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
1283 results found.
Excitation energy transfer in meta-substituted phenylacetylene multibranched chromophores
He G., Yu C., Li Y., Hu J., Liu Z., Zhang D., Guo Q. Xia A.
Chemistry- An Asian Journal, Vol.011, p.2741-2748 (2016)
Reference to: MicroTime 200
Spectral mapping of 3D multi-cellular tumor spheroid: time-resolved confocal microscopy
Mohapatra S., Nandi S., Chowdhury R., Das G., Ghosh S., Bhattacharyya K.
Physical Chemistry Chemical Physics, Vol.018, p.18381-18390 (2016)
Reference to:
MicroTime 200
Related to:
FLIM
Surface nanobubbles studied by time-resolved fluorescence microscopy methods combined with AFM: the impact of surface treatment on nanobubble nucleation
Hain N., Wesner D., Druzhinin S.I., Schönherr H.
Langmiur, Article ASAP (2016)
Reference to:
MicroTime 200
Related to:
FLIM
Surface passivation of carbon nanoparicles with p-phenylenediamine towards photoluminescent carbon dots
Cracium A.M., Diac A., Focsan M., Socaci C., Magyari K., Maniu D., Mihalache I., Veca L.M., Astilean S., Terec A.
RSC Advances, Vol.006, p.56944-56951 (2016)
Reference to: MicroTime 200, SymPhoTime
Ultralong perovskite microrods: one- versus two-step synthesis and enhancement of hole-transfer during light soaking
Wu X., Wang J., Yeow E.K.L.
The Journal of Physical Chemistry C, Vol.120, p.12273-12283 (2016)
Reference to: MicroTime 200
Design of polyelectrolyte core-shells with DNA to control TMPyP binding
Serra V.V., Teixeira R., Andrade S.M., Costa S.M.B.
Colloids and Surfaces B: Biointerfaces, Vol.146, p.127-135 (2016)
Reference to:
MicroTime 200
Related to:
FLIM
Enhanced local and nonlocal photoluminescence of organic rubrene microrods using surface plasmon of gold nanoparticles: applications to ultrasensitive and remote biosensing
Hwang H.S., Jo S.G., Lee J., Kim J., Joo J.
The Journal of Physical Chemistry C, Vol.120, p.11612-11620 (2016)
Reference to:
MicroTime 200
Related to:
TRPL
Bio-inspired supramolecular materials by orthogonal self-assembly of hydrogelators and phospholipids
Boekhoven J., Brizard A., Stuart M.C.A., Florusse L.J., Raffy G., Del Guerzo A., van Esch J.
Chemical Science, accepted manuscript (2016)
Reference to:
MicroTime 200
Related to:
FLIM
Vinculin head-tail interaction defines multiple earla mechanisms for cell substrate rigidity sensing
Liu Z., Bun P., Audugé N., Coppey-Moisan M., Borghi N.
Integrative Biology, Vol.008, p.693-703 (2016)
Reference to:
MicroTime 200, SymPhoTime
Related to:
FLIM
Dead-time correction of fluorescence lifetime measurements and fluorescence lifetime imaging
Isbaner S., Karedla N., Ruhlandt D., Stein S.C., Chizhik A., Gregor I., Enderlein J.
Optics Express, Vol.024, p.9429-9445 (2016)
Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), HydraHarp 400, SymPhoTime
Enhancing Fröster nonradiative energy transfer via plasmon interaction
Higgins L.J., Zhang X., Marocico C.A., Murphy G.P., Karanikolas V.K., Gun´ko Y.K., Lesnyak V., Gaponik N., Susha A.S., Rogach A.L., Parbrook P.J., Bradley A.L.
Conference Nanophotonics VI, Vol.9884 (2016)
Reference to:
MicroTime 200
Related to:
FRET
Lipid vesicles loading aluminum phthalocyanine chloride: formulation properties and disaggregation upon intracellular delivery
Calori I.R., Tedesco A.C.
Journal of Photochemistry and Photobiology B: Biology, Vol.160, p.240-247 (2016)
Reference to: MicroTime 200, SymPhoTime
Two-photon excitation of a plasmonic nanoswitch monitored by single-molecule fluorescence microscopy
Impellizzeri S., Simoncelli S., Hodgson G.K., Lanterna A.E., McTiernan C.D., Raymo F.M., Aramendia P.F., Scaiano J.C.
