Application Note
FLIM-PLIM-2016-08.doc April 2016 1
Simultaneous Phosphorescence and Fluorescence Lifetime Imaging by
Multi-Dimensional TCSPC and Multi-Pulse Excitation
Abstract. We present a fluorescence and phosphorescence lifetime imaging (FLIM / PLIM)
technique that simultaneously records FLIM and PLIM in confocal or multiphoton laser
scanning systems. Different than other techniques, it uses not only one, but multiple laser pulses
for every phosphorescence excitation cycle. The sensitivity is thus orders of magnitude higher.
Our technique is based on on-off modulating a high-frequency pulsed laser synchronously with
the pixel clock of the scanner, and recording the fluorescence and phosphorescence signals by
multi-dimensional TCSPC. FLIM is obtained by building up a photon distribution over the
times of the photons in the laser pulse period and the scan coordinates, PLIM by building up the
distribution over the times of the photons in the laser modulation period and the scan
coordinates. The technique does not require a reduction of the laser pulse repetition rate by a
pulse picker, and eliminates the need of high pulse energy for phosphorescence excitation.
Motivation of Using Phosphorescence Lifetime Imaging
Phosphorescence occurs when an excited molecule transits from the first excited singlet state, S1,
into the first triplet state, T1, and returns from there to the ground state by emitting a photon [24].
Both the S1-T1 transition and the T1-S0 transition are ‘forbidden’ processes. The transition rates
are therefore much smaller than for the S1-S0 transition. That means that phosphorescence is a slow
process, with lifetimes on the order of microseconds or even milliseconds. Phosphorescence of
organic dyes or endogenous fluorophores is extremely weak or even not detectable at room
temperature. However, strong phosphorescence with lifetimes from the microsecond up to the
millisecond range is obtained for lanthanide complexes [17] and organic complexes of ruthenium
[24, 25], platinum [20, 24, 27, 30], terbium, and palladium [27]. Of special interest for live-cell
imaging is that the phosphorescence of these complexes is strongly quenched by oxygen. The dyes
are therefore excellent oxygen sensors [21, 24, 27, 28, 29, 30, 32]. Applications are aiming at the
measurement of oxygen partial pressure in biological objects, and its effect on the metabolism of
the cells. To reach this target it is desirable that PLIM and FLIM measurements are performed
simultaneously. The oxygen concentration is then derived from the PLIM data, the metabolic
information from the FLIM data, preferably from the NAD(P)H fluorescence. To obtain clean
FLIM and PLIM data from within cells and tissue the imaging technique must provide depth
resolution, and should be able to deliver data from deep tissue layers. The best optical technique to
obtain these data is confocal and multiphoton laser scanning, and the best electronic technique to
obtain time-resolved data with scanning is multi-dimensional TCSPC [14].
Technical Challenges
Excitation Pulse Period and Laser Power
The obvious problem of PLIM is that the excitation pulse period must be a few times longer than
the phosphorescence decay time. For ruthenium dyes with phosphorescence lifetimes below 1 us
the reduction in laser repetition rate may still be feasible, see Hosny et al. [25]. However, the
lifetimes for platinum and palladium-based dyes are on the order of 50 to 100 µs, and the lifetimes
of europium and terbium dyes can be in the millisecond range. PLIM with these dyes would
require a laser repetition rate of less than 10 kHz. Reducing the repetition rate - if possible at all -
Application Note
2 FLIM-PLIM-2016-08.doc April 2016
results in a substantial reduction in the average excitation power, and, consequently, low
phosphorescence intensity. Attempts to compensate for the drop in average power by higher peak
power are limited by the capabilities of the laser, by saturation and other nonlinear effects in the
sample, or, in multiphoton systems, unwanted excitation of higher energy levels or even ionisation.
In other words, the effect of reducing the excitation pulse rate is poor sensitivity. Low sensitivity
can partially be compensated by high phosphor concentration. However, the commonly used
phosphorescence dyes are potentially toxic, and using them in high concentration is not desirable.
