This application is a National Stage of International patent application PCT/EP2017/070307, filed on Aug. 10, 2017, which claims priority to foreign French patent application No. FR 1658163, filed on Sep. 2, 2016, the disclosures of which are incorporated by reference in their entirety.
The invention relates to a method for detecting fluorescent species that are reversibly photoswitchable at high frequency. Such a method has many applications, in particular in chemistry, in biology and in the field of environmental measurements and screening.
The term “species” is understood to mean a chemical species such as a molecule or a complex, or a physical object such as a nanoparticle. The expression “reversibly photoswitchable species” is understood to mean a species that has at least two distinct states having different fluorescence properties and that may be made to pass from one state to the other reversibly under the effect of light. Examples of reversibly photoswitchable fluorescent species are the protein “Dronpa” and the complex “Spinach-DFHBI” (“Spinach” being an RNA aptamer and DFHPI a fluorogenic probe). These species may in particular be used as probes or markers. Other examples of reversibly switchable fluorescent species may be azo derivatives or indeed protein scaffolds.
Fluorescence imaging, and more particularly fluorescence microscopy, has become an indispensable tool in biology, but also in other disciplines such as the science of materials. Its applications are however limited by the ability to observe a signal of interest on a background of fluorescence or noise. This problem is particularly acute in animal or plant in vivo imaging applications, in which the fluorescent markers to be detected are dispersed in a complex autofluorescent and/or scattering medium; the useful signal is then hidden in intense background noise.
Another limit on fluorescence imaging and detecting technique resides in the width of the spectral band of the fluorophores generally employed, with respect to the width of the visible spectral band: it is difficult to selectively detect more than four fluorescent markers in the same sample, because their emission spectra tend to superpose.
To overcome these limits, the patent application WO 2015075209 A1 and the article by J. Querard et al. “Photoswitching Kinetics and Phase-Sensitive Detection Add Discriminative Dimensions for Selective Fluorescence Imaging”, Angew. Chem. Int. Ed. 2015, 54, 266-2637 (2015), disclose a method using reversibly photoswitchable fluorescent probes, in which method a sample, containing a photoswitchable fluorophore species, is illuminated with a periodically modulated light wave. The component of the intensity emitted by the fluorophores at the same angular frequency is then detected, in phase quadrature with respect to the excitation wave. This method allows certain reversibly photoswitchable fluorophores to be selectively detected while minimizing, under certain conditions that are calculated analytically depending on the characteristics of the fluorophore, the noise generated, in conventional methods, by autofluorescence and/or diffusion in the medium of the sample. One of the problems of this method resides in the frequency of acquisition of successive images. The various reversibly photoswitchable fluorescent species used in the prior art are induced to pass from an activated state to their initial non-activated state thermally: the characteristic time of this transition is for example from 5 to 10 seconds and corresponds to the acquisition time of an image using this method. This timescale is too long to take a substantial, biologically relevant number of measurements.
Another prior-art technique is disclosed in the article by Yen-Cheng Chen et al. (Chen, Y. C., Jablonski, A. E., Issaeva, I., Bourassa, D., Hsiang, J. C., Fahmi, C. J., & Dickson, R. M., 2015, Optically Modulated Photoswitchable Fluorescent Proteins Yield Improved Biological Imaging Sensitivity, Journal of the American Chemical Society, 137(40), 12764-12767) which proposes a fluorophore-detecting method that uses two monochromatic sources of laser light of different excitation wavelengths to achieve heterodyne excitation of a reversibly photoswitchable fluorescent species. This technique proposes an empirical choice of the parameters of measurement of the fluorescence of a species, this preventing this type of measurement from being easily transposed to other species. In addition, the signal-to-noise ratio during the measurement of a reversibly photoswitchable fluorescent species is not optimal. Lastly, the disclosed method does not indicate to a person skilled in the art how to observe two reversibly photoswitchable fluorescent species at the same time.
