about
Modified Filamentous Bacteriophage as a Scaffold for Carbon Nanofiber.Surface-enhanced Raman spectroscopy introduced into the International Standard Organization (ISO) regulations as an alternative method for detection and identification of pathogens in the food industry.Bacteriophage-Based Bioconjugates as a Flow Cytometry Probe for Fast Bacteria Detection.T7 bacteriophage induced changes of gold nanoparticle morphology: biopolymer capped gold nanoparticles as versatile probes for sensitive plasmonic biosensors.Antibody modified gold nanoparticles for fast and selective, colorimetric T7 bacteriophage detection.Label-free detection of lectins on carbohydrate-modified boron-doped diamond surfaces.Single molecule Raman spectra of porphycene isotopologues.Highly active 3-dimensional cobalt oxide nanostructures on the flexible carbon substrates for enzymeless glucose sensing.Recent advances in bacteriophage-based methods for bacteria detection.Alkali-resistant low-temperature atomic-layer-deposited oxides for optical fiber sensor overlays.Preparation of a responsive carbohydrate-coated biointerface based on graphene/azido-terminated tetrathiafulvalene nanohybrid material.Wide-Field Fluorescence Microscopy of Real-Time Bioconjugation Sensing.An alternative carrier solvent for fingermark enhancement reagents.Spectrally selective fluorescence imaging of Chlorobaculum tepidum reaction centers conjugated to chelator-modified silver nanowires.Hierarchical 3-dimensional nickel-iron nanosheet arrays on carbon fiber paper as a novel electrode for non-enzymatic glucose sensing.Titanium oxide thin films obtained with physical and chemical vapour deposition methods for optical biosensing purposes.Tungsten carbide nanotubes supported platinum nanoparticles as a potential sensing platform for oxalic acid.Sensitive sugar detection using 4-aminophenylboronic acid modified grapheneAmorphous silicon–carbon alloys for efficient localized surface plasmon resonance sensingMolecular monolayers on silicon as substrates for biosensorsOptical Properties of Submillimeter Silver Nanowires Synthesized Using the Hydrothermal MethodPlasmonics with Metallic Nanowires.Selective electrochemical detection of dopamine in a microfluidic channel on carbon nanoparticulate electrodesImmunosensor Based on Long-Period Fiber Gratings for Detection of Viruses Causing GastroenteritisInteractions of bacteriophage T4 adhesin with selected lipopolysaccharides studied using atomic force microscopyPhotochemical Printing of Plasmonically Active Silver NanostructuresUltrasensitive tantalum oxide nano-coated long-period gratings for detection of various biological targets
P50
Q36164933-FF148984-722A-4748-BAE5-635A1702CEC1Q37639728-82811F6A-49CB-4691-B5BE-BE805D16F525Q40404642-972F88BE-6DB8-4BE2-A2FE-04B531869866Q42214613-1DF2BCA9-7DB4-4041-97B1-1D6DCE3722A4Q42228297-0556ABC6-5CF7-4A00-B292-0D916762B909Q42912323-6EA1F0CB-5DCE-4239-8631-72CFB04AE0DEQ46615144-0C736416-0926-4D84-A362-2D77F9E3D366Q47437988-92F6B8A5-553A-49D7-A6E6-FE68E7D3DDC6Q47575010-D14B646E-A6BF-40B2-B17B-C592B497F88BQ47706955-2ED7708A-B2F7-4922-A9BB-27F10C78EE32Q47958845-99812688-C530-4579-90B9-22B594CFD75FQ48207613-81448A8B-F5D7-408B-95DD-F681F899D315Q50045212-3A1D5FF1-11D0-4743-8BC3-AA997DDCB01FQ50234896-737DF0B6-013D-46B2-BD7B-EDF864189E9DQ51640944-C85299F5-17E7-4677-A215-CC1561EBD944Q52887755-5BB8745A-ED6B-45E7-972D-E632C8476B15Q53502437-051183BB-9CBE-4A99-8D79-DCBD5943F1F9Q58600951-AEA347E5-7DE6-4921-9240-7ED5418B6091Q60496182-61C28D8A-11BD-4629-944D-FA8D5BC6DAEEQ60496208-0001DE7E-8AF0-4D66-AA2C-AB65C7C0E4F2Q64081964-D9ECFF77-40C3-4DFD-8735-DC9D386CBE9EQ64979876-74EB22BE-C2D6-48B8-8AAD-E13349A9ED4BQ87735395-9C4E5B3E-2C6C-4517-85FD-F08717BFBEA5Q89578327-4FCEDF29-AB50-49B9-8EEE-50BEDD4D86C4Q90350974-B2B0C789-7B36-4D79-8864-A9CCF68DD86AQ90432695-2CAB1B4B-387A-45C5-89B8-454BACEB8680Q92570324-CD6B987B-3861-42CE-8BF0-36E12513906A
P50
description
investigador
@es
researcher
@en
name
J Niedziółka-Jönsson
@en
type
label
J Niedziółka-Jönsson
@en
prefLabel
J Niedziółka-Jönsson
@en
P31
P496
0000-0001-9508-1373