Interferometry is an enabling technique used in measurement and imaging devices that, over the decades, has become indispensable in research and industry. Nearly all modern microscopes have built-in phase contrast (PhC) microscopy, differential interference contrast (DIC) microscopy, and/or polarized light microscopy capabilities, all of which are based on interferometry. For example, these interferometric microscopy techniques have been widely used for observing biological specimens in life sciences. Interferometry has also found wide application in inspecting semiconductor and optical components, where optical surface profilers rely on it to accurately map surface topographies.
Aspects of the present disclosure are related to imaging and sensing using interferometry. Various examples of methods, systems and apparatus related to interferometry for imaging and sensing are disclosed.
In one embodiment, among others, a system for imaging and sensing of a sample, comprises an interferometer configured to receive a sample; a light source configured to provide light to the interferometer at multiple wavelengths (λi), where the light is directed to the sample by optics of the interferometer; and optical path delay (OPD) modifying optics configured to enhance contrast in an interferometer output associated with the sample, the interferometer output captured by a detector at each of the multiple wavelengths (λi). In one or more aspects of these embodiments, the light can be a band of light having wavelengths centered about the wavelength (λi). The light source can comprise light emitting diodes (LEDs) or lasers configured to provide the light at the multiple wavelengths (λi). The light source can comprise a tunable light emitting diode (LED) or a tunable laser configured to provide the light at the multiple wavelengths (λi).
In one or more aspects of these embodiments, the system can comprise one or more filters configured to filter broadband light to provide the interferometer output at each of the multiple wavelengths (λi). The light source can comprise a broadband light source. The one or more filters can comprise a plurality of bandpass filters in the light source. The one or more filters can comprise a pixelated filter mask. The OPD modifying optics can comprise one or more birefringent crystals and one or more polarizers. The OPD modifying optics comprise one or more phase plate. The OPD modifying optics further comprise a 4-f optical system or an equivalent imaging system. The interferometer can comprise a light microscope.
In another embodiment, an apparatus for quantitative imaging or sensing of a sample comprises optical path delay (OPD) modifying optics configured to modify an interferometer output associated with a sample illuminated in an interferometer by light at one or more defined wavelength (λi); and an add-on unit containing the OPD modifying optics, the add-on unit configured to attach to the interferometer thereby aligning the OPD modifying optics with the interferometer output, and configured to attach to a detector configured to record the interferometer output. In one or more aspects of these embodiments, the interferometer can comprise a light microscope. The light can come from a light source configured to change wavelength without using filters.
In one or more aspects of these embodiments, the OPD modifying optics comprise a phase plate positioned between relay lenses. The add-on unit can comprise one or more filters aligned with the OPD modifying optics. The one or more filters can comprise a pixelated filter mask or a plurality bandpass filters. The OPD modifying optics can comprise at least one birefringent crystals and at least one polarizer. The add-on unit can be configured to switch between different configurations of the OPD modifying optics.
Other systems, methods, features, and advantages of the present disclosure will be or become apparent to one with skill in the art upon examination of the following drawings and detailed description. It is intended that all such additional systems, methods, features, and advantages be included within this description, be within the scope of the present disclosure, and be protected by the accompanying claims. In addition, all optional and preferred features and modifications of the described embodiments are usable in all aspects of the disclosure taught herein. Furthermore, the individual features of the dependent claims, as well as all optional and preferred features and modifications of the described embodiments are combinable and interchangeable with one another.
Many aspects of the present disclosure can be better understood with reference to the following drawings. The components in the drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the present disclosure. Moreover, in the drawings, like reference numerals designate corresponding parts throughout the several views.
Disclosed herein are various embodiments related to imaging and sensing using interferometry. This technology can be used to quantify the complex field of a sample, offering a combination of low cost, simple implementation, high speed and/or high sensitivity. Its applications include but are not limited to imaging and measurement of biological or non-biological specimens, solid or liquid surfaces, or other samples. The disclosed technique is compatible with a wide variety of existing interferometers, and may be implemented with minimal hardware modification, allowing for easy interfacing and upgrade. Various aspects can also be integrated with mobile devices to generate a new category of portable imaging and sensing devices. Reference will now be made in detail to the description of the embodiments as illustrated in the drawings, wherein like reference numbers indicate like parts throughout the several views.
