Injectable hydrogel microbeads for fluorescence-based in vivo continuous glucose monitoring.
about
Self and directed assembly: people and moleculesBiocompatible materials for continuous glucose monitoring devicesResponsive Boronic Acid-Decorated (Co)polymers: From Glucose Sensors to Autonomous Drug DeliveryImplantable nanosensors: toward continuous physiologic monitoringLong-term in vivo glucose monitoring using fluorescent hydrogel fibers.Overview of fluorescence glucose sensing: a technology with a bright future.Phosphorescent nanosensors for in vivo tracking of histamine levelsBoronic acids for fluorescence imaging of carbohydrates.Noninvasive Monitoring of Blood Glucose with Raman Spectroscopy.A Biocompatible and Biodegradable Protein Hydrogel with Green and Red Autofluorescence: Preparation, Characterization and In Vivo Biodegradation Tracking and Modeling.Ultrasensitive microchip based on smart microgel for real-time online detection of trace threat analytes.A graphene-based affinity nanosensor for detection of low-charge and low-molecular-weight moleculesSingle-walled carbon nanotube-based near-infrared optical glucose sensors toward in vivo continuous glucose monitoring.Optimization of a Concanavalin A-based glucose sensor using fluorescence anisotropy.A dual sensor for real-time monitoring of glucose and oxygen.Towards smart tattoos: implantable biosensors for continuous glucose monitoring.Boronic Acid-Based Carbohydrate Sensing.Stimuli-Triggered Sol-Gel Transitions of Polypeptides Derived from α-Amino Acid N-Carboxyanhydride (NCA) Polymerizations.Natural or Natural-Synthetic Hybrid Polymer-Based Fluorescent Polymeric Materials for Bio-imaging-Related Applications.Integrated fabrication-conjugation methods for polymeric and hybrid microparticles for programmable drug delivery and biosensing applications.Colorimetric Sugar Sensing Using Boronic Acid-Substituted Azobenzenes.An automated system for high-throughput generation and optimization of microdroplets.Rapid purification of cell encapsulated hydrogel beads from oil phase to aqueous phase in a microfluidic device.Development of hydrogels and biomimetic regulators as tissue engineering scaffolds.A differential dielectric affinity glucose sensor.Aqueous two-phase printing of cell-containing contractile collagen microgels.CMOS image sensor-based implantable glucose sensor using glucose-responsive fluorescent hydrogel.Remote in vivo stress assessment of aquatic animals with microencapsulated biomarkers for environmental monitoring.Multilayered Thin Films from Boronic Acid-Functional Poly(amido amine)sA MEMS differential viscometric sensor for affinity glucose detection in continuous glucose monitoring.Microencapsulated fluorescent pH probe as implantable sensor for monitoring the physiological state of fish embryosTough photoluminescent hydrogels doped with lanthanide.A hydrogel-based glucose affinity microsensor.Skin-like biosensor system via electrochemical channels for noninvasive blood glucose monitoring.Simultaneous Measurements of Geometric and Viscoelastic Properties of Hydrogel Microbeads Using Continuous-Flow Microfluidics with Embedded Electrodes.Controlled release of insulin-like growth factor 1 enhances urethral sphincter function and histological structure in the treatment of female stress urinary incontinence in a rat model.Boronate Affinity-Molecularly Imprinted Biocompatible Probe: An Alternative for Specific Glucose Monitoring.Injectable hydrogels for ophthalmic applications.An Injectable PEG-BSA-Coumarin-GOx Hydrogel for Fluorescence Turn-on Glucose Detection.Wearable Technology for Chronic Wound Monitoring: Current Dressings, Advancements, and Future Prospects.