Pile-Up Effect
Simply reducing the laser repetition rate causes a significant problem for recording FLIM
simultaneously with PLIM. In principle, it would be possible to derive FLIM and PLIM data from a
one and the same decay curve that is excited by low-repetition rate laser pulses and simultaneously
recorded at two different time scales. One channel would record a photon distribution over the
FLIM time scale, the other over the PLIM time scale. However, this would unavoidably create a
pile-up problem for the FLIM channel. Typical fluorescence lifetimes are on the order of a few
nanoseconds. Neither the detector nor the TCSPC electronics of the FLIM channel are able to detect
several photons within this time and determine their arrival times at picosecond accuracy. Detection
of several photons per excitation pulse must therefore be avoided. That means the detection rate
must be kept at a level no higher than 10% of the excitation rate [10, 12, 13]. With excitation rates
on the order of 100 kHz (for Ruthenium) and 10 kHz (for Platinum and Palladium) the available
detection rates become extremely low, and, consequently, the acquisition times unacceptably long.
Detector Overload
Another problem is that any sample that emits phosphorescence necessarily also emits fluorescence.
The fluorescence both comes from endogenous fluorophores of the sample, and from singlet
emission of the phosphorescence probe. At high laser peak power the peak power of fluorescence
becomes extremely high. This causes transient overload and extreme afterpulsing in the detectors. It
is then impossible to detect a correct phosphorescence decay in the first few microseconds after the
laser pulse. In principle, the overload problem can be solved by using laser pulses with a duration in
the microsecond range. However, apart from the fact this is not simply feasible with most lasers it
would make simultaneous FLIM impossible. More importantly, microsecond pulse duration is not
an option for multiphoton excitation.
Interference with Scanning
PLIM in scanning systems has also another problem. The time the scanner stays within the excited
sample volume must be longer than the phosphorescence lifetime. If the scanner runs off the excited
volume within the phosphorescence decay time photons in the tail of the decay function are lost,
and the recorded decay profile gets distorted. Reasonable recording, even of pure intensity images,
can thus be obtained only by sufficiently slow scanning. However, if both the pixel time and the
pulse repetition period are long there are only a few excitation pulses within the pixel time. Unless
the laser pulse sequence is synchronised with the pixel sequence the number of excitation pulses in
the pixels varies systematically. This induces Moiré effects in the images. The problem can be
solved by synchronising the laser pulses with the pixel frequency, but there is usually no provision
for this in normal laser scanning microscopes. Without synchronisation, the pixel time had to be at
Application Note
FLIM-PLIM-2016-08.doc April 2016 3
least 100 times longer than the laser period. This leads to extremely long frame times, and to a
further increase of the acquisition time.
Laser Pulses
High peak power
but
low average intensity
Phosphorescence
Laser
Fluorescence pulse,
overloads detectors,
causes afterpulsing
and pile-up for FLIM
High peak intensity
remains weak
Pinhole
Excitation
Pulse
Scan
Fig. 1: Challenges of PLIM. Left: Low laser repetition rate results in low average excitation intensity. Second left: High
peak-to-average power ratio causes high peak intensity of fluorescence, detector overload and afterpulsing, and pile-up
in parallel FLIM recording. The phosphorescence intensity remains low due to low average power. Second right:
Scanning must be slow enough to stay in the excited pixel over the time of the phosphorescence decay. Right: Low
scan rate interferes with low laser pulse repetition rate. This induces Moiré effects in the images.
FLIM - PLIM by Multipulse Excitation
The problems described above are avoided by a FLIM / PLIM technique developed by bh in 2010
[4, 11]. The technique is based on the idea that, if a single short laser pulse is not efficient in
exciting phosphorescence, a burst of multiple laser pulses will perform much better. As long as the
burst duration is shorter than the phosphorescence lifetime the excitation efficiency will increase in
proportion to the number of pulses within the burst. Multi-pulse excitation has been used for
multiphoton phosphorescence imaging earlier [30] but bh were first to apply it to TCSPC PLIM.
The principle is shown in Fig. 2. The sample is excited by a pulsed laser running at a repetition rate
in the 50 to 80 MHz range, i.e. at a repetition rate as it is typically used for TCSPC FLIM.
However, the laser does not run continuously. Instead, it is turned on only for a given period of
time, T
on
, at the beginning of each pixel. Within the on-time, T
on
, the laser pulses excite
fluorescence, and, pulse by pulse, build up phosphorescence. The phosphorescence intensity at the
end of the laser-on time is far higher than for a single laser pulse.
For the rest of the pixel time the laser is turned off. After the last laser pulse, the fluorescence
decays quickly, and for the rest of the pixel dwell time, T
off
, pure phosphorescence is detected.