Interferometry often measures the optical path delays (OPD, or optical pathlength difference) associated with a sample, which may be transparent, translucent, opaque, scattering or reflective. In a transparent/translucent sample, the OPD is usually caused by the change of the speed of light due to varying refractive index and/or thickness of the sample. In an opaque/reflective sample, OPD is typically caused by the difference in surface height at different locations. Some interferometric techniques measure the sample path delay by comparing it to that of a reference light field. This is called two-beam interferometry, and the OPD between the two beams is an important parameter. The methodology can also be applied to interferometry based on three or more beams or continuous wave field interferometry.
Referring to
One advantage of the disclosed system 100 is its simple implementation and low cost potential. The technology can be used in a wide variety of interferometry systems with no or minimal modification of the existing interferometer 106, enabling easy interfacing and upgrade. The methodology also permits the use of both narrow bandwidth lasers and low coherence (spatial or temporal) sources, and thus can be applied in not only traditional laser-based interferometry but also in low coherence interferometry, such as low coherence holography.
The light source 103 can be configured to emit a range of wavelengths. Examples of light sources 103 include, but are not limited to, halogen lamps, light emitting diodes (LED), edge-emitting LEDs, superluminescent diodes (SLD), tunable/swept wavelength sources (or lasers), or a combination of multiple lasers. Other suitable light sources 103 can also be utilized. In some implementations, the light source 103 can include filtering to facilitate the provision of a single wavelength λi of light or a fixed range (or band) of wavelengths about λi. A plurality of wavelengths (or wavelength bands) can be used to the imaging and sensing. For example, two, three, four, five or more wavelengths (or bands) λi can be used for imaging the sample. The wavelengths (or bands) can be evenly spaced within a wavenumber domain, or can be distributed in a different fashion (e.g., separated by linearly increasing distances or other specified distribution). The bandwidth can also be the same for each of the wavelength bands or can vary based upon any of a variety of factors.
The detector 109 can be a photodetector or image capture device such as, but is not limited to, photodiodes (PDs), avalanche PDs, photomultipliers, CCD/EMCCD/CMOS (charged-coupled device/electron multiplying CCD/complementary metal-oxide-semiconductor) line or area cameras and other types of cameras, or other suitable photodetectors. Image capture devices can include scientific grade cameras used in research labs or consumer cameras including cameras on laptops, cellphones, tablets or other mobile devices.
Processing of the recorded interferometer data (e.g., camera images) can utilize modeling of the corresponding interferometric process. Existing algorithms of multi-shot interferometry, such as phase-shifting interferometry (PSI), may be used. In alternative implementations, algorithms based on regression (fitting), such least square methods, or other appropriate modeling can be used. Numerical solutions such as those based on, e.g., least square regression can be used for processing the recorded interferometer data at the different wavelengths. The center wavelengths, their bandwidth and spectral shape can be determined for the wavelength bands using the measured data, and this information can used as known parameters for the algorithms.
The interferometer 106 can be any of a wide variety of configurations. Examples of interferometers 106 include, but are not limited to, Fabry-Pérot interferometers, Michelson interferometers, Mach-Zehnder interferometers, Linnik interferometers, Fizeau interferometers, Sagnac interferometers, or other interferometers that utilize PhC microscopy, DIC microscopy, diffraction phase microscopy, Fourier ptychography, and/or holography.
The optics in both the reference and sample arms of the interferometer 106 can vary depending on the imaging requirements. For instance, 4-f optical systems or other equivalent imaging systems can be inserted to change resolution and/or field of view or to facilitate path length matching or mismatching. The interferometer 106 can also contain beamsplitters, which can be optical fiber-based (e.g., a fiber-optic coupler), or free space-based (e.g., a beamsplitter cube), or can be based upon other suitable components.