P2860
Q26747301-93BD0290-635A-4D69-8B56-B98DFF63A813Q26823654-077A5774-BA16-4654-A323-2BAC4E7B9CF2Q28079504-A358BABE-6D69-489F-A2DA-9F43FECDCC3EQ30419409-FEC002F7-7960-4DDB-9CB9-7B2B6C211335Q30503549-99620434-EF83-42E8-AFE7-121312A75906Q30584876-4B132701-62FD-4596-A37D-CE59C8CA8224Q33931888-A4C34774-463E-419E-8C4D-49CA182B0F2EQ35884366-8643580E-117B-4FA3-81CC-E2888D7B4F10Q36245330-A10694D0-DEB6-4C66-BF98-605F2D471DC4Q36506789-00E744D8-3958-472A-85B7-E7CB3020AA8AQ36646608-8B686BB0-3AAA-46B9-9C0C-A27B0E2E3418Q36685245-7404356A-01AE-4D55-B6D2-ABCE03B17DD7Q36954263-F333E229-DE1D-4C70-85DC-BBFFA6328BB1Q37122253-A91D69FB-6533-4A9C-87C5-C7C4F335069BQ37426043-5E95A7B8-C5D8-45FD-93DE-9A01B94B8FD0Q38062870-14586CE5-733B-498B-AD72-4B599955BE41Q38547756-DFF168DA-BD91-4E03-B377-1C04F72D614AQ38633521-240AE698-25C9-45C5-B16B-0FE1E54240C2Q38637417-4A96FFF6-C97B-4A45-8222-20E340EC8381Q38882792-32ACD00A-58DE-4C1D-8E6F-E4049F4D0D3DQ39251731-6A427F48-72A6-4C4D-95CE-B4483242552AQ39297631-44C76ED3-C197-4B3D-B2C4-0FC1E1C81726Q39455779-F3AD1B9D-1F7C-45C4-9243-24230A8EBBC0Q39636970-98366173-0369-47D2-A388-78C04BC1080CQ41769435-8139C9F6-16F6-4753-92DD-6FC58E909246Q42109093-695FE5B7-6C50-48C8-84FA-DBF557C82F8AQ42177201-9B1861E8-C922-4114-8342-4BFD598C24A1Q42374820-0B44C18F-A92F-468A-916C-E078D6D5D03DQ42420931-8E9C8348-85DF-4511-9B2D-8CE036978516Q42554302-6D0CE9CA-D4B5-4F77-B854-655C4FA6D9F5Q42658289-0CF17ACF-4497-49AB-921B-E9A396F03C68Q42831161-45CF8522-5E7D-4426-9137-F421233A817CQ46908720-7DB8FD4A-F756-4937-81E9-27551F1E3386Q47094060-D7B5E7D0-775A-4593-BE37-733C68B20A55Q47345735-649C9794-4B4A-42B8-9E1F-850DE74D88BAQ47668527-5D5F734F-C5E1-46BE-A469-C151647F2D55Q48055377-563D092E-2940-4890-A3FD-DA47C8F1C7C6Q50072638-9C8001A1-4302-4DA5-AC2D-898D59B06537Q51803033-A05C0E4D-2306-46DA-B79F-976DDF64CA29Q54213050-821A9BC1-CF19-47DE-BC87-45ABAB91E4A3
P2860
Injectable hydrogel microbeads for fluorescence-based in vivo continuous glucose monitoring.
description
2010 nî lūn-bûn
@nan
2010 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Injectable hydrogel microbeads ...... continuous glucose monitoring.
@ast
Injectable hydrogel microbeads ...... continuous glucose monitoring.
@en
type
label
Injectable hydrogel microbeads ...... continuous glucose monitoring.
@ast
Injectable hydrogel microbeads ...... continuous glucose monitoring.
@en
prefLabel
Injectable hydrogel microbeads ...... continuous glucose monitoring.
@ast
Injectable hydrogel microbeads ...... continuous glucose monitoring.
@en
P2093
P2860
P356
P1476
Injectable hydrogel microbeads ...... continuous glucose monitoring.
@en
P2093
Hideaki Shibata
Teru Okitsu
Tetsuro Kawanishi
Yun Jung Heo
P2860
P304
17894-17898
P356
10.1073/PNAS.1006911107
P407
P577
2010-10-04T00:00:00Z