Luís Oliveira a,b , Maria Inês Carvalho c , Elisabete Nogueira a , Valery V. Tuchin d,e,f
description
Transcript of Luís Oliveira a,b , Maria Inês Carvalho c , Elisabete Nogueira a , Valery V. Tuchin d,e,f
Luís Oliveira a,b, Maria Inês Carvalho c, Elisabete Nogueira a, Valery V. Tuchin d,e,f
a DFI – Polytechnic of Porto, School of Engineering, Rua Dr. António Bernardino de Almeida, 431, 4200-072 Porto, Portugal;
b PhD student at FEUP – University of Porto, Rua Dr. Roberto Frias, 4200-465 Porto, Portugal
c DEEC/FEUP and INESC TEC, University of Porto, Rua Dr. Roberto Frias, 4200-465 Porto, Portugal
d Research-Educational Institute of Optics and Biophotonics, Saratov State University, 83 Astrakhanskaya str., Saratov 410012, Russia;
e Laboratory of Laser Diagnostics of Technical and Living Systems, Institute of Precise Mechanics and Control RAS, Saratov 410028, Russia;
f Optoelectronics and Measurement Techniques Laboratory, P. O. Box 4500, University of Oulu, FIN-90014, Oulu, Finland
Saratov Fall Meeting – 2012 September 25 – 28, 2012 Saratov, Russia
OPTICAL MEASUREMENTS OF RAT MUSCLE SAMPLES UNDER TREATMENT WITH ETHYLENE
GLYCOL AND GLUCOSE
1. Introduction
2
The importance of performing optical measurements from biological tissues
is very high to evaluate how the tissues respond to light stimulation.
Several classes of optical measurements can be obtained from ex vivo
tissue samples: transmittance, absorbance, reflection, etc. If those
measurements are to be made while tissue undergoes optical clearing
treatments, the optical measurements can be performed in a manner to
evaluate the time-dependence of the optical response of that tissue sample.
With the objective of studying the time-dependence of the optical response of
muscle to light stimulation and to lead in the near future to the determination
of the time-dependence of the optical properties of that tissue class under
treatment with ethylene glycol and glucose, we have performed a set of
measurements.
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Due to the use (or not) of an integrating sphere, we have two classes of
measurements: integrated – that include total transmittance and total reflectance
and non-integrated – that include collimated transmittance and specular
reflectance. In all cases we have used a Tungsten Halogen lamp with a broad
spectrum and a spectrometer to measure the spectra. The lamp is the HL-2000
model and the spectrometer is the AvaSpec-2048-USB2 model with UA grating set
for 200-1100 nm and 50 μm slit, both from Avantes.
We will present and discuss here the measurements of total transmittance,
collimated transmittance, specular reflectance and total reflectance measured from
muscle samples under treatment with these optical clearing agents. Additionally we
will present also the calculated absorbance and diffuse reflectance.
2. Experimental method
4
To measure total reflectance illumination
is now made through the illuminating
port at 8° with the normal direction to the
sample (right side of the sphere in figure
2). Total reflected light is collected at the
exit port of the sphere (lower hole in
figure 2).
2.1 Integrated measurements – Total transmittance
Figure 1: Total transmittance measuring assembly.
To measure total transmittance the
sample is placed at the sample port of
the integrating sphere (left entrance in
figure 1) and light is introduced into the
sphere through the sample. Total
transmitted light is collected at the exit
port (lower hole in figure 1).
2.2 Integrated measurements – Total reflectance
Figure 2: Total reflectance measuring assembly.
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2.3 Non integrated measurements – Collimated transmittance
Figure 3: Collimated transmittance measuring assembly.
Figure 3 shows the simple assembly used to
measure collimated transmittance: A collimated
beam (Ф=6 mm) is directed normally to the sample.
Immediately before and after the sample two
pinholes (Ф=1 mm) were placed to reduce the beam
diameter. The transmitted beam was measured on
the opposite side of the sample.
2.4 Non integrated measurements – Specular reflectance
Figure 4: Specular reflectance measuring assembly.