For some interferometers, the OPD between the reference and sample signals may not be optimal for the desired application. To improve or optimize the output, OPD modifying optics 112 can be added at various positions in the system 100. As illustrated in
In one embodiment, the OPD modifying optics 112 comprise a birefringent crystal inserted in a DIC microscope to achieve quantitative DIC imaging. The crystal can be any type of crystal that produces birefringence. A typical DIC microscope has an OPD between the two polarizations of light on the order of a fraction of the system wavelength. The inserted birefringent crystal can increase (or sometimes decrease) this OPD to achieve an improved or optimal operating condition. The “optimal operating conditions” can provide higher measurement sensitivity for the interferometry system 100.
The birefringent crystal can be inserted almost anywhere in the microscope. As shown in
In another embodiment, two or more birefringent crystals can be inserted for quantitative polarized light imaging to quantify sample birefringence. The orientation of each of the birefringent crystals may be different to create polarization mixing in order to encode a sample birefringence signal into the detected signal, which is different for each wavelengths. In addition to the polarizers already in the interferometer 106, additional polarizers may be included depending on the location of the inserted crystals.
In another embodiment, a PhC microscope can be used for quantitative PhC imaging. The typical OPD is sub-wavelength between the un-diffracted surround (reference) wave and the diffracted sample wave of the PhC microscope. As shown in
In another embodiment, a Mach-Zehnder interferometer can be used. The OPD can be modified by adding glass plates of different thickness in the sample and reference arms, or by slightly changing the distance of the optical components. This will be discussed further below.
The light source 103 is configured to generate multiple wavelengths (λi) of light or bands of wavelengths centered at λi, which can be accomplished in a variety of ways.
In other embodiments of the interferometry system 100, the light source 103 can comprise multiple LEDs and/or lasers configured to generate multiple wavelengths (or wavelength bands) λi of light as shown in
Referring next to
While the swept source scans, within the exposure time, the camera will capture the interference for a band of wavelength centered at λi (or wavenumber ki). The interference intensity can be written as:
Ii(x,y)=Ai+Bi cos kiL,i=1, . . . ,N, (1)
where Ai and Bi are intensity constants and ki=2π/λi is the wavenumber and L is the OPD between the sample and reference arms. To modify and optimize L, glass slides and coverslips can be inserted into one or both of the sample and reference arms.
As an example, assume that N=4 and that ki are evenly spaced in the wavenumber domain (e.g., 870 nm, 849.04 nm, 829.06 n, and 810 nm). The wavenumbers can then be written as:
ki=k0+(2i−5)Δk,i=1,2,3,4, (2)
where k0 is the center of the full scan range and 2Δk is the spacing. Using Carre's equation and assuming Ai's and Bi's are independent of i, the (wrapped) OPD of the sample is given by:
Calculating L for every image point will produce the OPD image of the sample.
In addition, the simulated sensitivity of the interferometry system 100 of
From the sensitivity plot of
The result indicates that for the setup of
In many quantitative phase imaging (QPI) systems, phase shifting interferometry (PSI) is the enabling technique. The incorporation of the PSI techniques in conventional interferometers typically requires substantial customization of an otherwise conventional interferometer. A potential solution is wavelength shifting interferometry (WSI), a technique that removes the phase shifter and the associated need for interferometer modification. Instead, the phase shift is generated by a wavelength change of the light source. Traditional WSI techniques, such as discrete wavelength stepping and bucket integrating methods, are based on highly coherent tunable lasers. They are often associated with severe coherence artifacts, limiting their applications in high quality imaging of microscopic objects such as biological cells.