Laser ON
Phosphorescence
Phosphorescence
Laser ON
Fluorescence
Fluorescence
t
T
Laser OFF Laser OFF
Pixel Time, Tpxl
Ton Toff
Fig. 2: Principle of Microsecond FLIM. A high-frequency pulsed laser is on-off modulated synchronously with the
pixels. FLIM is recorded in the Laser ON phases, PLIM in the Laser OFF phases.
Application Note
4 FLIM-PLIM-2016-08.doc April 2016
The buildup of TCSPC FLIM and PLIM images with this excitation sequence is straightforward.
For each photon, the TCSPC module determines the time, t, within the laser pulse period, and the
time, T, after the start of the modulation pulse. The TCSPC process builds up photon distributions
over these times and the scan coordinates [4, 11, 13, 15, 16]
The TCSPC principle is shown in Fig. 3. A fluorescence lifetime image is obtained by building up a
photon distribution over the times, t, of the photons in the laser pulse period, and the scanner
position, x, y, during the T
on
periods. The phosphorescence lifetime image is obtained by building
up a similar distribution over the times, T, within the laser modulation period and the beam
position, x, y. Thus, fluorescence and phosphorescence lifetime images are obtained
simultaneously, in the same scan, and from photons excited by the same laser pulses.
Frame Clock
Line Clock
Pixel Clock
Start
Stop
From scanner
from Laser
TCSPC Module
t
scan clock
after T0
Measurement
CFD
TAC
ADC
CFD
Time
pulses
Clock
Scanning
interface
X
Y
t
pixels
pixels
Photon Distribution
n (x, y, t)
Detector
From laser modulation
X
Y
T-To
pixels
pixels
Photon Distribution
n (x, y, T-T0)
T0
T
Phosphorescence:
Fluorescence:
Fig. 3: Simultaneous fluorescence and phosphorescence lifetime imaging
The procedure can be further refined by using the laser on/off information as a routing signal to
better separate the fluorescence in laser-on phases from the phosphorescence in the laser-off phases,
please see [6, 7, 12].
The principle solves all the problem
s discussed in the previous section. The excitation pulse rate of
FLIM gets de-coupled from the excitation rate of PLIM: The FLIM excitation rate is the laser pulse
period, the PLIM excitation period is the period of the on/off modulation. The average excitation
intensity drops only by the duty cycle of the laser modulation, and the FLIM excitation rate remains
high. High phosphorescence intensity is obtained, and there is no problem with pile-up. The peak
intensity of the laser pulses need not be higher than for a normal TCSPC FLIM measurement. The
principle thus remains compatible with multiphoton excitation. Moreover, there is no excessively
high fluorescence peak intensity, and no detector overload problem. Also the Moiré problem is
solved: The laser modulation is automatically synchronised with the pixels of the scan. Every pixel
thus gets the same number of excitation pulses.
Implementation in the bh FLIM Systems
All SPC-150, SPC-150N, and SPC-160 TCSPC module as well as SPC-830 modules later than
serial number 3D0178 (May 2007) [3] have the hardware functions to record simultaneous FLIM /
PLIM. The only system
requirement is that there is a way to on/off modulate the excitation laser
Application Note
FLIM-PLIM-2016-08.doc April 2016 5
according to the principle shown in Fig. 2. Modulation is performed in different ways in the bh
FLIM systems for different laser scanning microscopes.
DCS-120 Confocal Scanning FLIM System
Laser on/off modulation in the DCS-120 system is achieved via the laser multiplexing function of
the GVD-120 scan controller [6]. The system normally has two lasers which can be multiplexed
within one pixel. PLIM operation for one laser is obtained by enabling the pixel multiplexing
function, and turning the other laser off optically. The laser then turns on at the beginning of each
pixel, runs for a fraction of the pixel time, and then turns off.
The parameter definitions are shown in Fig. 4. Both lasers are turned on. The second laser is
disabled optically by turning the laser attenuator wheel at the scanner fully down. Laser
m
ultiplexing is set to ‘Pixel’. The fraction of the pixel time in which ‘Laser 1’ is on is defined in the
field left of ‘% for 1st laser’. This is the time when the laser is running, and fluorescence is
measured. For the rest of the pixel time the laser is off, and phosphorescence is measured.
For PLIM, a scan speed must be selected that keeps the scanner within the same pixel for a period
of time a few times longer than the phosphorescence decay time. The automatic selection of the
scan speed (normally used for FLIM recording) must therefore be turned off, and an appropriate
scan speed be selected. This is achieved by turning off the ‘Auto’ button for the scan rate, and
selecting a pixel time, T
pxl
, a few times longer than the expected phosphorescence decay time.