The measurement assembly for specular reflectance (figure 4) is accordingly with the total
reflectance measurement assembly in angles and dimensions (figure 2).
it uses an incident beam at 8°
with the normal direction to the
sample surface and the
reflected beam is also
measured at the same angle on
the other side.
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2.5 Tissue samples
The tissue samples used in this experimental study were obtained from the
abdominal wall muscle from rat (Species Wistar Han, see figure 5). All samples
used in these studies (both agents) were obtained from a single animal to
guarantee the maximum similarity in the physiology of all samples.
Figure 5: Whistar Han rat with abdominal wall muscle at the center.
Abdominal wall muscle
Figure 6: Muscle block, excised from the abdominal wall of animal.
After animal sacrifice, the entire
abdominal wall muscle was dissected
from the animal and a muscle block (like
the one seen in figure 6) was available to
prepare samples to be studied.
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2.6 Optical clearing agents
The optical clearing agents used in this study were ethylene glycol and glucose. The
solution of ethylene glycol had 99% of this agent and 1% of water and for the
glucose solution we have dissolved glucose in water to produce a solution
containing 40% of glucose.
We have measured the refractive index of these solutions, obtaining 1.4280 for
ethylene glycol and 1.3850 for glucose 40% [1].
These solutions are recognized as useful optical clearing agents as we have already
observed in our previous studies [1] [2] and also as verified by other researchers [3] [4] [5 ] [6].
In the present study, instead of measuring only the collimated transmittance as before [1], we have selected 4 types of measurements for later use in the determination of the
optical properties of the muscle and their variation while in optical clearing.
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3. Experimental results
We have performed measurements to obtain total transmittance, total reflectance,
collimated transmittance and specular reflectance. These measurements also
allow to calculate absorbance and diffuse reflectance from the sample. These are
the results that we will present in subsections 3.1 and 3.2 below and their
definition is presented here.
In each particular measurement, we measured the light reference spectrum and
the spectra for natural tissue and while under optical clearing treatment using
the Scan mode of the spectrometer. Considering that the light reference is 100%
of light used in each experiment, we have calculated from the measurements the
total transmittance, total reflectance, collimated transmittance and specular
reflectance spectra by using equations 1, 2, 3 and 4 below. The results obtained
with these equations are presented in percentage of the light reference used in
each case.
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tt
ttt S
tRtT ,%100, (1)
(2)
tc
tcc S
tRtT ,%100,
For the case of total transmittance, we consider Stt(λ) as the spectrum of the light
reference and Rtt(λ,t) as the total transmitted spectrum measured from the sample at
a time t of the treatment. Using these symbols we can present equation 1 that
calculates the total transmittance spectrum at that time t:
Similarly, for the case of collimated transmittance, we consider Stc(λ) as the spectrum
of the light reference and Rtc(λ,t) as the collimated transmitted spectrum measured
from the sample at a time t of the treatment. In equation 2 we show the calculation of
the collimated transmittance spectrum of the sample at time t:
(3)
To calculate the total reflectance spectrum of the sample at a time t of the treatment,
we consider Srt(λ) as the spectrum of the light reference and Rrt(λ,t) as the total
reflected spectrum measured from the sample at a time t of the treatment. Equation
3 shows this calculation:
rt
rtt S
tRtR ,%100,
In a similar manner, equation 4 shows the calculation of the specular reflectance
spectrum at a time t that uses the measurements of the source spectrum (Ssr(λ)) and
the specular reflected spectrum (Rsr(λ,t) ) from the sample at time t:
(4)
sr
srs S
tRtR ,%100,
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Using the experimental measurements we can also calculate the absorbance and
diffuse reflectance of the tissue.
On the other hand, we know that total reflectance contains both specular and diffuse
terms. This way, using the measurements of total and specular reflectance
(performed in the same conditions), we can use equation 6 to calculate diffuse
reflection of the sample at time t:
Considering the integrated measurements of total transmittance and total
reflectance presented in equations 1 and 3 and assuming once again that the light
spectrum that is used in the integrated measurements is 100%, the absorbance of
the sample can be determined as the difference between 100% of light used and the
integrated measurements [7].