Low coherence wavelength shifting interferometry (LC-WSI) was implemented using the interferometry system 100 of
For the operation of LC-WSI, consider the interference between two fields Us and Ur, for example, the sample and reference fields. Intensity at the detector 109 can be expressed as a function of time delay z between the two fields:
I(τ)=|Us|2+|Ur|2+2|Us∥Ur|Re{Γ(τ)}, (4)
where Γ(τ) is the temporal correlation function. According to the generalized Wiener-Khintchin theorem, Γ(τ) is also the Fourier transform of the normalized source power spectrum density S(ω). Assuming this spectral shape is centered at ω1, a shifted spectrum can be defined as S1(ω)=S(ω+ω1), and Γ(τ) can be further given as:
Γ(τ)=∫S1(ω−Ω1)ejωτdω=ejω
wherein |γ1(τ)| and ξ1(τ) are the magnitude and phase responses of the Fourier transform of S1(ω), respectively. Note that ω1τ=k1L, in which k1 is the wavenumber corresponding to ω1 and L is the optical pathlength (OPL) difference (or OPD) between the two fields. Therefore in LC-WSI, for the n-th wavelength band with center wavenumber kn, the detected intensity can be obtained by combining Eqs. (4) and (5):
Equation (6) can be further simplified under several conditions: (1) the spectrum of each band is symmetric about its own kn so that ξn=0; (2) all N bands have a common spectral shape, which means |γn(τ)| are identical; (3) the intensity ratios Usn/Urn are the same for all bands; (4) kn are evenly spaced by Δk. For the case of four-band LC-WSI (N=4), Eq. (6) can now be rewritten as:
where a and b are magnitude constants independent of n, k0=(k1+k4)/2 is the center wavenumber of the full spectrum, and the additional phase terms ϕn, although unknown because of L, are evenly spaced by Δϕ=ΔkL. In the following, In is used to represent the normalized intensity in the left-hand side of Eq. (7).
Eq. (7) is a special case of LC-WSI, but has the exact mathematical form that can be processed by the Carre algorithm designed for PSI. The OPL can thus be demodulated as:
which is a modified version of the original Carré equation with the addition of a signum function to resolve the quadrant ambiguity of the arctangent function. It produces the OPL image of the sample. When sample OPL is too large and thus wrapped, Eq. (8) can be followed by a routine 2D unwrapping process.
To demonstrate above principle, the Mach-Zehnder interferometer-based system of
The low coherence operation of LC-WSI can minimize various types of coherence noises. The camera 109 operated at a rate of 250 fps, equivalent to an imaging rate of 62.5 Hz. Finally, the above conditions to use Eq. (7) were indeed met: (1) and (2) was satisfied with the swept source, which exhibits a substantially even spectrum response across the full sweeping range; (3) was typically true for transparent phase objects and determined only by the splitting ratio of the interferometer; and (4) was satisfied by the linear k sweep. Further, the intensity normalization in Eq. (7) can be implemented using the reference arm intensity obtained by blocking the sample arm.
To demonstrate the behavior of the system, its performance was simulated. The same center wavelengths and bandwidths as in actual experiments were used. Signal strength and the associated shot noise were simulated based on the measured electron saturation capacity of the camera (9000 e−). In for a wide range of L were generated and processed respectively by both original Carré equation and the modified version in Eq. (8).
Further, to better visualize noise performance of the unwrapped L′, the demodulation was repeated 100 times with random noises and the results plotted together as the shaded background in plots “c” and “d” of
The ambiguity issue shown in plot “a” of
In comparison, a simple sgn(·) term is added in Eq. (8) to achieve equivalent results. But Eq. (9) offers important insights into the cause of the inflection points in plot “d” of
The feasibility of LC-WSI for quantitative phase imaging was demonstrated using human red blood cells (RBCs). A drop of whole blood was sandwiched by a No. 1.5 coverslip and a microscope slide and placed on the sample stage of the interferometer 106. As a first step, the OPL difference between the two arms was ensured to be within the optimal range. This was achieved by taking advantage of the swept laser source in the light source 103. Before the four-band experiments, the laser was slowly swept and interferograms recorded at a large number of wavenumber positions and with narrow linewidth. Plot “a” of
Next, the system sensitivity was characterized with a water-filled, blank sample chamber. Temporal measurement sensitivity was quantified by acquiring 100 consecutive OPL images of this sample and calculating the standard deviation for each image pixel of the recorded interferometer data. The average sensitivity across the field of view (FOV) was 2.33 nm, in excellent agreement with the simulated result. This sensitivity can be further improved by spatial filtering in the Fourier domain to remove out-of-band noise since the camera oversamples the recorded image. The spatial-frequency passband was determined by imaging a piece of lens tissue, whose fine structures fill the bandwidth.
