| Nome |
# |
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Electrochemical biosensors based on nanomodified screen-printed electrodes: recent applications in clinical analysis, file e291c0d5-d7ae-cddb-e053-3a05fe0aa144
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2.063
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Prussian Blue based screen printed biosensors with improved characteristics of long-term lifetime and pH stability, file e291c0d3-8d7c-cddb-e053-3a05fe0aa144
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901
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A novel continuous subcutaneous lactate monitoring system, file e291c0d3-8d30-cddb-e053-3a05fe0aa144
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835
|
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Programmable pH-Triggered DNA Nanoswitches, file e291c0d4-8c99-cddb-e053-3a05fe0aa144
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750
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DNA-Based Scaffolds for Sensing Applications, file e291c0d7-6482-cddb-e053-3a05fe0aa144
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639
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Dual-reporter drift correction to enhance the performance of electrochemical aptamer-based sensors in whole blood, file e291c0d6-827e-cddb-e053-3a05fe0aa144
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602
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Fuel‐responsive allosteric DNA‐based aptamers for the transient release of ATP and cocaine, file e291c0d7-6a69-cddb-e053-3a05fe0aa144
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565
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Survey of Redox-Active Moieties for Application in Multiplexed Electrochemical Biosensors, file e291c0d6-8d05-cddb-e053-3a05fe0aa144
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555
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Rapid micromotor-based naked-eye immunoassay., file e291c0d6-8cf2-cddb-e053-3a05fe0aa144
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473
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Electrochemical DNA-Based Immunoassay That Employs Steric Hindrance to Detect Small Molecules Directly in Whole Blood, file e291c0d7-2101-cddb-e053-3a05fe0aa144
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467
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Acetylcholinesterase sensor based on screen-printed carbon electrode modified with prussian blue, file e291c0d3-8ceb-cddb-e053-3a05fe0aa144
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453
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A DNA Nanodevice that loads and releases a cargo with hemoglobin-like allosteric control and cooperativity, file e291c0d6-8cf0-cddb-e053-3a05fe0aa144
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424
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Dissipative DNA nanotechnology, file 3eb27133-2c2e-40fb-9510-489784b9bfb5
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409
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Novel planar glucose biosensors for continuous monitoring use, file e291c0d3-8d31-cddb-e053-3a05fe0aa144
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407
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Porous Silicon Nanoparticle Delivery of Tandem Peptide Anti-Infectives for the Treatment of Pseudomonas aeruginosa Lung Infections, file e291c0d7-1c3c-cddb-e053-3a05fe0aa144
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407
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Dissipative synthetic DNA-based receptors for the transient load and release of molecular cargo, file e291c0d7-699c-cddb-e053-3a05fe0aa144
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392
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Electronic Activation of a DNA Nanodevice Using a Multilayer Nanofilm, file e291c0d6-8568-cddb-e053-3a05fe0aa144
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372
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|
Characterisation of Prussian blue modified screen-printed electrodes for thiol detection, file e291c0d3-8d38-cddb-e053-3a05fe0aa144
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370
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DNA-Based Nanodevices Controlled by Purely Entropic Linker Domains, file e291c0d7-699b-cddb-e053-3a05fe0aa144
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360
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|
Development of a recombinant Fab-fragment based electrochemical immunosensor for deoxynivalenol detection in food samples, file e291c0d3-7978-cddb-e053-3a05fe0aa144
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358