Yet another prior-art technique that makes it possible to exploit the temporal dynamic range of a reversibly photoconvertible probe—which is specific thereto and different from that of interfering fluorophores—to extract a useful signal from the background noise is known as optical lock-in detection (OLID). This technique is described in the article by G. Marriott et al. “Optical lock-in detection imaging microscopy for contrast-enhanced imaging in living cells”, PNAS, vol. 105, no 46, pages 17789-17794 (18 Nov. 2008), and in the article by Y. Yan et al. “Optical switch probes and optical lock-in detection (OLID) imaging microscopy: high-contrast fluorescence imaging with living systems”, Biochem J (2011), 411-422 and in the article by C. Petchprayoon et al. “Rational design, synthesis, and characterization of highly fluorescent optical switches for high-contrast optical lock-in detection (OLID) imaging microscopy in living cells”, Bioorganic & Medicinal Chemistry 19 (2011), 1030-1040. One drawback of this technique is that it delivers no quantitative information on the concentration of the reversibly photo convertible fluorophores.
The invention aims to remedy the aforementioned drawbacks of the prior art, and more particularly to:
image a sample while differentiating a plurality of different fluorophores;
allow fluorophores to be imaged at high frequency using a technique allowing autofluorescence/scattering noise to be removed;
generally, one or more fluorescent probes in a mixture to be selectively and quantitatively imaged.
One subject of the invention allowing this aim to be partially or entirely achieved is a method for detecting at least one reversibly switchable fluorescent species, including the following steps:
(a) illuminating a sample containing said at least one said reversibly photoswitchable fluorescence species with a first illuminating light beam, of wavelength λ1, and periodically modulated at an angular frequency ω, and with a second illuminating light beam, of λ2 different from λ1, periodically modulated at said angular frequency ω;
(b) detecting fluorescence radiation emitted by said sample thus illuminated; and
(c) extracting the amplitude from the component of the intensity of said fluorescence radiation that has the same periodicity as said periodically modulated first illuminating light beam and that is in phase quadrature therewith;
said second illuminating light beam being modulated in antiphase with respect to said first illuminating light beam; and
the average intensity of said first illuminating light beam, the average intensity of said second illuminating light beam, and their angular frequency ω being chosen so as to get close to a maximum of said amplitude of the intensity component of said fluorescence radiation. For example, the amplitude may have a value equal to at least 75%, preferably 80%, even more preferably 90% of the maximum.
According to one particular embodiment of such a method, at least one said reversibly photoswitchable fluorescent species may have a first and second chemical state, at least one of said states being fluorescent, said or each said reversibly photoswitchable fluorescent species being capable of being converted from said first state to said second state via a first photo-induced reaction, then of returning to said first state via a second photo-induced reaction, and said first illuminating light beam may have an average intensity I10 and be modulated at an angular frequency ω and said second illuminating light beam may have an average intensity I20 with:
(σ12,1+σ21,1)I10=(σ12,2+σ21,2)I20
and
ω=2(σ12,1+σ21,1)I10
where σ12,1I10 and σ21,1I10 are the rate constants of said first and said second reactions photo-induced by said first illuminating light beam, respectively; and where σ12,2I20 and σ21,2I20 are the rate constants of said first and said second reactions photo-induced by said second illuminating light beam, respectively.
Moreover, the average intensity of said first illuminating light beam, the average intensity of said second illuminating light beam, and their angular frequency ω may also be chosen so as to ensure a minimum contrast between said amplitude of the intensity component of said fluorescence radiation and the amplitude of a fluorescence intensity component having the same periodicity generated by interfering species.
