about
Perspectives of hyperpolarized noble gas MRI beyond 3HeA "Smart" ¹²⁸Xe NMR Biosensor for pH-Dependent Cell LabelingUtilizing a water-soluble cryptophane with fast xenon exchange rates for picomolar sensitivity NMR measurements."Clickable" hydrosoluble PEGylated cryptophane as a universal platform for 129Xe magnetic resonance imaging biosensors.Molecular imaging of cancer cells using a bacteriophage-based 129Xe NMR biosensor.Development of an antibody-based, modular biosensor for 129Xe NMR molecular imaging of cells at nanomolar concentrationsCell-compatible, integrin-targeted cryptophane-(129)Xe NMR biosensors.Degeneracy in cryptophane-xenon complex formation in aqueous solution.Short peptides as biosensor transducers.An Expanded Palette of Xenon-129 NMR Biosensors.Crystallographic observation of 'induced fit' in a cryptophane host-guest model systemMeasurement of radon and xenon binding to a cryptophane molecular host.Cryptophane-folate biosensor for (129)xe NMR.Toward the Ideal Synthesis and Transformative Therapies: The Roles of Step Economy and Function Oriented Synthesis.Fifteen years of cell-penetrating, guanidinium-rich molecular transporters: basic science, research tools, and clinical applicationsSynchrotron X-ray fluorescence studies of a bromine-labelled cyclic RGD peptide interacting with individual tumor cells.Functionalized 129Xe contrast agents for magnetic resonance imaging.NMR of hyperpolarised probes.Protein recognition using synthetic small-molecular binders toward optical protein sensing in vitro and in live cells.NMR Hyperpolarization Techniques of Gases.Design, synthesis, and in vitro evaluation of a binary targeting MRI contrast agent for imaging tumor cells.A doubly responsive probe for the detection of Cys4-tagged proteins.A preorganized β-amino acid bearing a guanidinium side chain and its use in cell-penetrating peptides.Cryptophane xenon-129 nuclear magnetic resonance biosensors targeting human carbonic anhydrase.Preparation, Characterization and Activity of a Peptide-Cellulosic Aerogel Protease Sensor from Cotton.Shorter synthesis of trifunctionalized cryptophane-A derivativesMultiple hindered rotators in a gyroscope-inspired tribenzylamine hemicryptophane.129Xe NMR-based sensors: biological applications and recent methods.Vault Nanoparticles: Chemical Modifications for Imaging and Enhanced Delivery.Biomembrane interactions of functionalized cryptophane-A: combined fluorescence and 129Xe NMR studies of a bimodal contrast agent.A cryptophane-based "turn-on" 129Xe NMR biosensor for monitoring calmodulin.Molecular Sensing with Hyperpolarized (129) Xe Using Switchable Chemical Exchange Relaxation Transfer.Design and Characterization of Two Bifunctional Cryptophane A-Based Host Molecules for Xenon Magnetic Resonance Imaging ApplicationsCell Tracking with Caged Xenon: Using Cryptophanes as MRI Reporters upon Cellular Internalization
P2860
Q26851718-AB79A63B-B484-4560-9227-AEE705A1E079Q28831191-026B562D-0F4D-4E08-8E11-6F6AF6777E8AQ30575118-76F0F38F-6D1A-40F5-8361-5B9F28502CF1Q30598991-67714302-845A-4846-8383-B3C0029621F7Q30612000-91437A78-1556-4FC0-B688-3D6736FC2811Q30839246-E9532D6E-FCD0-4835-AFC8-181966B79D66Q30866826-470F5CDA-40F0-4A00-A5F1-9A42944DA720Q30878972-62E82AF3-86B2-4883-8332-420D185405DEQ31043462-9B9D8A2E-50E2-4412-92DD-2EA45F48F401Q31131667-34155595-2335-4824-A0B4-D91D6D221C5CQ35018410-A7629DBB-68E0-4303-8CE5-6C5AC2E4D61DQ35090935-58B18A01-4758-43FE-9BD1-24D9038928E0Q35464342-F383A54F-D094-42D3-BAA3-C810FCE4AAA4Q37095319-27770FD2-35D2-4D6A-8D3A-C39F3A60B567Q37228573-C6F9921B-F076-4855-9C6C-5B05E25EE50CQ37619340-DC84044B-8CC9-41EA-8BE7-71F0B41BC389Q37633017-1EB3DF0A-B614-43C7-A369-EACE0DF27FB4Q38049124-6CDDF585-519F-4701-83C6-36DBBA3B8726Q38389717-6626568C-7DEA-403F-87F0-BA5B55817661Q38973699-E85F2634-A567-4282-8CBD-A35CC4DF12F1Q39035238-62FD75F7-8CCF-44CA-A59C-60F3BD95FDB2Q40819769-2BF175F1-5C46-4FC9-B954-F2154CEE649AQ41034490-AE1ADF20-D582-4A07-A448-7D2921D575BCQ41963820-796F36E4-2997-4EA8-896D-2BCF32FC2FA0Q41972622-65D9CF7E-CC60-4C06-9C34-BBF1129F0101Q41992211-B1629097-FDE4-4905-B112-1BC923780A0CQ42272140-6FE196D6-8EEB-4DA9-9631-03FEC563CF7FQ42697584-06C6BACB-EE26-4E50-9657-2F1951CF519AQ46134859-B1F7B453-782B-4FAD-83B0-1CB355DE6B42Q46412940-E621C086-C8AD-4013-B2EC-4E02772077D3Q47618169-E9069B58-8C1E-4F6E-A199-33AE7D0E6B46Q51620937-F557BADA-A739-44C5-ABE1-AC8B8D136DBBQ58378186-BC9FEFFB-2B65-43F3-B2B6-570D492CDA32Q58378218-EB515802-4323-457A-ABDE-847A05F98CEF
P2860
description
2008 nî lūn-bûn
@nan
2008 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
2008 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
name
Peptide-mediated cellular uptake of cryptophane.
@ast
Peptide-mediated cellular uptake of cryptophane.
@en
type
label
Peptide-mediated cellular uptake of cryptophane.
@ast
Peptide-mediated cellular uptake of cryptophane.
@en
prefLabel
Peptide-mediated cellular uptake of cryptophane.
@ast
Peptide-mediated cellular uptake of cryptophane.
@en
P2093
P2860
P356
P1476
Peptide-mediated cellular uptake of cryptophane.
@en
P2093
Garry K Seward
Ivan J Dmochowski
P2860
P304
P356
10.1021/BC8002265
P577
2008-11-01T00:00:00Z