With a high acquisition rate and high sensitivity, the interferometry system 100 is capable of imaging dynamic biological specimens such as sperm cells. It has been reported that sperm morphology is highly correlated to its quality. For example, with intracytoplasmic morphologically selected sperm injection, the pregnancy rates of in vitro fertilization can be improved. For experiment validation, boar semen was collected, extended and diluted with sperm wash medium.
An application of OPL images is to calculate the dry mass and/or volume of the cell. The conversion between OPL values and the total dry mass of cell within an enclosed area s can be expressed as:
where χ≈0.18 cm3/g is a conversion coefficient. Since the sperm cell is in constant motion, the integral accuracy will be affected by the spatial variation of background, which is evident in image “a” of
The real-time dry mass can be calculated with an automatic edge-detection based algorithm to generate a mask for the sperm head as illustrated in plot “d” of
The LC-WSI technique and its application to dynamic QPI has been demonstrated using the interferometry system 100 of
The disclosed techniques can be easily implemented on commercial microscopes. As shown in
As discussed with respect to
The OPD modifying optics 112 can also be utilized with conventional microscope body to provide quantitative polarized light (birefringence) imaging through multi-wavelength interferometry as illustrated in
The light source 103 can also be configured as an add-on unit that can be attached or coupled to the interferometer (or microscope) 106. The light source 103 can include a broadband light source 403, multiple LEDs and/or lasers 412, or tunable LEDs and/or lasers 412 to provide the different wavelengths (or wavelength bands) λi. The add-on unit can also include bandpass filter(s) 406 for the broadband source 403 as previously discussed. In some embodiments, the light source 103 can be included in a common add-on unit with the OPD modifying optics 112. The light source 103 and detector 109 may also be provided in a common device such as, e.g., a cellphone or tablet. For example, a smartphone can provide a broadband light source 403 for the light source 103 and a camera as the detector 109. The add-on unit can be configured to allow the smartphone, cellphone or tablet to be attached and aligned with the optics to record the interferometer data from the output of the interferometer (or microscope) 106 and/or direct the light from the broadband light source 403 to the interferometer (or microscope) 106.
Next, an interferometry system 100 using a common-path, reflective interferometer configuration including OPD modifying optics 112 is presented, as illustrated in
The interferometry system 100 of
Signal propagation through the system 100 can be analyzed with Jones calculus using the schematic representation of
First analyze birefringence imaging, i.e. without the Nomarski prism 1512 in
where R is the rotation matrix and T is the transmission matrix for polarizing components, as in:
Additionally, θC(k)=kLC(x,y), θB(k)=kLB(x,y), and θS(k)=kLS(x,y), where k is the wavenumber, LC is the optical pathlength (OPL) retardation of the crystal retarder, and LB(x,y) and LS(x,y) stand for the retardation of system birefringence and sample birefringence at (x,y), respectively.
Since both LB and LS in live cell imaging are typically small compared to the wavelength, small angle approximation is valid for θB and θS. With Eqs. (11) and (12), the detected interference spectrum can be shown to be:
I=I0(k)|E0|2=IDC(k)+[I1f(k)+c.c]+[I2f(k)+c.c.], (13)
where I0(k) is the spectrum envelope,
and c. c. denotes the complex conjugate of the corresponding terms. Eq. (4) clearly indicates that I1f and I2f are two interference terms in the detected spectrum with carriers of ejkL
Based on above derivation, we can perform a system birefringence calibration without sample to acquire AB and BB, and remove them from sample measurement to obtain AS and BS. only for the determination of sample birefringence parameters.