Another subject of the invention is a method for detecting at least two reversibly photoswitchable fluorescent species having different dynamic properties, including the following steps:
(a) illuminating a sample containing each said reversibly photoswitchable fluorescent species with a first illuminating light beam of wavelength λ1 and periodically modulated with a first function summing at least two first illuminating components that are modulated with angular frequencies ωi, each said angular frequency ωi of each said first illuminating component being associated with one said reversibly photoswitchable fluorescent species, and being different from the one or more other said angular frequencies ωi; and
illuminating the sample with a second illuminating light beam, of wavelength λ2 different from λ1, and periodically modulated with a second function summing at least two second illuminating components that are modulated with said angular frequencies ωi, each said angular frequency ωi of each said second illuminating component being equal to a said angular frequency ωi of a said first illuminating component;
(b) detecting fluorescence radiation (FLU) emitted by said sample thus illuminated;
(c) extracting each (algebraic) amplitude of the component of the intensity of said fluorescence radiation that has the same angular frequency ωi as each said illuminating component, and that is in phase quadrature with each said first illuminating component;
for each said angular frequency ωi, each said second illuminating component modulated with said angular frequency ωi being in antiphase with respect to each said first illuminating component modulated with said angular frequency ωi;
and the average intensity of said first illuminating light beam, the average intensity of said second illuminating light beam, and said angular frequencies being chosen so as to get close to a maximum of each said amplitude of the intensity component of said fluorescence radiation.
According to particular embodiments of such a method:
Each said reversibly photoswitchable fluorescent species may have a first and a second chemical state, at least one of said states being fluorescent, each said reversibly photoswitchable fluorescent species being capable of being converted from said first state to said second state via a first photo-induced reaction, then of returning to said first state via a second photo-induced reaction, and said first illuminating light beam may have an average intensity I10 and be periodically modulated with a said first function, and said second illuminating light beam may have an average intensity I20 with, for each said reversibly photoswitchable fluorescent species:
(σ12,1+σ21,1)I10=(σ12,2+σ21,2)I20
where σ12,1I10 and σ21,1I10 are the rate constants of said first and said second reactions photo-induced by said first light beam illuminating said species, respectively; and where σ12,2I20 and σ21,2I20 are the rate constants of said first and said second reactions photo-induced by said second light beam illuminating said species, respectively.
For each said angular frequency ωi corresponding to one said reversibly photoswitchable fluorescent species, it is possible for:
ωi=2(σ12,1+σ21,1)I10
where σ12,1I10 and σ21,1I10 are the rate constants of said first and said second reactions photo-induced by said first light beam illuminating said species, respectively. Advantageously, the ratio between at least two said angular frequencies ωi is strictly higher than 10.
In said step e), said sample may be illuminated by at least one substantially monochromatic illuminating light beam.
Said steps b) and c) may be implemented via synchronous detection of said fluorescence radiation.
The method may also include the following step:
d) determining the concentration of said or at least one said reversibly photoswitchable fluorescent species from the component of the intensity of said fluorescence radiation which is extracted in said step c).
Said or at least one said reversibly photoswitchable fluorescent species is chosen from: a photochromic fluorescent protein; and a complex of a biomolecule with a fluorogenic probe.
The sample may contain biological material.
Yet another subject of the invention is a fluorescence-imaging (and in particular fluorescence-microscopy) method implementing such a detecting method. In this case, said sample may comprise a living organism, and at least one element chosen from the presence and concentration of a said reversibly photoswitchable fluorescent species may be measured on the basis of the component of the intensity of said fluorescence radiation which is extracted in said step c), without taking a sample of said living organism.
A said illuminating light beam comprises an amount of daylight and wherein said amount of daylight is included in the light intensity received by said reversibly photoswitchable fluorescent species but remains less than or equal to the average intensities of said illuminating light beams.
The invention will be better understood and other advantages, details and features thereof will become apparent from the following explanatory description, which is given by way of example with reference to the appended drawings, in which:
The reversibly photoswitchable fluorescent species P has two different states that are exchangeable under the action of light. It may be a question of a photochromic fluorescent species, or of any other system the dynamic behavior of which may be modelled as an exchange between two states under the action of light; these states may correspond to different stereochemical configurations of a molecule, to a bound/non-bound state of a complex, etc. In
The sample E, and more precisely the species P that it contains, when illuminated by a first illuminating light beam FEX1 and by a second illuminating light beam FEX2, emits fluorescent radiation FLU the intensity of which is also modulated and which may be decomposed into:
a component in phase with the first illuminating light beam FEX1, which component is indicated in the figure by IFin; and
a component in quadrature with the excitation beam, which component is indicated in the figure by IFout. Patent application WO 2015075209 A1 discloses the advantage and basis for observation of the component IFout during the observation of the species P.
