Bibliography
The bibliography contains articles mentioning explicitly PicoQuant or at least one of our product's name (e.g. MicroTime).
Most of the references can be found easily by full-text searches on the internet. However, some papers cite us only indirectly,
sometimes not at all. Such publications are included only if the use of a PicoQuant product is known, for example, based on
communication with the author(s). There are certainly many more articles reporting results obtained using PicoQuant devices.
Unfortunately, such papers are often hidden for us. Please help completing this list.
Do you miss your publication? If yes, we will be happy to include it in our bibliography. Please send an e-mail
to info@picoquant.com containing the appropriate citation.
Thank you very much in advance for your kind co-operation.
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Searching for MicroTime 200
1310 results found.
Highly selective imidazole-appended 9,10-N,N′-diaminomethylanthracene fluorescent probe for switch-on Zn2+ detection and switch-off H2PO4− and CN− detection in 80% aqueous DMSO, and applications to sequential logic gate operations
Pandith A., Uddin N., Choi C.H., Kim H.-S.
Sensors and Actuators B: Chemical, Vol.247, p.840-849 (2017)
Reference to: MicroTime 200
Polysucrose-based hydrogels for loading of small molecules and cell growth
Jugdawa Y., Bhaw-Luximon A., Wesner D., Goonoo N., Schönherr H., Jhurry D.
Reactive and Functional Polymers, Vol.115, p.18-27 (2017)
Reference to: MicroTime 200, PicoHarp 300
Enhanced fluorescence properties of type-I and type-II CdTe/CdS quantum dots using porous silver membrane
Thuy U.T.D., Chae W.-S., Yang W.-G., Liem N.Q.
Optical Materials, Vol.066, p.611-615 (2017)
Reference to: MicroTime 200, SymPhoTime
A FRET sensor enables quantitative measurements of membrane charges in live cells.
Ma Y., Yamamoto Y., Nicovich P.R., Goyette J., Rossy J., Gooding J.J., Gaus K.
Nature Biotechnology, Vol.035, p.363-370 (2017)
Reference to:
MicroTime 200, PicoHarp 300, SPADs
Related to:
FLIM, FRET
Inorganic rubidium cation as an enhancer for photovoltaic performance and moisture stability of HC(NH2)PbI3 perovskite solar cells
Park Y.H., Jeong I., Bae S., Son H.J., Lee P., Lee J., Lee C.-H., Ko M.J.
Advanced Functional Materials, Vol.027, 1605988 (2017)
Reference to: MicroTime 200, SymPhoTime
TiO2 mesocrystals composited with gold nanorods for highly efficient visible-NIR-photocatalytic hydrogen production
Elobanna O., Kim S., Fujitsuka M., Majima T.
Nano Energy, Vol.035, p.1-8 (2017)
Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series)
Differential role of nonmuscle myosin II isoforms during blebbing of MCF-7 cells
Dey S.K., Singh R.K., Chattoraj S., Saha S., Das A., Bhattacharyya K., Sengupta K., Sen S., Jana S.S.
Molecular Biology of the Cell, Vol.028, p.997-1159 (2017)
Reference to:
MicroTime 200
Related to:
FRET
Lipid-protein microdomains in tonoplast of Beta vulgaris L.: comparison between the results obtained by detergent and detergent-free isolation techniques
Ozolina N.V., Nesterkina I.S., Spiridonova E.V., Dudareva L.V., Nurminsky V.N., Salyaev R.K.
Turkish Journal of Biochemistry, Vol.042, p.287-297 (2017)
Reference to: MicroTime 200
Lipid-protein microinclusions in the morphological structures of organelle membranes studied by fluorescent confocal microscopy
Chernyshov M.Yu., Nurminsky V.N., Ozolina N.V.
Advances in Biological Chemistry, Vol.007, p.42-59 (2017)
Reference to: MicroTime 200
Nanoscale characterization of GaN/InGaN multiple quantum wells on GaN nanorods by photoluminescence spectroscopy
Chen W., Wen X., Latzel M., Yang J., Huang S., Shrestha S., Patterson R., Christiansen S., Conibeer G.
Proceedings of SPIE, Gallium Nitride Materials and Devices XII, 101040U (2017)
Reference to:
MicroTime 200
Related to:
FLIM, TRPL
8-Styryl-substituted coralyne derivatives as DNA binding fluorescent probes
Pithan P.M., Decker D., Druzhin S.I., Ihmels H., Schönherr H., Voß Y.
RSC Advances, Vol.007, p.10660-10667 (2017)
Reference to: MicroTime 200
Genome organization in the nucleus: From dynamic measurements to a functional model
Vivante A., Brozgol E., Bronshtein I., Garini Y.