To avoid that the scanner moves during the pixel time the DCS-120 scanner has an option to run
along the lines in steps of the individual pixels (scanners normally run continuously to achieve fast
scanning). Stepping along the lines is defined by setting ‘Line Type’ to ‘Steps’.
Scan format and scan area definitions in the scanner control panel are the same as for standard
FLIM. Please see [6] for details.
Fig. 4: DCS-120 scanner setup for simultaneous FLIM/PLIM. Left: Scan and laser control parameters. Right: PLIM
timing parameters
The time range of PLIM is defined in the ‘Configure’ sub-menu of the TCSPC system parameters,
see Fig. 4, right. For efficient PLIM recording, T
pxl
should be a about the same as the ‘Time Range’
selected in the Configure panel. Please see [12] and [6] for details.
Application Note
6 FLIM-PLIM-2016-08.doc April 2016
DCS-120 MP Multiphoton FLIM System
The DCS-120 MP is the multiphoton version of the DCS-120 confocal FLIM system. It uses a Ti:Sa
laser for excitation [8]. Since November 2015 the DCS-120 MP is available with a AOM (acousto-
optical modulator) for laser power control and modulation. Laser modulation is controlled the same
way as for the ps diode lasers of the confocal system. The parameter settings are the same as shown
in Fig. 4.
PZ-FLIM-110 Piezo Scanning FLIM System
The PZ-FLIM-110 system uses sample scanning by a piezo stage [9]. Since the stage is driven by
the bh GVD-120 scan controller FLIM / PLIM is available the same way as in the DCS-120 system.
Please see Fig. 4 for the setup of the scan control parameters.
Zeiss LSM 710, 780, 880 Systems
For the FLIM systems for the Zeiss LSM 710 / 780 / 880 microscope family a bh DDG-210 pulse
generator card is added to the FLIM system. The DDG card triggers on the pixel clock of the LSM,
and sends a ‘Laser On’ signal to the laser controller of the microscope. The principle is shown in
Fig. 5. The pixel clock is split off from the scan synchronisation cable and connected into the
trigger input of the DDG card. The ‘Laser On’ signal is connected into the laser control module of
the Zeiss LSM via a ‘PLIM’ input. Please note that this input is optional; it has to be ordered from
Zeiss via an ‘INDIMO’ (individual modification) request. A PLIM macro has to be installed to
activate and de-activate the PLIM input. PLIM Laser control via the DDG-210 card is integrated in
the SPCM software, see Fig. 5, right. The laser-on time is defined on the left. The times on the right
define a routing signal that is used to separate the photon from the laser-on and the laser-off times
in the SPC module. The routing signal can be delayed with respect to the laser-modulation pulse to
compensate for the delay in the AOM of the microscope. Please see [7] for further details.
DDG-210
SPC-150
Pxl Clk
Routing
Pxl
Clk
Laser
Intensity
Routing
Laser on
Laser on
TCSPC module(s)
Pulse generator
Laser Control
Module
Zeiss
Real-Time
Computer
Out1
Out2
TRG
Line, Frame
'PLIM'
Zeiss
Fig. 5: Left: Principle of laser on/off control for the Zeiss LSMs. Right: Laser control panel of bh SPCM software.
Leica SP5, SP8, SP11 Multiphoton Systems
Since October 2015 FLIM / PLIM is available also for the bh FLIM systems for the Leica SP5,
SP8, and SP11 multiphoton microscopes. Laser on-off is controlled by a bh DDG-100 pulse
generator module that is added to the FLIM system. The card is triggered by the pixel clock of the
microscope. The on-off signal from the DDG is fed into the beam blanking control of the
microscope via a logic gate.
Application Note
FLIM-PLIM-2016-08.doc April 2016 7
Laser power control in the Leica multiphoton systems is performed by an EOM (electro-optical
modulator). The EOM is fast enough for PLIM on-off modulation. However, we often found that it
does not turn the laser entirely off. This is no problem in standard imaging applications but it can be
a problem for PLIM. Spurious excitation during the ‘laser-off’ phases causes a large background in
the phosphorescence decay or even makes it impossible to record phosphorescence at all. The
solution is an ND filter in the excitation beam path. FLIM / PLIM is performed at no more than 5%
of the available laser power. A filter that transmits about 20% shifts the power range from 0 to 5%
to 0 to 25%, and reduces the laser power in the off phases sufficiently to avoid spurious excitation.
