1. Field of the Invention
The technology of the present application relates generally to low-coherence interferometry (LCI) and obtaining structural and depth-resolved information about a sample using LCI. The technology includes angle-resolved-based LCI (a/LCI), Fourier-based LCI (f/LCI), and Fourier and angle-resolved-based LCI (fa/LCI) apparatuses, systems, and methods.
2. Technical Background
Examining the structural features of cells is essential for many clinical and laboratory studies. The most common tool used during examination for the study of cells has been the microscope. Although microscopic examination has led to great advances in understanding cells and their structure, it is inherently limited by the artifacts of preparation. The characteristics of the cells can only been seen at one moment in time with their structural features altered because of the addition of chemicals. Further, invasion is necessary to obtain the cell sample for examination.
Thus, light scattering spectroscopy (LSS) was developed to allow for in vivo examination applications, including cells. The LSS technique examines variations in the elastic scattering properties of cell organelles to infer their sizes and other dimensional information. In order to measure cellular features in tissues and other cellular structures, it is necessary to distinguish the singly scattered light from diffused light, which has been multiply scattered and no longer carries easily accessible information about the scattering objects. This distinction or differentiation can be accomplished in several ways, such as the application of a polarization grating, by restricting or limiting studies and analysis to weakly scattering samples, or by using modeling to remove the diffused component(s).
As an alternative approach for selectively detecting singly scattered light from sub-surface sites, low-coherence interferometry (LCI) has also been explored as a method of LSS. LCI typically utilizes a broadband light source with low temporal coherence, such as a broadband white light source, for example. Interference is achieved when the path length delays of the interferometer are matched with the coherence time of the light source. The axial resolution of the system is determined by the coherence length of the light source and is typically in the micrometer range suitable for the examination of tissue samples. Experimental results have shown that using a broadband light source and its second harmonic allows the recovery of information about elastic scattering using LCI. LCI has used time domain depth scans by moving the sample with respect to a reference arm directing the light onto the sample to receive scattering information from a particular point on the sample. Thus, scan times were on the order of five (5) to thirty (30) minutes in order to completely scan the sample.
Angle-resolved LCI (a/LCI) has been developed as a means to obtain sub-surface structural information regarding the sizes of a cell and its components such as nuclei and mitochondria. a/LCI has been successfully applied to measuring cellular morphology in tissues and in vitro as well as diagnosing intraepithelial neoplasia and assessing the efficacy of chemopreventive agents in an animal model of carcinogenesis. a/LCI has also been used to prospectively grade tissue samples without tissue processing, demonstrating the potential of the technique as a biomedical diagnostic.
In a/LCI, light is split into a reference beam and a sample beam, wherein the sample beam is projected onto the sample at an angle to examine the angular distribution of scattered light. The a/LCI technique combines the ability of LCI to detect singly scattered light from sub-surface sites with the capability of light scattering methods to obtain structural information with sub-wavelength precision and accuracy to construct depth-resolved tomographic images. Structural information is determined by examining the angular distribution of the back-scattered light using a single broadband light source that is mixed with a reference field with an angle of propagation. The size distribution of the cell and its components such as nuclei or mitochondria can be determined by comparing the oscillatory part of the measured angular distributions to predictions.
Initial prototype and second generation a/LCI systems required approximately thirty (30) and five (5) minutes respectively to obtain similar data. The method of obtaining angular specificity to obtain structural information about a sample was achieved by causing the reference beam of the interferometry to cross the detector plane at a variable angle. However, these a/LCI systems relied on time domain depth scans just as provided in previous LCI-based systems. The length of the reference arm of the interferometer had to be mechanically adjusted to achieve serial scanning of the detected scattering angle to obtain depth information regarding a sample.
Embodiments disclosed herein involve low-coherence interferometry (LCI) techniques which enable acquisition of structural and depth information regarding a sample of interest at rapid rates. The acquisition rate is sufficiently rapid to make in vivo applications feasible. Biomedical applications of the embodiments disclosed herein include using the a/LCI systems and processes described herein for measuring cellular morphology in tissues and in vitro as well as diagnosing intraepithelial neoplasia, and assessing the efficacy of chemopreventive and chemotherapeutic agents. Prospectively grading tissue samples without tissue processing can also be accomplished using the embodiments disclosed herein, demonstrating the potential of the technique as a biomedical diagnostic.
In one embodiment, a “swept-source” (SS) light source is used in LCI to obtain structural and depth information about a sample. The swept-source light source is used to generate a reference signal and a signal directed towards a sample. Light scattered from the sample is returned as a result and mixed with the reference signal to achieve interference and thus provide structural information regarding the sample. By “swept-source,” the light source is controlled to sweep emitted light over a given range of wavelengths in time. Because the emitted light is broken up into particular wavelengths or narrower ranges of wavelengths during emission, scattered light returned from the sample is known to be in response to a particular wavelength or range of wavelengths. Thus, the returned scattered light is spectrally-resolved and depth-resolved, because the returned light is in response to the light source emitted light over a spectral domain. This is opposed to a wider or broadband light source that generates a wider range wavelengths of light in one light emission in time, wherein the returned scattered light from the sample contains scattered light at a wider range of wavelengths. In this instance, a spectrometer may be required to spectrally-resolve the returned scattered light. However, when using a swept-source light source, the series of returned scattered lights from the sample at each wavelength are already in the spectral domain to provide spectrally-resolved information about the sample.
