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
1293 results found.
Is it beneficial for the major photosynthetic antenna complex of plants to form trimers?
Janik E., Bednarska J., Zubik M., Sowinski K., Luchowski R., Grudzinski W., Gruszecki W.I.
The Journal of Physical Chemistry B, Vol.119, p.8501-8508 (2015)
Reference to: MicroTime 200, FluoTime 300, FluoFit
Methylene blue-induced neuronal protective mechanism against hypoxia-reoxygenation stress
Ryou M.-G., Choudhury G.R., Li W., Winters A., Yuan F., Liu R., Yang S.-H.
Neuroscience, Vol.301, p.193-203 (2015)
Reference to: MicroTime 200, SymPhoTime
Time-domain microfluidic fluorescence lifetime flow cytometry for high-throughput Fröster resonance energy transfer screening
Nedbal J., Visitkul V., Ortiz-Zapater E., Weitsman G., Chana P., Matthews D.R., Ng T., Ameer-Beg S.M.
Cytometry Part A, Vol.087, p.104-118 (2015)
Reference to: MicroTime 200
Excited state proton transfer in the lysosome of live lung cells: normal and cancer cells
Chowdhury R., Saha A., Maneal A.K., Jana B., Ghosh S., Bhattacharyya K.
The Journal of Physical Chemistry B, Vol.119, p.2149-2156 (2015)
Reference to: MicroTime 200
The other side of the coin: time-domain fluorescence lifetime in flow
Bene L., Damjanovich L.
Cytometry Part A, Vol.087, p.101-103 (2015)
Reference to:
MicroTime 200
Related to:
FRET
Multiple-pulse pumping with time-gated detection for enhanced fluorescence imaging in cells and tissue
Fudala R., Rich R.M., Kimball J., Gryczynski I., Raut S., Borejdo J., Stankowska D.L., Krishnamoorty R.R., Gryczynski K., Milwal B.P., Grczynski Z.
Springer Series on Fluorescence (ebook) (p.225-239) (2015)
Reference to: MicroTime 200, SymPhoTime
Accurate fluorescence quantum yield determination by fluorescence correlation spectroscopy
Kempe D., Schöne A., Fitter J., Gabba M.
The Journal of Physical Chemistry B, Vol.119, p.4668-4672 (2015)
Reference to:
MicroTime 200
Related to:
FCS, Time-resolved Fluorescence
Rational design of a new fluorescent ‘on/off’ xanthene dye for phosphate detection in live cells
Martínez-Peragón A., Miguel D., Orte A., Mota A.J., Ruedas-Rama M.J., Justicia J., Alvarez-Pez J. M., Cuerva J.M., Crovetto L.
Organic & Biomolecular Chemistry, Vol.012, p.6432-6439 (2014)
Reference to: MicroTime 200, FluoTime 200, TimeHarp 100/200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), FluoFit, SymPhoTime
GroEL/ES modulates the mechnism and accelerates the rate of TIM-barrel domain folding
Popova K.
Dissertation Ludwig-Maximilians-Universität München (2014)
Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), SymPhoTime
Single-molecule FRET characterization of RNA remodeling induced by an antitermination protein
Ait-Bara S., Clerté C., Margeat E.
RNA Remodeling Proteins, Vol.1259 of the series Methods in Molecular Biology, p.349-368 (2014)
Reference to:
MicroTime 200, SymPhoTime
Related to:
FRET
Properties of femtosecond laser-induced defects in alkali metal fluoride crystals
Bryukvina L.I., Kuznetsov A.V., Suvorova L.F., Martynovich E.F.
Bulletin of the Russian Academy of Sciences: Physics, Vol.078, p.1374-1378 (2014)
Reference to: MicroTime 200
Role of denatured-state properties in chaperonin action probed by single-molecule spectroscopy
Hofmann H., Hillger 'F., Delley C., Hoffmann A., Pfeil S.H., Nettels D., Lipman E.A., Schuler B.
Biophysical Journal, Vol.107, p.2891-2902 (2014)
Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), HydraHarp 400
Efficient one-pot synthesis of monodisperse alkyl-terminated colloidal germanium nanocrystals
Carolan D., Doyle H.