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A modular electrochemical peptide-based sensor for antibody detection, file e291c0d4-c155-cddb-e053-3a05fe0aa144
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358
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pH-driven reversible self-assembly of micron-scale DNA scaffold, file e291c0d7-178a-cddb-e053-3a05fe0aa144
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353
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Cholinesterase sensors based on screen-printed electrodes for detection of organophosphorus and carbamic pesticides, file e291c0d3-8df7-cddb-e053-3a05fe0aa144
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347
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Using Nature’s “Tricks” To Rationally Tune the Binding Properties of Biomolecular Receptors, file e291c0d6-8cb7-cddb-e053-3a05fe0aa144
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339
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Electroanalytical study of Prussian Blue modified glassy carbon paste electrodes, file e291c0d3-8d3a-cddb-e053-3a05fe0aa144
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338
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Reversible Electrochemical Modulation of a Catalytic Nanosystem, file e291c0d6-8d04-cddb-e053-3a05fe0aa144
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333
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Protein-controlled actuation of dynamic nucleic acid networks by using synthetic DNA translators, file e291c0d8-b2b0-cddb-e053-3a05fe0aa144
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331
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Simulative and experimental characterization of a pH-dependent clamp-like DNA triple-helix nanoswitch, file e291c0d6-8556-cddb-e053-3a05fe0aa144
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326
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Extraction and detection of pesticides by cholinesterase inhibition in a two-phase system: A strategy to avoid heavy metal interference, file e291c0d3-8dec-cddb-e053-3a05fe0aa144
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322
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Programmable Nucleic Acid Nanoswitches for the Rapid, Single-Step Detection of Antibodies in Bodily Fluids, file e291c0d8-431b-cddb-e053-3a05fe0aa144
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322
|
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Chapter 24 Mediated enzyme screen-printed electrode probes for clinical, environmental and food analysis, file e291c0d3-7fa1-cddb-e053-3a05fe0aa144
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312
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Prussian Blue modified carbon nanotube paste electrodes: A comparative study and a biochemical application, file e291c0d3-8df9-cddb-e053-3a05fe0aa144
|
284
|
|
Reorganization of self-assembled DNA-based polymers using orthogonally addressable building blocks, file e291c0d9-1758-cddb-e053-3a05fe0aa144
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277
|
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Using the population-shift mechanism to rationally introduce "hill-type" cooperativity into a normally non-cooperative receptor, file e291c0d5-00af-cddb-e053-3a05fe0aa144
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266
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Self-sensing enzyme-powered micromotors equipped with pHResponsive DNA nanoswitches, file e291c0d7-6ce0-cddb-e053-3a05fe0aa144
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264
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A modular clamp-like mechanism to regulate the activity of nucleic-acid target-responsive nanoswitches with external activators, file e291c0d6-8cb5-cddb-e053-3a05fe0aa144
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260
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Glutathione amperometric detection based on a thiol-disulfide exchange reaction, file e291c0d3-8de9-cddb-e053-3a05fe0aa144
|
257
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Remote electronic control of DNA-based reactions and nanostructures assembly, file e291c0d7-5e9a-cddb-e053-3a05fe0aa144
|
256
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Employing the Metabolic “Branch Point Effect” to Generate an All-or-None, Digital-like Response in Enzymatic Outputs and Enzyme-Based Sensors, file e291c0d5-a249-cddb-e053-3a05fe0aa144
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241
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Folding-upon-binding and signal-on electrochemical DNA sensor with high affinity and specificity, file e291c0d5-0127-cddb-e053-3a05fe0aa144
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237