Equation 5 shows the calculation of sample’s absorption spectrum at a time t during
the optical clearing treatment:
(5) tRtTtA tt ,,%100,
(6) tRtRtR std ,,, 11
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The results from the study with ethylene glycol are presented in sub-section 3.1 and
the results from the study with glucose are presented in sub-section 3.2.
In each study we will begin by presenting the results for total transmittance,
followed by the results of collimated transmittance, total reflectance, specular
reflectance, absorbance and diffuse reflectance. Each case is well identified.
For each of these particular cases, we present 5 figures:
In the first figure we present the corresponding spectrum for the natural sample.
The second figure contains the spectral evolution in the first 2 minutes of
treatment. The starting reference (natural spectrum) is seen as a thicker line.
Between 5 and 40 seconds, spectra are presented at each 5 seconds and after that
spectra are presented at each 10 seconds. The viewing point for this figure varies
from case to case to optimize the identification of variations.
The third figure shows the time dependence lines for some particular wavelengths
during the first minute of treatment. The chosen wavelengths were 400 nm, 500
nm, 600 nm, 700 nm, 800 nm, 900 nm and 1000 nm.
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The fourth figure shows the spectral variation during 15 minutes of treatment.
It is similar to figure 2, but now spectra are separated by 1 minute. Natural
spectrum is again presented as a thicker line and viewing point may vary
from case to case to optimize the identification of time variations.
Similarly to figure 3, figure 5 shows the time dependence curves for the same
particular wavelengths (400 nm ….. 1000 nm), but now for 30 minutes of
treatment and with one minute resolution.
This set of figures allows immediate identification of the time dependence of the
sample spectrum with the optical clearing treatment applied.
The analysis of these figures and comparison between the two studies allows to identify
differences between the two treatments and recognize some particularities in each
treatment that allow to detect the variation of the optical responses of the muscle sample
with the treatment. Additionally, we can take some conclusions regarding the variation of
the optical properties of the tissue, even without making their calculation.
3.1 Experimental results – Ethylene Glycol
3.1.1 Total transmittance
Figure 7: Total transmittance spectrum from natural muscle. 14
In this first study, we used a solution of ethylene glycol 99%. The results
obtained from the different measurement assemblies and calculations
with equations 1 to 6 are presented below:
Figure 7 shows the natural
spectrum of the muscle
measured with the total
transmittance assembly.Typical absorption
bands.Total
transmittance rises with
wavelength
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Figure 8: Total transmittance spectral evolution in the first two minutes.
Figure 9: Total transmittance evolution in the first minute of treatment for some wavelengths.
Figure 10: Total transmittance spectral evolution in the first 15 minutes.
Figure 11: Total transmittance evolution during the treatment for some particular wavelengths.
Saturation regime begins at ~12 minutes.
Total transmittance spectrum retains its form and rises in the first 2 minutes of treatment.
3.1.2 Collimated transmittance
Figure 12: Collimated transmittance spectrum from natural muscle.16
Figure 12 shows the collimated transmittance spectrum of the natural muscle.
Collimated transmittance
rises with wavelength
Typical absorption band.
Absorption bands of Hemoglobin are not well seen due to tissue blood-washout
after animal sacrifice
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Figure 13: Collimated transmittance spectral evolution in the first two minutes.
Figure 14: Collimated transmittance evolution in the first minute of treatment for some particular wavelengths.
Figure 15: Collimated transmittance spectral evolution in the first 15 minutes.
Figure 16: Collimated transmittance evolution during the treatment for some particular wavelengths.
Variations are more evident in the present case, due that collimated transmittance is a non integrated measurement.
3.1.3 Total reflectance
Figure 17: Total reflectance spectrum from natural muscle. 18
The total reflectance spectrum of the natural muscle is represented in figure 17:
The spectral form is very similar to the one seen for total
transmittance.
The difference is that total reflectance shows much smaller values than total transmittance.