As for the choice of a, a wide range of angles may be used except when sin 4α=0 or sin2 2α=0 in Eq. (14). A detailed sensitivity analysis and experimental validation regarding a for spectral multiplexing interferometry based birefringence measurement can be found in “Quantitative polarized light microscopy using spectral multiplexing interferometry” by C. Li, and Y. Zhu (Opt. Lett., 40(11), 2622-2625, 2015)., which is hereby incorporated by reference in its entirety. Since here IDC(k) is sample independent with small angle approximation, we now set α at 31.7° so that sin 4α=sin2 2α, which leads to identical coefficients for both interference terms in Eq. (14). Thus the sensitivity of both sample birefringence retardation and azimuth angle will be independent of sample birefringence orientation.
With knowledge of α f, I0(k) can also be determined from IDC. The signal demodulation hence involves bandpass filtering of I1f and I2f, normalizing them using α and I0, and frequency downshifting. With the carrier waves obtained from the interference spectra without sample, I1f and I2f can be downshifted to baseband for extracting AS and BS from the imaginary part of the complex amplitude after removing AB and BB. Sample birefringence is therefore:
where avg(·) denotes averaging over the range of k. This process allows the background-free measurement of LS and β from one single spectrum.
To demonstrate the birefringence imaging capability, Plasmodium falciparum-infected human RBCs was chosen. During their asexual replication cycle within RBCs, malaria parasites consume host cell hemoglobin and produce birefringent hemozoin crystals. For imaging, an in vitro culture of P. falciparum-infected erythrocytes was fixed with 0.1% glutaraldehyde in phosphate buffered saline (PBS). Fixed parasites were then washed with PBS to remove glutaraldehyde prior to imaging.
To quantify RBC birefringence, system birefringence background is first calibrated. An example of the system birefringence background is illustrated in
Image “e” shows the birefringence retardation image of the P. falciparum-infected human RBCs after background subtraction based on Eqs. (14) and (15), with a scale bar of 20 μm. Among the imaged cells, the infected ones can be clearly identified by the hemozoin crystals inside. The magnitude of hemozoin birefringence retardation in the infected RBCs is about 30 nm and is much stronger than the birefringence of the cell body, which is believed to be originated largely from local heterogeneity. Enlarged birefringence retardation images of two single infected RBCs from image “e” are depicted in “f” and “g” with a scale bar of 2 μm. The slow axis orientation is illustrated in the inset images, where the line direction and length indicate the local optical axes orientation and birefringence retardation of the hemozoin crystals. One and two crystals are revealed respectively with the birefringence slow axis distributed uniformly for each crystal. The presence of two crystals likely indicates that this red cell has been invaded by two parasites.
In addition to single-shot birefringence imaging, the same setup can also be used for quantitative DIC imaging. Note that as shown in
where Ts1 and Ts2 denote the respective transmission matrices for sample retardation for the two waves at their corresponding positions,
Similar to birefringence imaging, Eq. (17) can be expanded and the second interference term (2f) can be obtained as:
For non-birefringent samples, the o- and e-waves are identical. When system birefringence is also ignored, Eq. (9) can be simplified to:
which, as expected, is essentially identical to the previously reported expression. The quantitative DIC signal is simply the phase of the downshifted I2f.
In contrast, for birefringent samples, the OPL gradient term in I2f is ejk(L
Referring to
Further, with these two directional OPL gradient images and 2D phase reconstruction algorithms, quantitative phase image of the sample can be obtained, as shown in
The spatial and temporal sensitivity of the integrated phase are also calibrated using a gold mirror. The spatial sensitivity of the QPI was measured as phase having a normal distribution of σs=64.6 pm across the full field, as seen in the plot “b” (scale bar=20 μm) and the quantitative phase histogram of the full field in plot “c.” The temporal sensitivity between 100 consecutive acquisitions is also calibrated in the histogram in plot “d”, obtaining a lower noise level of σt=51.7 pm. Silica microsphere size standards (e.g., Corpuscular Inc., ϕ=6.4 μm) are used to validate the quantitative phase imaging accuracy. Images “e” and “f” are the DIC images of silica microspheres with horizontal and vertical shear, respectively. The physical width and height of the silica microspheres, as labelled in plot “g” (scale bar=5 μm) are consistent with the manufacture's specification. The inset illustrates the physical thickness curve along the line across the upper microsphere.