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Antibody-powered nucleic acid release using a DNA-based nanomachine, file e291c0d6-9957-cddb-e053-3a05fe0aa144
|
214
|
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Using spectroscopy to guide the adaptation of aptamers into electrochemical aptamer-based sensors, file 76eb9f21-9de1-4ed1-a933-adad9e1d071f
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213
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Allosterically Tunable, DNA-Based Switches Triggered by Heavy Metals, file e291c0d5-9519-cddb-e053-3a05fe0aa144
|
212
|
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Intrinsic disorder as a generalizable strategy for the rational design of highly responsive, allosterically cooperative receptors, file e291c0d5-0222-cddb-e053-3a05fe0aa144
|
199
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SENSING TOXICANTS IN MARINE WATERS MAKES SENSE USING BIOSENSORS, file e291c0d6-9913-cddb-e053-3a05fe0aa144
|
199
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Hybrid Polymer/Porous Silicon Nanofibers for Loading and
Sustained Release of Synthetic DNA-based Responsive Devices, file e291c0d8-49b7-cddb-e053-3a05fe0aa144
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198
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Protein-templated reactions using DNA-antibody conjugates, file e291c0d9-faa6-cddb-e053-3a05fe0aa144
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191
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|
Rational control of the activity of a Cu2+-dependent DNAzyme by re-engineering purely entropic intrinsically disordered domains, file e291c0d9-1756-cddb-e053-3a05fe0aa144
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189
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Allosteric DNA nanoswitches for controlled release of a molecular cargo triggered by biological inputs, file e291c0d6-8ca9-cddb-e053-3a05fe0aa144
|
184
|
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Selective control of reconfigurable chiral plasmonic metamolecules, file e291c0d6-8555-cddb-e053-3a05fe0aa144
|
174
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pH-controlled assembly of DNA tiles, file e291c0d6-8cb1-cddb-e053-3a05fe0aa144
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173
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Rational Design of Allosteric Inhibitors and Activators Using the Population-Shift Model: In Vitro Validation and Application to an Artificial Biosensor, file e291c0d5-8b3f-cddb-e053-3a05fe0aa144
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160
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The Effects of Crowding on the Stability of a Surface-Tethered Biopolymer: An Experimental Study of Folding in a Highly Crowded Regime, file e291c0d4-82f3-cddb-e053-3a05fe0aa144
|
143
|
|
Orthogonal enzyme-driven timers for DNA strand displacement reactions, file 89831d96-256a-4f64-a38e-73b812ab6d82
|
140
|
|
Determining the folding and binding free energy of DNA-based nanodevices and nanoswitches using urea titration curves, file e291c0d7-20fe-cddb-e053-3a05fe0aa144
|
140
|
|
Switching the aptamer attachment geometry can dramatically alter the signalling and performance of electrochemical aptamer-based sensors, file e291c0d9-b7ea-cddb-e053-3a05fe0aa144
|
136
|
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Real-time, seconds-resolved measurements of plasma methotrexate in situ in the living body, file 7e696410-b3b9-495c-883b-042833a3e1ca
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119
|
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Engineering a responsive DNA triple helix into an octahedral DNA nanostructure for a reversible opening/closing switching mechanism: a computational and experimental integrated study, file e291c0d7-65b9-cddb-e053-3a05fe0aa144
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119
|
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Tumor-Targeting, MicroRNA-Silencing Porous Silicon Nanoparticles
for Ovarian Cancer Therapy, file e291c0d8-84c8-cddb-e053-3a05fe0aa144
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119
|
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DNA-based nanoswitches: insights into electrochemiluminescence signal enhancement, file e291c0d9-a850-cddb-e053-3a05fe0aa144
|
87
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Using antibodies to control DNA-templated chemical reactions, file e291c0d8-9fe3-cddb-e053-3a05fe0aa144
|
80
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Single antibody detection in a DNA origami nanoantenna, file e291c0da-0fc5-cddb-e053-3a05fe0aa144
|
71
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Transient DNA-based nanostructures controlled by redox inputs, file e291c0d9-6601-cddb-e053-3a05fe0aa144
|
64
|