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Figure 18: Total reflectance spectral evolution in the first two minutes.
Figure 19: Total reflectance evolution during in the first minute of treatment for some particular wavelengths.
Figure 20: Total reflectance spectral evolution in the first 15 minutes.
Figure 21: Total reflectance evolution during the treatment for some particular wavelengths.
Total reflectance lowers with treatment (majorly within the first minute).
Some oscilations are evident in this measurement. They tend to lower their magnitude with time.
3.1.4 Specular reflectance
Figure 22: Specular reflectance spectrum from natural muscle.20
Figure 22 shows the specular reflectance spectrum of the natural muscle:
In opposition to the total reflectance
spectrum and apart from the absorption
band seen near 400 nm, the specular reflectance
decreases with wavelength until the
upper limit of the visible range.
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Figure 23: Specular reflectance spectral evolution in the first two minutes. Figure 24: Specular reflectance evolution in the first
minute of treatment for some particular wavelengths.
Figure 25: Specular reflectance spectral evolution in the first 15 minutes.
Figure 26: Specular reflectance evolution during the treatment for some particular wavelengths.
Like in the case of total reflectance, the spectrum of specular reflectance decreases significantly in the first few seconds. Osmotic pressure of agent causes initial increase in specular reflectance. Saturation regime shows
almost linearly increasing specular reflectance.
3.1.5 Absorbance
Figure 27: Absorbance spectrum from natural muscle.22
Using the measurements of total transmittance and total reflectance in equation 5
we have determined the absorbance spectra during the treatment with ethylene
glycol. The Absorbance spectrum for natural tissue is represented in figure 27:
We verify that the muscle presents major
absorbance at lower wavelengths.
Figure 31: Absorbance evolution during the treatment for some particular wavelengths. 23
Figure 28: Absorbance spectral evolution in the first two minutes. Figure 29: Absorbance evolution in the first minute
of treatment for some particular wavelengths.
Figure 30: Absorbance spectral evolution in the first 15 minutes.
From these figures we verify a decreasing behavior for absorbance. Such behavior suggests also a decrease in the absorption coefficient of the muscle.
3.1.6 Diffuse reflectance
Figure 32: Diffuse reflectance spectrum from natural muscle. 24
The last results for this study are for diffuse reflectance. They were calculated by
using total and specular reflectances in equation 6.
For natural tissue, we can see the diffuse reflectance spectrum in figure 32:
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Figure 33: Diffuse reflectance spectral evolution in the first two minutes.
Figure 34: Diffuse reflectance evolution in the first minute of treatment for some particular wavelengths.
Figure 35: Diffuse reflectance spectral evolution in the first 15 minutes. Figure 36: Diffuse reflectance evolution during
the treatment for some particular wavelengths.
Agent insertion into the muscle and muscle fiber bundle re-arrangement produce na initial boost in diffuse reflectance which tends to a long-time decrease.
Figure 37: Total transmittance spectrum from natural muscle. 26
In this second study, we will present the results obtained with equations 1, 2, 3 and 4 from measurements performed from muscle under treatment with a glucose 40% solution. We will also present the absorbance and diffuse reflectance by calculations with equations 5 and 6. The sequence of figures in each case is the same as in the previous case.
3.2 Experimental results – Glucose 40%
3.2.1 Total transmittance
Figure 7 shows the natural
spectrum of the muscle sample
used in the present study.
This spectrum is very similar to the one
obtained in the study with ethylene glycol.
Now, transmittance is a little higher for
longer wavelengths.The differences observed
between the two natural samples
are imposed by the physiology
(which varies between samples,
even from the same animal, but
from different areas of muscle
block).
Figure 41: Total transmittance evolution during the treatment for some particular wavelengths. 27
Figure 38: Total transmittance spectral evolution in the first two minutes.
Figure 39: Total transmittance evolution in the first minute of treatment for some particular wavelengths.
Figure 40: Total transmittance spectral evolution in the first 15 minutes.