In conclusion, a dual-modality system for quantitative birefringence and phase imaging has been demonstrated. Imaging modes can be easily switched by the insertion and removal of a Nomarski prism. A unified theoretical treatment provides rigorous foundation for both techniques. From the theory, a process for system birefringence background subtraction is derived to improve birefringence measurement accuracy. This is important for imaging live cells, whose birefringence is often weak and can be significantly distorted by the background. The theory also enables the correction of birefringence-induced phase error, and thus opens doors to precision phase imaging of birefringent samples. Experiments on P. falciparum-infected human RBCs demonstrate the system's capability for highly sensitive birefringence, DIC and phase imaging. Hemozoin crystals were visualized with high contrast and can potentially be used for quantitative studies of crystal formation and growth. This highly integrated system may find applications in label-free imaging of biological specimens where multiple intrinsic contrasts are desired.
It should be emphasized that the above-described embodiments of the present disclosure are merely possible examples of implementations set forth for a clear understanding of the principles of the disclosure. Many variations and modifications may be made to the above-described embodiment(s) without departing substantially from the spirit and principles of the disclosure. All such modifications and variations are intended to be included herein within the scope of this disclosure and protected by the following claims.
The quantitative images or measurements obtained by this invention can be used in a wide range of applications. It may be used in life sciences R&D to quantify cell growth, proliferation, death, viability, motility, migration, mass transport, biophysics and biomechanics for applications in areas such as developmental biology, oncology, stem cells, drug development and neuroscience. It may also be used for quantitative, label-free pathology for disease diagnosis, and for computational super-resolution. Another application is to monitor cell culture for production quality control in bio-processing industry. Further, the quantitative information can be used for in vitro diagnostics, such as quality assessment of oocytes, sperm and embryos for in vitro fertilization. The technique may also be used in metrology and materials science for device and material characterization.
It should be noted that ratios, concentrations, amounts, and other numerical data may be expressed herein in a range format. It is to be understood that such a range format is used for convenience and brevity, and thus, should be interpreted in a flexible manner to include not only the numerical values explicitly recited as the limits of the range, but also to include all the individual numerical values or sub-ranges encompassed within that range as if each numerical value and sub-range is explicitly recited. To illustrate, a concentration range of “about 0.1% to about 5%” should be interpreted to include not only the explicitly recited concentration of about 0.1 wt % to about 5 wt %, but also include individual concentrations (e.g., 1%, 2%, 3%, and 4%) and the sub-ranges (e.g., 0.5%, 1.1%, 2.2%, 3.3%, and 4.4%) within the indicated range. The term “about” can include traditional rounding according to significant figures of numerical values. In addition, the phrase “about ‘x’ to ‘y’” includes “about ‘x’ to about ‘y’”.
This application is the 35 U.S.C. § 371 national stage application of PCT Application No. PCT/US2017/016499, filed Feb. 3, 2017, where the PCT claims priority to, and the benefit of, U.S. provisional application entitled “Methods and Apparatus of Interferometry for Imaging and Sensing” having Ser. No. 62/290,507, filed Feb. 3, 2016, both of which are herein incorporated by reference in their entireties. This application claims priority to, and the benefit of, U.S. provisional application entitled “Methods and Apparatus of Interferometry for Imaging and Sensing” having Ser. No. 62/290,507, filed Feb. 3, 2016, the entirety of which is hereby incorporated by reference.
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PCT/US2017/016499 | 2/3/2017 | WO |
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WO2017/136721 | 8/10/2017 | WO | A |
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