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Thermo-programmed synthetic DNA-based receptors, file 3bf745a2-f94f-4d49-b568-cace1b354d78
|
60
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Dissipative operation of pH-responsive DNA-based nanodevices, file e291c0d9-c276-cddb-e053-3a05fe0aa144
|
60
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Non-natural protein-protein communication mediated by a DNA-based, antibody-responsive device, file e291c0d9-f77b-cddb-e053-3a05fe0aa144
|
49
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Disulfide-linked allosteric modulators for multi-cycle kinetic control of DNA-based nanodevices, file 9759eec4-7e49-4be8-83f3-334101c3e158
|
48
|
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Optimizing the specificity window of biomolecular receptors using structure-switching and allostery, file a6dc8390-c625-44d7-9879-7b7cbcf2cf67
|
38
|
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Protein–protein communication mediated by an antibody-responsive DNA nanodevice, file 1d6a3711-f19b-4945-b44b-56e07773e559
|
37
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|
DNA tile self-assembly guided by base excision repair enzymes, file 866ad285-5e38-4ad5-a9d4-8a0d6bf2e069
|
37
|
|
Enhancement of CRISPR/Cas12a trans-cleavage activity using hairpin DNA reporters, file d929cc35-aa57-4246-adf2-176cbf2659ac
|
24
|
|
Programmable cell-free transcriptional switches for antibody detection, file e291c0d9-ff84-cddb-e053-3a05fe0aa144
|
21
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On the rational design of cooperative receptors, file 559d25d7-37aa-4557-a1dd-b5022ca64c53
|
20
|
|
Spontaneous reorganization of DNA-based polymers in higher ordered structures fueled by RNA, file 5c7b8854-d641-4f46-967e-dd9821908483
|
19
|
|
Dissipative control over the toehold-mediated DNA strand displacement reaction, file df50daca-4ee1-4f2f-8504-4cde1658e317
|
18
|
|
The sequestration mechanism as a generalizable approach to improve the sensitivity of biosensors and bioassays, file 2ff79926-6aca-4321-ad30-8619a67e3d36
|
13
|
|
Synthetic antigen-conjugated DNA systems for antibody detection and characterization, file a315932c-e417-4d27-bf1a-0b2bd588144c
|
13
|
|
Dynamic and reversible decoration of DNA-based scaffolds, file 7d7ac58f-ca41-44ea-ad59-a2f30af2fcfc
|
10
|
|
Controlling DNA nanodevices with light-switchable buffers, file 89c8a771-18b1-4be1-8191-c257f4749b1b
|
8
|
|
Enhancement of CRISPR/Cas12a trans-cleavage activity using hairpin DNA reporters, file c6430f4e-f7fc-487f-88e5-3e9b94d1b924
|
8
|
|
Bispecific antibody detection using antigen-conjugated synthetic nucleic acid strands, file 1f0a0490-d84b-43a0-b68a-4470a3c08999
|
6
|
|
Real-time, seconds-resolved measurements of plasma methotrexate in situ in the living body, file ba8c2cca-1985-4bf0-8dfe-ae1ad74238b2
|
5
|
|
Entropy-based rational modulation of the p Ka of a synthetic pH-dependent nanoswitch, file e291c0d7-c6b8-cddb-e053-3a05fe0aa144
|
3
|
|
Decorated DNA-based scaffolds as lateral flow biosensors, file 7e4c6a97-9c5b-4677-bc0d-70c354f1c316
|
2
|
|
Programmable, multiplexed DNA circuits supporting clinically relevant, electrochemical antibody detection, file e291c0d9-f7be-cddb-e053-3a05fe0aa144
|
2
|
|
Folding-upon-repair DNA nanoswitches for monitoring the activity of DNA repair enzymes, file e291c0d9-fb83-cddb-e053-3a05fe0aa144
|
2
|
|
Electrochemical cell-free biosensors for antibody detection, file fa6f0a75-6e83-49a1-b5fd-e7f3c5f310d9
|
2
|
|
Timed pulses in DNA strand displacement reactions, file 3841c09d-f92c-4d8e-bbe9-25261d249f7d
|
1
|
|
Autonomous and programmable reorganization of DNA-based polymers using redox chemistry, file bb688b5c-4910-44d6-ac60-fb9d2b25fe37
|
1
|
|
Nanoscale probing and imaging of HIV-1 RNA in cells with a chimeric LNA-DNA sensor, file c6eaf4f7-36ad-498f-a2e0-ceba5bdf02de
|
1
|
|
Enzyme‐Linked DNA Displacement (ELIDIS) assay for ultrasensitive electrochemical detection of antibodies, file d508697f-e0b5-4e3f-b070-3f64e7c8aab4
|
1
|
|
Bioelectrochemical Switches for the Quantitative Detection of Antibodies Directly in Whole Blood, file e291c0d5-90d2-cddb-e053-3a05fe0aa144
|
1
|
|
Using Distal-Site Mutations and Allosteric Inhibition To Tune, Extend, and Narrow the Useful Dynamic Range of Aptamer-Based Sensors, file e291c0d8-89fd-cddb-e053-3a05fe0aa144
|
1
|
|
Dissecting the intracellular signalling and fate of a DNA nanosensor by super-resolution and quantitative microscopy, file e291c0d8-c520-cddb-e053-3a05fe0aa144
|
1
|
|
Probing transcription factor binding activity and downstream gene silencing in living cells with a DNA nanoswitch, file e291c0d8-f48e-cddb-e053-3a05fe0aa144
|
1
|
|
Rapid, cost-effective peptide/nucleic acid-based platform for therapeutic antibody monitoring in clinical samples, file e291c0d8-ff36-cddb-e053-3a05fe0aa144
|
1
|
| Totale |
21.863 |