Please use a reflective filter (an absorptive filter may crack), and tilt it by a few degrees to avoid
back-reflection into the laser.
Leica systems use a sinusoidal scan in x direction. The nonlinearity of the scan is compensated by a
non-uniform pixel time. This is not a problem for the bh FLIM systems: The bh systems use the
pixel clock from the Leica scanner and thus avoid distortion of the images [5, 14]. For PLIM,
however, the variable pixel time along the lines results in a variable laser on/off period and a
variable effective PLIM excitation rate. Also this is not normally a problem. However, the scan rate
should be selected slow enough to let the phosphorescence completely decay within the pixel time.
Normally, incomplete decay can be taken into account by a suitable model in the SPCImage data
analysis [12]. However, this requires that the excitation period is constant over the entire image.
This is not the case for PLIM with the Leica microscopes.
Applications
Oxygen sensing
Oxygen sensing by PLIM has become a hot topic in biomedical microscopy, see [21, 24, 27, 28, 29,
30, 32]. Until recently, phosphorescence imaging has mainly been performed by gated camera
techniques. The disadvantage of these techniques is that they neither yield images from deeper
tissue layers nor images with optical sectioning. PLIM by the technique described here solves these
problems by confocal and two-photon laser scanning microscopy, and, additionally, yields FLIM
and PLIM simultaneously. An increasing number of publications therefore aims at the use of PLIM
for oxygen sensing in cells and tissue. Toncelly et al. used the technique to characterize the sensor
dyes [33]. The penetration into cells and the behaviour of the dyes in the biological environment
was investigated by Dmitriev et al. [19]. The response of the cells and cell clusters on variations in
the oxygen concentration in physiological conditions has been investigated by [18, 22, 23, 29]. An
overview on the FLIM / PLIM technique and an introduction into the use of an oxygen-sensitive
solid matrix for cells has been given by Jenkins et al. [26].
Examples are shown in the figures below. Fig. 6 and Fig. 7 show cultured human embryonic kidney
cells incubated with a palladium-based phosphorescence dye. Fig. 6 was recorded under
atmospheric oxygen partial pressure. The maximum of the lifetime distribution over the pixels is at
75 s. Fig. 7 was recorded under decreased oxygen partial pressure. As can be seen, the maximum of
the lifetime distribution has shifted to 144 µs.
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8 FLIM-PLIM-2016-08.doc April 2016
Fig. 6: HEK cells incubated with a palladium dye under atmospheric oxygen partial pressure. Recorded by bh DCS-120
confocal scanning system, data analysis by bh SPCImage. Lifetime scale 0 (red) to 300 µs (blue). Phosphorescence
lifetime at the Cursor-Position 65 µs. The maximum of the lifetime distribution over the pixels is at 75 µs.
Fig. 7: HEK cells incubated with a palladium dye under reduced oxygen partial pressure. Recorded by bh DCS-120
confocal scanning system, data analysis by bh SPCImage. Lifetime scale 0 (red) to 300 µs (blue). Phosphorescence
lifetime at the Cursor-Position 212 µs. The maximum of the lifetime distribution over the pixels is at 144 µs.
Simultaneous Recording of PO
2
and NAD(P)H Images
Simultaneously recorded fluorescence and phosphorescence lifetime images of live cultured human
squamous carcinoma (SCC-4) cells stained with tris (2,2’-bipyridyl) dichlororuthenium (II)
hexahydrate are shown in Fig. 8, left and right. The data were acquired on a Zeiss LSM 780 NLO
microscope with a bh Simple-Tau 152 system. The excitation wavelength was 750 nm. The image
on the left was recorded in a wavelength interval from 440 to 480 nm. It contains mainly
fluorescence of NAD(P)H. The data were analysed with a double-exponential decay model. The
image shows the ratio of the amplitudes, a1 and a2, of the decay components. The a1/a2 ratio
directly represents the ratio of unbound (a1) and bound (a2) NAD(P)H. The image on the right is
the PLIM image. It shows the phosphorescence lifetime of the Ruthenium dye. The lifetime is
reciprocally related to the oxygen concentration.
