passively operated microfluidic device for stimulation and secretion sampling of single pancreatic isletsMacro-to-micro interfacing to microfluidic channels using 3D-printed templates: application to time-resolved secretion sampling of endocrine tissue3D-templated, fully automated microfluidic input/output multiplexer for endocrine tissue culture and secretion sampling.Homogeneous Assays of Second Messenger Signaling and Hormone Secretion Using Thermofluorimetric Methods That Minimize Calibration Burden.Understanding Signal and Background in a Thermally Resolved, Single-Branched DNA Assay Using Square Wave Voltammetry.Improvement of Sensitivity and Dynamic Range in Proximity Ligation Assays by Asymmetric Connector HybridizationThermal isolation of microchip reaction chambers for rapid non-contact DNA amplificationPractical Fluid Control Strategies for Microfluidic DevicesAdvancement of analytical modes in a multichannel, microfluidic droplet-based sample chopper employing phase-locked detectionRapid lipolytic oscillations in ex vivo adipose tissue explants revealed through microfluidic droplet sampling at high temporal resolutionAutomated microfluidic droplet sampling with integrated, mix-and-read immunoassays to resolve endocrine tissue secretion dynamicsA Nucleic Acid Nanostructure Built through On-Electrode Ligation for Electrochemical Detection of a Broad Range of Analytes
P50
Q30311147-C523E7B5-E4FA-47E4-827E-CE1E340DF77AQ30436698-747C0A21-2A33-4CB9-9306-FC2F1B93EF72Q30436949-620B4FB5-400D-433B-8780-0E324151F84AQ30437108-89C43D69-1095-4D44-B2C8-87D2F64DAA25Q30440343-D5725976-205B-40A4-9278-EA5C4C9288E7Q30440815-E0B84AF7-676A-49A7-AAB6-F773FCF25B83Q30441884-1124F2B2-9FAD-49F6-B556-971085CF8A8AQ30442921-F02FF56A-C1AB-4283-85FC-39588942F911Q30490547-A76AF86C-386D-40C4-9A0C-838ADC88B86DQ30532720-318971FC-C329-46B4-97C9-058D40E9B153Q30670313-70CB5FBE-EEEA-452D-B9BD-93B11FB5CEB2Q34108550-A72D66D5-CF18-4D22-84AF-A8CB7399A837Q34321009-EAEAB24A-67A6-48CF-846E-33AA85D84A46Q35039619-FC2ECE84-8130-4EE6-9C8B-BDE71DBC3BEEQ36034510-9F9D256F-2D0F-4D54-80FA-1B178DD5BD80Q36146845-F48A39CB-5EDA-4744-B388-CEDD272409EEQ36362130-736D2955-2E2E-43A2-B97A-0BDA159BE557Q36785183-D4DB34FC-FCA1-4387-AED1-FE10C0FB53DBQ37192636-180B99FD-50E6-41C0-8CE8-0DF10B661421Q37407576-E835475F-48A4-4691-A161-A8D561E5CFC5Q37830700-B373AD90-6BC2-4D1D-B518-FD529491D925Q38337533-659A3968-CC72-4DFA-9312-1411A46186E3Q42152523-6C33A36F-C769-4202-B72A-F7A496E05711Q42388018-62AD3A15-4ECA-4882-802D-D12CC164DE80Q48142059-2D055E45-38B0-4718-8417-CFADDD5ADB38Q48144597-B23446CC-69AE-4B83-A4F5-0E11F1643199Q49553801-CA9BB708-3C07-43D4-B518-99ABD9F2A49AQ54993837-8A45190E-8350-417F-A919-1CBDB64EEBD5Q54993844-EB4CDA50-1286-487A-BC23-BCAAE8D30E9CQ54993847-BE4759BB-9317-452E-99AF-8182A755D6B9Q90040684-3C503FB5-FFA7-496E-B264-4F3D2249529AQ90837167-B5DA7C2C-BBB2-45F8-91CF-3411B341BBA0Q90970548-B05EF709-F8B6-403B-9E06-52A7D2DD21C9Q93142995-547BCEC5-94E5-44A7-BB83-095651A7A280
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Christopher J Easley
@ast
Christopher J Easley
@en
Christopher J Easley
@es
Christopher J Easley
@nl
Christopher J Easley
@sl
type
label
Christopher J Easley
@ast
Christopher J Easley
@en
Christopher J Easley
@es
Christopher J Easley
@nl
Christopher J Easley
@sl
prefLabel
Christopher J Easley
@ast
Christopher J Easley
@en
Christopher J Easley
@es
Christopher J Easley
@nl
Christopher J Easley
@sl
P106
P21
P31
P496
0000-0002-2403-4147