Journal of Nanoparticle Research, Vol.016, 2721 (2014)
Reference to: MicroTime 200, TimeHarp 100/200, FluoFit
Graphene oxide intercalction into self-assembled porphyrin J-aggregates
Maraka H.V.R., Al-Shammari R.M., Al-Attar N., Lopez S.G., Keyes T.E., Rice J.H.
Materials Research Express, Vol.001, 045038 (2014)
Reference to: MicroTime 200, SymPhoTime
Study of the fluorescence blinking behavior of single F2 color centers in LiF crystal
Boichenko S.V., Koenig K., Zilov S.'A., Dresvianskiy V.P., Voitovich A.P., Rakvich A.L., Kuznetssov A.V., Bartul A.V., Martynovich E.F.
Journal of Physics: Conference Series, Vol.552, 012048 (2014)
Reference to: MicroTime 200
Energy transfer effect of hybrid organic rubrene nanorod with CdSe/ZnS quantum dots: application to optical wavefuiding modulators
Moon W.S., Cho E.H., Lee J.B., Jeon S., Kim J., Lee K.-S., Joo J.
Synthetic Metals, Vol.198, p.285-292 (2014)
Reference to: MicroTime 200
A homodimeric BODIPY rotor as a fluorescent viscosity sensor for membrane-mimicking and cellular environments
Raut S., Kimball J., Fudala R., Doan H., Maliwal B., Sabnis N., Lacko A., Gryczynski I., Dzyuba S.V., Gryczynski Z.
Physical Chemistry Chemical Physics, Vol.016, 27037-27042 (2014)
Reference to: MicroTime 200, FluoTime 200, FluoFit, SymPhoTime
Formation of a CdO layer on CdS/ZnO nanorod arrays to enhance their photoelectrochemical performance
Van T.K., Pham L.Q., Kim D.Y., Zheng J.Y., Kim D., Pawar A.U., Kang Y.S.
ChemSusChem, Vol.007, p.3505-3512 (2014)
Reference to: MicroTime 200
Dynamic study on the transformation process of gold nanoclusters
Ma X., Wen X., Toh Y.-R., Huang K.-Y., Tang J., Yu P.
Nanotechnology, Vol.025, p.445705-445710 (2014)
Reference to: MicroTime 200
High-performance liquid chromatography on glass chips using precisely defined porous polymer monoliths as particle retaining elements
Thurmann S., Mauritz L., Heck C., Belder D.
Journal of Chromatography A, Vol.1370, p.33-39 (2014)
Reference to: MicroTime 200
Preparation of plasmonic platforms of silver wires on gold mirrors and their application to surface enhanced fluorescence
Shtoyko T., Raut S., Rich R.M., Sronce R.J., Fudala R., Mason R.N., Akopova I., Gryczynski Z., Gryczynski I.
ACS Applied Materials & Interfaces, Vol.006, p.18780-18787 (2014)
Reference to: MicroTime 200, PicoHarp 300, SymPhoTime
Nanoantenna enhanced emission of light-harvesting complex 2: the role of resonance, polarization, and radiative and non-radiative rates
Wientjes E., Renger J. Curto A.G., Cogdell R., van Hulst N.F.
Physical Chemistry Chemical Physics, Vol.016, p.24739-24746 (2014)
Reference to: MicroTime 200
ANG-2 for quantitative Na+ determination in living cells by time-resolved fluorescence microscopy
Roder P., Hille C.
Photochemical & Photobiological Sciences, Vol.013, p.1699-1710 (2014)
Reference to: MicroTime 200, PicoHarp 300, SymPhoTime
Controlling the luminescence of carboxyl-functionalized CdSe/ZnS core-shell quantum dots in solution by binding with gold nanorods
Focsan M., Gabudean A.M., Vulpoi A., Astilean S.
The Journal of Physical Chemistry C, Vol.118, p.25190–25199 (2014)
Reference to: MicroTime 200, SymPhoTime
Magnetical and optical properties of nanodiamonds can be tuned by particles surface chemistry: theoretical and experimental study
Kratochvílová I., Šebera J., Ashcheulov P., Golan M., Ledvina M., Míčová J., Mravec F., Kovalenko A., Zverev D., Yavkin B., Orlinskii S., Záliš S., Fišerová A., Richter J., Šefc L., Turánek J.
The Journal of Physical Chemistry C, Vol.118, p.25245-25252 (2014)
Reference to: MicroTime 200, SymPhoTime