The dynamic behavior of a reversibly photoswitchable fluorescent species P may be described in the following way. Under the illumination of a species P with light of intensity I(t) containing two components I1(t) and I2(t), corresponding to a first illuminating light beam FEX1, of wavelength λ1 and a second illuminating light beam FEX2, of wavelength λ2, respectively, the dynamic behavior of the species P may be described by the following exchange between two states:
in which the state 1, which is thermodynamically more stable, is converted, via a photochemical reaction, into a thermodynamically less stable state 2 with a rate constant k12(t)=σ12,1I1(t)+σ12,2I2(t), and may return to the more stable initial state 1 via a photochemical and/or thermal process with a rate constant k21(t)=σ21,1I1(t)+σ21,2I2(t)+k21Δ, in which σ12,1I1(t) σ12,2I2(t), σ21,1I1(t), σ21,2I2(t) represent the photochemical contributions and k21Δ the thermal contribution to the rate constants, σ12,1 being the cross section of photoconversion from the state 1 to the state 2 for the illumination of the light beam FEX1, σ12,2 being the cross section of photoconversion from the state 1 to the state 2 for the illumination of the light beam FEX2, σ21,1 being the cross section of photoconversion from the state 2 to the state 1 for the illumination of the light beam FEX1 and σ21,2 being the cross section of photoconversion from the state 2 to the state 1 for the illumination of the light beam FEX1. All of these constants together define the behavior of the species P.
The system is assumed to be illuminated uniformly or may be considered to be uniform at any given time. The variation in the concentrations 1 (concentration in state 1 of species P) and 2 (concentration in state 2 of the species P) may then be described by the following system of equations:
Considering the sample E to be suddenly illuminated by two constant illuminating sources, of wavelength λ1 and λ2, respectively, the illumination is characterized by the intensity I(t)=I10+I20=I0 and the rate constants may be written in the form:
k12(t)=k120=k12,10+k12,20, (4)
k21(t)=k210=k21,10+k21,20+k21Δ. (5)
where
k12,10=σ12,1I10, (6)
k21,10=σ21,1I10, (7)
k12,20=σ12,2I20, (8)
k21,20=σ21,2I20. (9)
Considering the initial state to contain only the species 1, the concentrations 1 and 2 vary as follows:
corresponds to the relaxation time of a reversibly photoswitchable fluorophore and 10 and 20 to the concentrations 1 and 2 in the photostationary state achieved at the time τ120. Thus:
and the total concentration of the species P is Ptot=1+2.
It is possible to analyze the response in terms of fluorescent emission, or fluorescence radiation FLU of a reversibly photoswitchable fluorescent species P when it is subjected to two periodically modulated illuminating light beams FEX1, FEX2, corresponding to embodiments of the invention.
Generally, if a reversibly photoswitchable fluorescent species P is subjected to an illumination comprising two components: a periodic illumination I1(t) at the wavelength λ1 and an illumination I2(t) at the wavelength λ2, said illumination may be constant, this corresponding to an embodiment not according to the invention, or periodically modulated, this corresponding to embodiments of the invention. It is possible to write, in the most general case:
I(t)=I1(t)+I2(t) (35)
and Ij(t)=Ij0[1+αhj(t)] (36)
with j=1 or 2. In equation (36), a corresponds to the amplitude of the light modulation and hj(t) corresponds to periodic functions. Equations (4) and (5) here become:
k12(t)=k12,10[1+αh1(t)]+k12,20[1+αh2(t)] (37)
and k21(t)=k21,10[1+αh1(t)]+k21,20[1+αh2(t)]+k21Δ. (38)
By introducing a function ƒ(t), it is possible to write the expression for the concentrations in the following way:
2=20+αƒ(t) (39)
and 1=10−αƒ(t). (40)
The system of differential equations governing the variation as a function of time of the concentrations 1 and 2 may be solved with equations (2) and (3) to obtain:
respectively designate the speed of the reaction corresponding to equation (1) in the stationary state (with 10 and 20 given by equation (12)) and the differences in the relative contributions of the averages of the modulated illuminations (I10 and I20, respectively) to the rate constants respectively leading to from state 1 to state 2 or from state 2 to state 1.