Application Note
FLIM-PLIM-2016-08.doc April 2016 9
Fig. 8: FLIM and PLIM images of SCC-4 cells stained with (2,2’-bipyridyl) dichlororuthenium (II) hexahydrate. FLIM
shown left, PLIM shown right. Zeiss LSM 780 NLO with PLIM option, Simple-Tau 152 FLIM/PLIM system, 2-photon
excitation at 750 nm.
Although the results obtained so far look promising caution appears indicated when PLIM data are
interpreted in terms of absolute O
2
concentration measurement. As can be seen from Fig. 8 the
ruthenium dye binds to the constituents of the cells. The phosphorescence lifetime of bound and
unbound dye can be different. Moreover, quenching phenomena are at least in part diffusion-
controlled. The quenching rate - and thus the sensitivity to oxygen - more or less depends on the
oxygen diffusion constant. The diffusion constant may be different inside the cells and outside, and
in different compartments of the cells. pO
2
results derived from PLIM decay times may therefore
not necessarily be comparable for different sub-structures of the cells.
Detection of Zinc Oxide Nanoparticles
There are also FLIM / PLIM applications that use phosphorescence to identify nanoparticles in
biological tissue, and follow their migration or possible dissolution. The principle is used to track
ZnO nanoparticles from sunscreens or cosmetical products in human skin, and investigate possible
influence on the viability via the fluorescence of NAD(P)H [31]. Fig. 9 shows zinc oxide
nanoparticles can easily be detected by PLIM. The decay function is m
ulti-exponential, with
average (intensity-weighted) lifetimes up to 20 µs.
Fig. 9: PLIM of zinc oxide nanoparticles. Left: Lifetime image, intensity weighted lifetime of double-exponential fit.
Right: Decay curve at cursor position. Zeiss LSM 710, two-photon excitation at 750 nm, non-descanned detection
Application Note
10 FLIM-PLIM-2016-08.doc April 2016
PLIM of Inorganic Materials
Fig. 10 was obtained from an Autumit crystal (a uranium mineral). The phosphorescence lifetimes
vary from about 100 us to 400 us. The lifetime image is shown on the left, decay curves of two
selected spots on the right. The pixel time was 3.6 ms, the laser-on time 200 µs. The excitation
wavelength was 405 nm, a 435 nm long pass filter was used in the emission path.
Fig. 10: PLIM image of a uranium mineral. Decay curves if two arbitrary selected spots are shown on the right.
256x256 pixels, 256 time channels, pixel time 3.6 ms, excitation 405 nm, emission filter long pass 435 nm.
Suppression of Autofluorescence
Other applications are using PLIM for suppressing of autofluorescence by using the long lifetime of
PLIM as a discrimination parameter [1, 2]. The SPCM software offers this option online, without
the need of special data analysis, see [12, 6, 7].
Summary
Compared with PLIM techniques that use a single excitation pulse for every phosphorescence
decay cycle our techniques has a number of significant advantages. The first one is that excitation
with multiple pulses obtains a significantly higher triplet population than excitation with a single
pulse. The sensitivity is therefore much higher. The technique can thus be used at correspondingly
lower concentration of the phosphorescence probe, which, in turn, helps reduce possible toxicity.
The second advantage is that it is compatible with multiphoton excitation. Due to the excitation
with multiple laser pulses it does not require higher laser power or laser pulse energy than normal
confocal or multiphoton FLIM. A third advantage is related to the TCSPC technique itself. TCSPC
FLIM can record no more than one photon per laser pulse. The photon rate thus has to be limited to
no more than 10% of the excitation pulse rate. This is no problem for the 80 MHz or 50 MHz pulse
rates of Ti:Sapphire or picosecond diode lasers but it would be a problem if the pulse repetition rate
was reduced to the kHz range. Our technique avoids this limitation because it works at the full laser
repetition rate. The acquisition times is therefore on the order of 10 to 100 seconds, depending on
the expectations to the signal-to-noise ratio of the lifetimes [10, 12]. The only remaining limitation
is in the scan rate. The pixel time must not be shorter than about 5 times the phosphorescence decay
time. This leads to minimum frame times in the range of 1 second for ruthenium dyes and about 10
seconds for platinum dyes. This no longer than the acquisition time required to obtain the desired
signal-to-noise ratio. It thus has no influence on the total acquisition time of the FLIM / PLIM
process.
Application Note
FLIM-PLIM-2016-08.doc April 2016 11
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Contact:
Wolfgang Becker
Becker & Hickl GmbH
Berlin, Germany