Chemistry- A European Journal, Vol.022, p.7281–7287 (2016)
Reference to:
MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series)
Related to:
Single Molecule Detection
Apoferritin fibers: a new template for 1D fluorescent hybrid nanostructures
Jurado R., Castello F., Bondia P., Casado S., Flors C., Cuesta R., Dominique-Vera J.M., Orte A., Galves N.
Nanoscale, Vol.008, p.9648-9656 (2016)
Reference to: MicroTime 200
Monitoring the collapse of pH-sensitive liposomal nanocarriers and environmental pH simultaneously–a fluorescence-based approach
Draffehn S., Kumke M.U.
Molecular Pharmaceutics, Vol.013, p.1608-1617 (2016)
Reference to:
MicroTime 200
Related to:
FCS
ns-time resolution for multispecies STED-FLIM and artifact free STED-FCS
Koenig M., Reisch P., Dowler R., Kraemer B., Tannert S., Patting M., Clausen ;.P., Galiani S., Eggeling C., Koberling F., Erdmann R.
Proceedings of SPIE, Vol.9712, 97120T (2016)
Reference to:
MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), HydraHarp 400, SymPhoTime, VisIR
Related to:
FCS, STED, Pulsed Interleaved Excitation (PIE)
Expression and association of the Yersinia pestis translocon proteins, YopB and YopD, are facilitated by nanolipoprotein particles
Coleman M.A., Cappuccio J.A., Blanchette C.D., Gao T., Arroyo E.S., Hinz A.K., Bourguet F.A., Segelke B., Hoeprich P.D., Huser T., Laurence T.A., Motin V.L., Chromy B.A.
PLoS ONE, Vol.011, e0150166 (2016)
Reference to:
MicroTime 200, SymPhoTime
Related to:
FCS
Strong-light-induced yellowing of green microalgae Chlorella: A study on molecular mechanisms of the acclimation response
Grudzinski W., Krzeminska I., Luchowski R., Nosalewicz A., Gruszecki W.I.,
Algal Research, Vol.016, p.245-254 (2016)
Reference to:
MicroTime 200, HydraHarp 400
Related to:
FLIM
Measuring membrane association and protein diffusion within membranes with supercritical angle fluorescence microscopy
Ma Y., Benda A., Nicovich P.R., Gaus K.
Biomedical Optics Express, Vol.007, p.1561-1576 (2016)
Reference to: MicroTime 200, TimeHarp 260
Translational dynamics of lipidated ras proteins in the presence of crowding agents and compatible osmolytes
Winter R.H.A., Patra S., Erwin N.
ChemPhysChem, Vol.017, p.2164–2169 (2016)
Reference to:
MicroTime 200, SymPhoTime
Related to:
FCS
Optical clearing delivers ultrasensitive hyperspectral dark-field imaging for single-cell evaluation
Cui Y., Wang X., Ren W., Liu J., Irudayaraj J.
ACS Nano, Vol.010, p.3132-3143 (2016)
Reference to: MicroTime 200
Multiple filamentation of femtosecond laser pulses
Kuznetsov A.V., Kuzakov A.S., Martynovich E.F.
Bulletin of the Russian Academy of Sciences: Physics, Vol.080, p.64-67 (2016)
Reference to: MicroTime 200
Quantum trajectories of photoluminescence of F 2 centers in a LiF crystal
Zilov S.A., Voitovich A.P., Bojchenko S.V., Kuznetsov A.V., Dresvyanskiy V.P., Rakevich A.L., Bartul A.V., Koenig K., Martynovich E.F.
Bulletin of the Russian Academy of Sciences: Physics, Vol.080, p.81-84 (2016)
Reference to: MicroTime 200
Formation of defects in lithium fluoride ceramics upon irradiation with femtosecond laser pulses
Moiseeva M.A., Alekseev S.V., Dresvyanskiy V.P., Losev V.F., Martynovich E.F.
Bulletin of the Russian Academy of Sciences: Physics, Vol.080, p.60-63 (2016)
Reference to: MicroTime 200
Red luminescence decay kinetics in Brazilian diamonds
Stepanov F.A., Mironov V.P., Rakevich A.L., Shatsky V.S., Zedgenizov D.A., Martynovich E.F.
Bulletin of the Russian Academy of Sciences: Physics, Vol.080, p.74-77 (2016)
Reference to: MicroTime 200, SymPhoTime