After the relaxation time τ120, a steady-state regime is entered into, in which ƒ(x) is a continuous periodic function. More generally, ƒ(x) may be a periodic function. In the various embodiments of the invention, an illuminating light beam FEX1, FEX2 may be modulated with a fundamental angular frequency ω or two fundamental angular frequencies (ω1 and ω2) or at least two fundamental angular frequencies, each of the various fundamental angular frequencies being denoted, in this case, by a generic term ωi.
In a first case, the Fourier series corresponding to ƒ(x) may be written in the form:
and where an,cos and bn,sin designate the amplitudes of the nth components of the Fourier series.
In the second case, the Fourier series corresponding to ƒ(x) may be written in the form:
and where a0, an,m,cos and bn,m,sin correspond to the amplitudes of the 0-th and of the {n,m}-th components of the Fourier series. a0 and/or an,m,cos and/or bn,m,sin may be extracted from equation (41) by identifying components of the same order.
All of the obtained equations may be transformed so as to make the concentration modulations explicit for all the angular frequencies. It is then possible to write:
It is also possible to express the fluorescence intensity. Equation (67) defines the observable corresponding to observation at the wavelength λj withj=1 or 2:
Oj(t)=Q1,j1(t)+Q2,j2(t) (67)
Extracting the fluorescence emission If(t) gives equation (68):
IF(t)=O1(t)I1(t)+O2(t)I2(t). (68)
Thus, with the time dependence given by equations (55) and (56):
Whereas the expressions for the amplitudes of the terms Oj(t) are generic, the expressions for the amplitudes of the terms IF(t) vary with the time dependency of the illumination.
With the time dependencies 1(t) and 2(t) given by equations (61) and (62):
in which, likewise, the expressions for the amplitudes of the terms Oj(t) are generic, the expressions for the amplitudes of the terms IF(t) vary with the time dependency of the illumination.
The inventors first of all considered cases in which the modulations of the two amplitudes of the illuminating light beams are small, and denoted ε instead of α below. This case allows the equations to be linearized and analytical expressions to be derived.
In prior-art embodiments, one of the two illuminating light beams is modulated sinusoidally (for example the illuminating light beam FEX1 at the wavelength λ1, which oscillates about an average intensity I10, at the angular frequency ω and with a small amplitude εI10 (ε<<1)) an illuminating light beam of constant intensity I20 and of wavelength λ2 being superposed therewith. Then:
I(t)=I10[1+ε sin(ωt)]+I20 (79)
h1(t)=sin(ωt) (80)
h2(t)=0. (81)
Developing to the first order the expression for the luminous switching, equation (41) becomes:
After the relaxation time τ120 given by equation (11), it is possible to derive:
Using two different wavelengths, the exchanges between states 1 and 2 are essentially governed by the photochemical contributions if the average intensities (I10, I20) are chosen so that: σ21,1I10+σ21,2I20>>k21Δ.
In this case, |1norm1,cos| has a single maximum when the two following conditions of resonance are met:
(σ12,1+σ21,1)I10=(σ12,2+σ21,2)I20 and (90)
ω=2(σ12,1+σ21,1)I10. (91)
This optimization results in an optimization that is independent of the terms α1 and θ/[(1+θ2] of equation (86). α1 corresponds to the variation Δ20 in the steady-state regime 20 after an amplitude jump ΔI10=εI10. It is maximized when the rate constants of the photochemical reactions induced by the two illuminating light beams are equal. The second optimized term, θ/[1+θ2], is maximized by adjusting the angular frequency ω to the relaxation time τ120 so as to obtain θ=1. When ω>>1/τ120, the exchange is slow with respect to variations in the illumination and the pair {1,2} has no time to respond, so as to make the terms i1,sin and i1,cos disappear. In contrast, when ω>>1/τ120, i1,cos cancels out and the concentrations 1 and 2 oscillate in phase with the modulation of the illumination. More generally, and in all the embodiments of the invention, the average intensity of said first illuminating light beam (FEX1), the average intensity of said second illuminating light beam (FEX2), and their angular frequency ω are chosen so as to maximize the amplitude of the intensity component of said fluorescence radiation (FLU) in phase quadrature with the first illuminating light beam.