Methods, Vol.123, p.128-137 (2017)
Reference to:
MicroTime 200
Related to:
FCS
Tuning the local solvent composition at a drug carrier surface: the effect of dimethyl sulfoxide/water mixture on the photofunctional properties of hypericin–β-lactoglobulin complexes
Delcanale P., Rodríguez-Amigo B., Juárez-Jiménez J., Luque F.J., Abbruzzetti S., Agut M., Nonell S., Viappiani C.
Journal of Materials Chemistry B, Vol.005, p.1633-1641 (2017)
Reference to: MicroTime 200, FluoTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), NanoHarp 250, SPADs, PMA Series
Joint refinement of FRET measurements using spectroscopic and computational tools
Kyrychenko A., Rodnin M.V., Ghatak C., Ladokhin A.S.
Analytical Biochemistry, Vol.522, p.1-9 (2017)
Reference to:
MicroTime 200, FluoTime 200, FluoFit
Related to:
FRET
Probing micro-environment of lipid droplets in a live breast cell: MCF7 and MCF10A
Ghosh C., Nandi S., Bhattacharyya K.
Chemical Physics Letters, Vol.670, p.27-31 (2017)
Reference to: MicroTime 200
Detailed study of BSA adsorption on micro-and nanocrystallinge diamond//β-SiC composite fradient films by time-resolved fluorescence microscopy
Handschuh-Wang S., Wang T., Druzhinin S.I., Wesner D., Jiang X., Schönherr H.
Langmuir, Vol.033, p.802-813 (2017)
Reference to: MicroTime 200
Significant performance enhancement of InGaN/GaN nanorod LEDs with multi-layer graphene transparent electrodes by alumina surface passivation
Latzel M., Büttner P., Sarau G., Höflich K., Heilmann M., Chen W., Wen X., Conibeer G., Christiansen S.H.
Nanotechnology, Vol.028, 055201 (2017)
Reference to:
MicroTime 200
Related to:
TRPL
A facile synthesis of CuFeO2 and CuO composite photocatalyst films for the production of liquid formate from CO2 and water over a month
Kang U., Park H.
Journal of Materials Chemistry A, Vol.005, p.2123-2131 (2017)
Reference to: MicroTime 200, SymPhoTime
Two-step amyloid aggregation: sequential lag phase intermediates
Castello F., Paredes J.M., Ruedas-Rama M.J., Martin M., Roldan M., Casares S., Orte A.
Scientific Reports, Vol.007, 40065 (2017)
Reference to:
MicroTime 200
Related to:
FRET, Single Molecule Detection
Corrosion-assisted self-growth of Au-decorated ZnO corn silks and their photoelectrochemical enhancement
Zhang Z., Choi M., Baek M., Deng Z., Yong K.
ACS Applied Materials & Interfaces, Vol.009, p.3967-3976 (2017)
Reference to: MicroTime 200, SymPhoTime
Do grain boundaries dominate non-radiative recombination in CH3NH3PbI3 perovskite thin films?
Yang M., Zeng Y., Li Z., Kim D.H., Jiang C.S., van de Lagemaat J., Zhu K.
Physical Chemistry Chemical Physics, Vol.019, p.5043-5050 (2017)
Reference to:
MicroTime 200, PicoHarp 300, SymPhoTime
Related to:
FLIM, TRPL
Determination of nanostructures and drug distribution in lipid nanoparticles by single molecule microscopy
Boreham A., Volz P., Peters D., Keck C.M., Alexiev U.
European Journal of Pharmaceutivs and Biopharmaceutics, Vol.110, p.31-38 (2017)
Reference to:
MicroTime 200
Related to:
FCS
A novel method to evaluate ribosomal performance in cell-free protein synthesis systems
Kempf N., Remes C., Ledesch R., Züchner T., Höfig H., Ritter I., Katranidis A., Fitter J.
Scientific Reports, Vol.007, 46753 (2017)
Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), PicoHarp 300, SPADs, SymPhoTime
Single-molecule FRET measurements in additive-enriched aqueous solutions
Kempe D., Cerminara M., Poblete S., Schöne A., Gabba M., Fitter J.
analytical chemistry, Vol.089, p.694-702 (2017)
Reference to:
MicroTime 200
Related to:
FRET, Single Molecule Detection
Significant improvement in the performance of PbSe quantum dot solar cell by introducing a CsPbBr3 perovskite colloidal nanocrystal back layer
Zhang Z., Chen Z., Zhang J., Chen W., Yang J., Wen X., Wang B., Kobamoto N., Yuan L., Stride J.A., Conibeer G.J., Patterson R.J., Huang S.
Advanced Energy Materials, Vol.007, 1601773 (2017)
Reference to: MicroTime 200