The increase in total transmittance verified in the case of glucose 40% for the first 2 minutes is much smaller than the one verified in the case of ethylene glycol.
The differences observed between the two studies are justified by agent concentration in solution and also the different magnitudes of the correspondent diffusion coefficients (probably greater for ethylene glycol in muscle, as we have already observed in our previous studies [1]).
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3.2.2 Collimated transmittance
Figure 42: Collimated transmittance spectrum from natural muscle.
The first result from the collimated transmittance measurements is the spectrum for natural muscle sample, which is presented in figure 42:
Once more, the similarity
between this spectrum
and the one obtained from
the sample used with
ethylene glycol (figure 12)
is high.
In this case, collimated
transmittance is a little
higher for lower
wavelengths and smaller
for longer wavelengths.
Figure 46: Collimated transmittance evolution during the treatment for some particular wavelengths. 29
Figure 43: Collimated transmittance spectral evolution in the first two minutes.
Figure 44: Collimated transmittance evolution in the first minute of treatment for some particular wavelengths.
Figure 45: Collimated transmittance spectral evolution in the first 15 minutes.
We can see that the magnitude of the variations in the first 2 minutes is similar between studies (compare figures 13 and 14 with figure 43 and 44).Considering the long-time representations, the treatment with ethylene glycol produces higher magnitude variations (see also figures 15 and 16).Comparing figures 16 and 46 we see that the major increase occurs within the first 10 minutes for ethylene glycol, while in the case of glucose 40% it occurs within the first minute.
3.2.3 Total reflectance
Figure 47: Total reflectance spectrum from natural muscle.
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The total reflectance spectrum was obtained from measurement on the natural sample before the solution was added. Figure 47 shows this spectrum:
Once more, no significant
differences are observed
in the spectral form
registered from the two
samples used in both
studies.
In the present case, total
reflectance is smaller for
longer wavelengths that in
the case of the study with
ethylene glycol.
Figure 51: Total reflectance evolution during the treatment for some particular wavelengths. 31
Figure 48: Total reflectance spectral evolution in the first two minutes.
Figure 49: Total reflectance evolution during the treatment for some particular wavelengths.
Figure 50: Total reflectance spectral evolution in the first 15 minutes.
Once more, similar variations are observed between the two studies in the first two minutes (in form and magnitude).
Again, total reflectance shows some oscillations during the first minute. This is certainly caused by the positioning of agent in-between the muscle fiber bundles of the muscle, forcing them to oscillate from their central position during the process.
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3.2.4 Specular reflectance
Figure 52: Specular reflectance spectrum from natural muscle.
The specular reflectance spectrum of the natural sample is also very similar to the one obtained in the study with ethylene glycol.
Comparing between
figures 22 and 52, we
see the same spectral
form.
One of the two
differences is a less
intense absorption band
at 410 nm in this case.
The other difference is that in
the present case we see lower
level specular reflectance at
longer wavelengths.
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Figure 53: Specular reflectance spectral evolution in the first two minutes.
Figure 54: Specular reflectance evolution in the first minute of treatment for some particular wavelengths.
Figure 55: Specular reflectance spectral evolution in the first 15 minutes.
Figure 56: Specular reflectance evolution during the treatment for some particular wavelengths.
In figure 53 we see an oscillation in the first seconds of treatment. Specular reflectance lowers from natural state until 10 seconds and then it rises smooth until
20 seconds. After that it tends to a constant value.
Specular reflectance lowers in different stages as we can see from figure 55. This fact indicates that the diffusion of agent into the muscle sample is also in stages
due to the small diffusion power of glucose.
The oscillations seen in this case do not exist in the case of ethylene glycol since its concentration in solution is very high.
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3.2.5 Absorbance
Figure 57: Absorbance spectrum from natural muscle.
Like in the previous
cases, the absorbance
spectrum is very similar
between the two studies.
Using total transmittance and total reflectance measurements, we have calculated absorbance through equation 5. The absorbance spectrum for natural muscle is represented in figure 57:
For longer wavelengths
we verify a lower
absorption than in the
case presented in the
previous study.