In embodiments of the invention, the two illuminating light beams FEX1, FEX2 are modulated sinusoidally (or more generally periodically), at the same angular frequency ω. The inventors have discovered that it is possible to increase the amplitude, to the first order, of the response to the illuminating modulations of a species P with respect to the case in which the second illuminating light beam excites a species P with a constant intensity. By way of example, I(t) is considered to comprise a superposition of two sinusoidal modulations of small amplitudes: on the one hand, at the wavelength λ1 about the average intensity I10 and at the angular frequency ω, and on the other hand, at the wavelength λ2 about the average intensity I20 and at the angular frequency ω. Thus:
I(t)=I10[1+εh1(t)]+I20[1+εh2(t)], (92)
h1(t)=sin(ωt), (93)
h2(t)=sin(ωt+φ) (94)
with ε<<1.
Developing to the first order the switching caused by the illumination, f(x)=f1(θx)+f2(θx) is a solution of equation (41) when f1(θx) and f2(θx) are solutions of the following equation (95):
with j=1 or 2, respectively. It will be noted that this equation is similar to equation (82). After the relaxation time τ120 given by equation (11), it is possible to derive:
For the species P used in the embodiments of the invention, nonlimitingly, the photochemically induced transition from the state 1 to that state 2 (or from state 2 to state 1, respectively) is governed exclusively by an illumination at the wavelength λ1 (or λ2, respectively). Considering the rate constant of the reaction that causes the transition from state 2 to state 1 to be mainly governed by photochemistry, it is possible to deduce that a1=−a2. Equations 98 and 99 become:
Equations (100) and (101) show that φ=π is typically favourable for increasing the amplitudes of the fluorescence response. Equations (100) and (101) then become:
and the terms of the fluorescence intensities are:
=(Q1,110+Q2,120)I10+(Q1,20+Q2,220)I20 (104)
=ε{[(Q1,110+Q2,120)I10−(Q1,210+Q2,220)I20]}+ε{[(Q1,1−Q2,1)I10+(Q1,2−Q2,2)I20]11,sin} (105)
=ε[(Q1,1−Q2,1)I10+(Q1,2−Q2,2)I20]11,cos. (106)
In particular, the inventors have discovered that the illumination variation corresponding to equation (92) with φ=π produces, qualitatively, the same results for as a luminous excitation governed by equation (79) but with an amplitude that, in theory, is two times higher. This increase in amplitude allows a number of prior-art technical problems to be solved as it allows a species P obeying the resonance conditions given by equations (90) and (91) to be selectively imaged with a higher temporal resolution and a higher signal-to-noise ratio. More generally, in all of the embodiments of the invention, in which embodiments a first illuminating light beam FEX1 is modulated periodically at an angular frequency ω and a second illuminating light beam is modulated periodically at the same angular frequency ω, the second illuminating light beam FEX2 is modulated in antiphase, i.e. at φ=π with respect to the first illuminating light beam FEX1.
Analytically, it is possible to consider, nonlimitingly, the illuminating intensity I(t) to be a superposition of two small-amplitude sinusoidal modulations, at the angular frequencies ω1 and ω2, which oscillate about an average intensity I10, at the wavelength λ1, and about an average intensity I20, at the wavelength λ2. In other embodiments of the invention, the modulations may be periodic, of different forms, and of larger amplitude. It is considered that:
I(t)=I10[1+εh1(t)]+I20[1+εh2(t)], (121)
h1(t)=sin(ω1t)+β sin(ω2t), (122)
h2(t)=−sin(ω1t)−β sin(ω2t), (123)
with ε<<1. In this case, I10[1+εh1(t)] corresponds to a first function and I20[1+εh2(t)] corresponds to a second function.
Developing to the first order the switching caused by the illumination, f(x)=f1(θ1x)+βf2(θ2x) is a solution of equation (41) when f1(θ1x) and f2(θ2x) are solutions of the following equation (124):
with j=1 or 2, respectively. After the relaxation time τ120, it is possible to derive:
Equations (127) to (130) lead to:
and the terms associated with the oscillating fluorescence emissions are:
=(Q1,110+Q2,120)I10+(Q1,210+Q2,220)I20, (135)
=ε{(Q1,110+Q2,120)I10−(Q1,210+Q2,220)I20}+ε{[(Q1,1−Q2,1)I10+(Q1,2−Q2,2)I20]11,0,sin}, (136)
=ε[(Q1,1−Q2,1)I10+(Q1,2−Q2,2)I20]11,0,cos, (137)
=εβ{(Q1,110+Q2,120)I10−(Q1,210+Q2,220)I20}+ε{[(Q1,1−Q2,1)I10+(Q1,2−Q2,2)I20]10,1,sin} and (138)
=ε[(Q1,1−Q2,1)I10+(Q1,2−Q2,2)I20)]10,1,cos. (139)
In this embodiment, the fluorescence response of the sample E to the superposition of two small-amplitude antiphase modulations at two different angular frequencies ω1 and ω2 allows the embodiments of the invention corresponding to
Advantageously, the periodic modulations applied to the intensities of the first illuminating light beam FEX1 and of the second illuminating light beam FEX2 are not small with respect to the average intensity of these illuminating light beams. They may for example be of the same order of magnitude. In the case of large-amplitude periodic modulations of the intensities of the illuminating light beams FEX1, FEX2, i.e. in the case where α<1, the inventors have discovered that the conditions described above remain valid. These validations were carried out by numerically calculating the various orders of truncated Fourier series the corresponding functions of which were linearized in the preceding cases considering small-amplitude intensity modulation.
The arrows of
When the signal IF0 is used to titrate the species P, the result of the titration overestimates the total concentration because of the contributions of the interfering species. In contrast, the first-order phase-quadrature response to the illumination may be expressed:
and allows Ptot to be determined when the triplet of parameters (I10,I20,ω) is adjusted under the conditions of resonance for a species P. Specifically, the term 1P1,cos is maximum whereas the terms 1X1,cos are negligible. The signal generated by the species P is predominant with respect to that of the other interfering species, and the titration result Ptitration1,cos is approximately equal to Ptot.
Panel A of
In one of the embodiments of the invention, the sample E is illuminated with two illuminating light beams of different wavelengths, and each of the illuminating light beams is periodically modulated in order to image a plurality of reversibly photoswitchable species selectively, as illustrated in
In one particular embodiment, the conditions of resonance set by the two average intensities of the illuminating light beams, i.e. by the relationship (σ12,1+σ21,1)I10=(σ12,2+σ21,2)I20, are employed. Graphically, this solution consists in imaging two reversibly photoswitchable species the conditions of resonance of which may be illustrated by points that are substantially dose to the same vertical line in
One variant of the invention consists in employing these conditions and choosing two frequencies ω1 and ω2 (in the case of detection of two species P′ and P″) meeting the conditions of resonance of each of the species. In other words, each angular frequency a meets the condition ω=2 (σ12,1+σ21,1)I10. This embodiment allows the amplitude of each first-order phase-quadrature fluorescence response IFout to be maximized.
Another variant of the invention consists in employing conditions respecting the relationship (σ12,1+σ21,1)I10=(σ12,2+σ21,2)I20, and in choosing two angular frequencies to modulate the illuminating light beams, each of these angular frequencies being associated with one reversibly photoswitchable species and the ratio of said angular frequencies being, for example, strictly higher than 10 and preferably higher than 100. Specifically, when the relationship (90) is respected, the ratio of the resonant angular frequencies specific to two species P′ and P″ may be low, for example lower than 10. In this case, if conditions meeting relationship (91) are employed, the amplitude IFout corresponding to each species is maximized, but the contribution of interference to an amplitude associated with a given species prevents an optimal contrast from being obtained between the species. It is possible, in this variant, to use relationship (106) to choose the angular frequencies used to modulate the illuminating light beams FEX1, FEX2 so as to obtain a ratio between the angular frequencies that is higher than a predefined value, for example 10, in order to increase the contrast.