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Figure 58: Absorbance spectral evolution in the first two minutes.
Figure 59: Absorbance evolution in the first minute of treatment for some particular wavelengths.
Figure 60: Absorbance spectral evolution in the first 15 minutes.
Figure 61: Absorbance evolution during the treatment for some particular wavelengths.
By comparing between the two studies, we see that ethylene glycol reduces absorbance significantly, while glucose produces modest reduction (compare
figures 28, 29, 30 and 31 with 58, 59, 60 and 61).
36Figure 62: Diffuse reflectance spectrum from natural muscle.
3.2.6 Diffuse reflectance
Finally, we present the results for diffuse reflectance. Once more these spectra were calculated with equation 6 and from the measurements of total reflectance and specular reflectance. Figure 62 shows the spectrum for natural muscle:
Again the diffuse
reflectance obtained in
the present case is
very similar in form and
magnitude to the one
obtained from the
sample used in the
previous study
(compare with figure
32).
The absorption band at lower wavelengths is not so evident in the
present case.
Higher level of diffuse reflectance
for longer wavelengths.
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Figure 63: Diffuse reflectance spectral evolution in the first two minutes.
Figure 64: Diffuse reflectance evolution in the first minute of treatment for some particular wavelengths.
Figure 65: Diffuse reflectance spectral evolution in the first 15 minutes. Figure 66: Diffuse reflectance evolution during
the treatment for some particular wavelengths.
In opposition to the case of ethylene glycol (figure 33) witch presents a strong rise in the first 5 seconds and then remains constant, glucose shows a rise in the first 10 seconds, then lowers a little before entering the saturation regime (figure 63).
The existence of oscillations in the time dependence verified in figures 64 and 66 are caused by the oscillations measured in total reflectance (see figures 49 and 51).
4. Conclusions
We will use these results later to estimate the variations of the optical properties of muscle under
treatment with these solutions. From the increase in collimated transmittance and decrease in
specular reflectance that we have observed in both cases we can estimate that the scattering
coefficient will decrease with the applied treatments. Also as a consequence of these variations, the
g factor will probably increase to improve directionality of the incident beam, which was observed
by the increase in collimated transmittance. On the other hand, the decrease in sample's
absorbance that we have verified in both cases indicates that the absorption coefficient has also
decreased during the treatment with these solutions.
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We have measured and calculated the optical response variations of muscle during the treatments
with ethylene glycol and glucose in aqueous solution.By analyzing and comparing between measurements in the two cases, we verify that ethylene glycol
creates a higher magnitude optical clearing effect than the solution of glucose 40%. An interesting case was observed in the measurements of specular reflectance for the treatment of
glucose 40%, where some initial oscillations were detected. These oscillations indicate that this
agent presents a small diffusion coefficient in muscular tissue. An additional explanation for this
fact might be the lower concentration of glucose (40%) in solution when compared to the
concentration of ethylene glycol used (99%).
When determining the variations of the optical properties of the muscle for these optical clearing
effects we will be able to confirm these assumptions and will complement the results here
presented.
Acknowledgements
The authors would like to thank the following institutions for all the help in preparation of the samples and resources made available to perform the measurements:
CIETI – Centro de Inovação em Engenharia e Tecnologia Industrial, ISEP – Instituto Superior de Engenharia do Porto, Portugal.
LAIMM – Laboratório de Apoio à Investigação em Medicina Molecular, Departamento de Biologia Experimental, Faculdade de Medicina da Universidade do Porto, Portugal.
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This work was also supported in part by grants:
• 224014 PHOTONICS4LIFE of FP7-ICT-2007-2, 1.4.09 of RF Ministry of Education and Science;
• RF Governmental contracts 02.740.11.0770, 02.740.11.0879, and 11.519.11.2035;
• FiDiPro, TEKES Program (40111/11), Finland;
• SCOPES EC, Uzb/Switz/RF, Swiss NSF, IZ74ZO_137423/1;
• RF President’s grant “Scientific Schools”, 1177.2012.2.
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Thank you for your attention.