More generally, it is possible to depart from the maximum amplitude of the fluorescence signal in order to increase the contrast with respect to one or more interfering species. It is for example possible to maximize the amplitude of the fluorescence under the constraint of obtaining a minimum contrast, to maximize the contrast provided a minimum amplitude (generally expressed in percent of the maximum amplitude) is obtained, or even to determine a region of the parameter space ((ω/I1, I1/I2) ensuring both a sufficiently high amplitude and a sufficiently high contrast are obtained. Likewise, in the case where it is sought to detect a single fluorescent species, it may be advantageous to depart from the conditions of resonance in order to improve the contrast with the interfering fluorescenct species, at the price of a decrease in the amplitude of the signal. Most often however, illumination conditions that ensure that the amplitude of the signal is equal to at least 75%, preferably 80% and even more preferably 90% of the maximum achievable signal will be chosen.
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Number | Date | Country | Kind |
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16 58163 | Sep 2016 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/070307 | 8/10/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/041588 | 3/8/2018 | WO | A |
Number | Name | Date | Kind |
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7964333 | Belfield | Jun 2011 | B1 |
20160084763 | de Boer | Mar 2016 | A1 |
20160305883 | Betzig | Oct 2016 | A1 |
20170370847 | Ghadiali | Dec 2017 | A1 |
Number | Date | Country |
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2015075209 | May 2015 | WO |
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Brakemann et al., “A reversibly photoswitchable GFP-like proton with fluorescence excitation decoupled from switching,” Sep. 2011, Nature Biotechnology, DOI:10.1038/nbt.1952, pp. 942-947. (Year: 2011). |
Querard, et al., “Kinetics of Reactive Modules Adds Discriminative Dimensions for Selective Cell Imaging”, Chemphyschem, vol. 17, No. 10, pp. 1396-1413, May 18, 2016. |
Querard, et al., “Photoswitching kinetics and phase-sensitive detection add discriminative dimensions for selective fluorescence imaging”, Angew Chem Int Editioin, vol. 54, No. 9, pp. 2633-2637, Jan. 21, 2015. |
Querard, et al., “Out-of-phase imaging after optical monochromatic modulation”, Program, 248th ACS National Meeting and Exposition, Aug. 13, 2014. |
Marriott, et al.,“Optical lock-in detection imaging microscopy for contrast-enhanced imaging in living cells”, Proc Natl Acad Sci U S A., vol. 105, No. 46, pp. 17789-17794, Nov. 18, 2008. |
Yan, et al., “Reversible optical control of cyanine fluorescence in fixed and living cells: optical lock-in detection immunofluorescence imaging microscopy”, Philosophical Transactions, Royal Society of London, B: Biol Sci., vol. 368, No. 1611, p. 20120031, Dec. 24, 2012. |
Yan, et al., “Optical switch probes and optical lock-in detection (OLID) imaging microscopy: high-contrast fluorescence imaging within living systems”, Biochemical Journal, vol. 433, No. 3, pp. 411-422, Feb. 1, 2011. |
Querard, et al., “Out-of-phase titration after modulation of activating light (OPTIMAL) for selective and quntitative detection”, Program, 248th ACS National Meeting and Exposition, Aug. 12, 2014. |
Chen et al.,“Optically Modulated Photoswitchable Fluorescent Proteins Yield Improved Biological Imaging Sensitivity”, Journal of the American Chemical Society, 137(40), pp. 12764-12767, 2015. |
Petchprayoon, et al., “Rational design, synthesis, and characterization of highly fluorescent optical switches for high-contrast optical lock-in detection (OLID) imaging microscopy in living cells”, Bioorganic & Medicinal Chemistry, vol. 19, No. 3, pp. 1030-1040, Jul. 7, 2010. |
Number | Date | Country | |
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20190212268 A1 | Jul 2019 | US |