Several LCI embodiments employing a swept-source light source are disclosed herein. For example, one LCI embodiment disclosed herein involves using a swept-source light source in angle-resolved low-coherence interferometry (a/LCI). This is also referred to as swept-source a/LCI (SS a/LCI). The swept-source light source is employed to generate a reference signal and a signal directed towards a sample over the swept range of wavelengths or ranges of wavelengths. The light is either directed to strike the sample at an angle, or the light source or another component in the system (e.g., a lens) is moved to direct light onto the sample at a plurality of angles. This causes a set of scattered light to be returned and dispersed from the sample at a plurality of angles, thereby representing spectrally-resolved and angle-resolved scattered information about the sample from a plurality of points on the sample.
The spectrally-resolved and angle-resolved scattered information about the sample can be detected at a single scattering angle to provide a single scattering plane (i.e., 1-dimension) of spectrally-resolved and angle-resolved scattered information about the sample. Alternatively, the spectrally-resolved and angle-resolved scattered information about the sample can be detected at a plurality or range of angles to provide two-dimensional spectrally-resolved and angle-resolved scattered information about the sample. Capture of two-dimensional spectrally-resolved and angle-resolved scattered information from multiple scattering angles allows generation of more information about the sample under study and/or information with higher signal-to-noise ratio.
Depth information about the sample can be obtained using Fourier domain concepts as well as time domain techniques when using SS a/LCI. For example, in one manner of using time domain techniques to obtain depth information, the sample can be moved with respect to the light source to direct light at different planes within the sample. The resulting scattered light is processed to determine depth characteristics about the sample of interest. When using Fourier techniques as an example, the spectrally-resolved distribution of the scattered light returned from the sample as a result of the light emitted by the swept-source light source is converted into the Fourier domain. This allows obtaining depth-resolved information about the sample. Because the light source is swept, a spectrometer is not required to obtain spectral information about the sample, because the returned scattered light from the sample is already in the spectral domain as a result of a series of data acquisitions collected in narrower wavelengths or ranges emitted by the light source during its sweep. Scattering size characteristic information about the sample can be obtained by processing the spectrally-resolved and depth-resolved profile.
In another embodiment disclosed herein, a multiple channel time-domain a/LCI system and method is provided employing a broadband light source. This technique physically scans the depth in the time domain, but unlike other previous a/LCI systems and methods, the angular distribution of scattered light returned from the sample is detected at a plurality of angles simultaneously to obtain angle-resolved information about the sample. The light source generates a reference signal which is directed towards a sample. The light is either directed to strike at an angle, or the light source or another component in the system (e.g., a lens) is moved to direct the light onto the sample at a plurality of angles. This causes a set of scattered lights to be returned from the sample scattered at a plurality of angles off of the sample, thereby representing angle-resolved scattered information about the sample from a plurality of points on the sample.
In yet another embodiment, a Fourier LCI system and method with serial detection of angular scatter information about the sample are provided. An a/LCI system is used to collect the angular distribution information from the sample in a serial fashion by moving the angle at which the light from the light source is directed to the sample. Depth information about a sample can be determined in the spectral domain using a Fourier domain approach with either a broadband light source with a spectrometer or a swept-source light source with a detection device. For the broadband light source, the system and method do not use the time domain approach and thus movement of the reference arm with respect to the sample to obtain time domain-based data is not needed. This system and method can also be implemented with a swept-source light source in place of the broadband light source.
In another embodiment, a multi-spectral a/LCI approach can be used to obtain structural and depth-resolved information about a sample. A narrower band light source is employed to generate a reference signal and a signal directed towards a sample a number of times to obtain a series of data acquisitions. The light may be emitted directly onto the sample for LCI or at a scatter angle for a/LCI. The reference signal and the returned scattered light from the sample are mixed or cross-correlated to provide spectral information about the sample. Performing this method numerous times at a plurality of wavelengths provides spectral information about the sample. Depth information about the sample can be obtained using Fourier domain concepts as well as time domain techniques.
Various apparatuses and systems can be employed in the aforementioned systems and methods. For example, in one embodiment, the apparatus is based on a light splitter system that splits the emitted swept-source light into a reference path and a sample path using a series of splitters and lenses. In another embodiment, an optical fiber probe can be used to deliver light from a swept-source light source and collect the scattered light from the sample of interest. A fiber optic bundle collector comprised of a plurality of optical fibers is particularly well-suited for detecting two-dimensional angle-resolved spectral information about the sample.
The LCI-based apparatuses, systems, and methods described above and in this application can be clinically viable methods for assessing tissue health without the need for tissue extraction via biopsy or subsequent histopathological evaluation. These LCI-based apparatuses, systems, and methods can be applied for a number of purposes including, but not limited to: early detection and screening for dysplastic tissues, disease staging, monitoring of therapeutic action, and guiding the clinician to biopsy sites. Some potential target tissues include the esophagus, the colon, the stomach, the oral cavity, the lungs, the bladder, and the cervix. The non-invasive, non-ionizing nature of the optical and LCI probe means that it can be applied frequently without adverse affect. The provision of rapid results through the use of the a/LCI systems and processes disclosed herein greatly enhance its widespread applicability for disease screening.
With reference now to the drawing figures, several exemplary embodiments of the present disclosure are described. The word “exemplary” is used herein to mean “serving as an example, instance, or illustration.” Any embodiment described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other embodiments.
Embodiments disclosed herein involve new low-coherence interferometry (LCI) techniques which enable acquisition of structural and depth information regarding a sample of interest at rapid rates. A sample can be tissue or any other cellular-based structure. The acquisition rate is sufficiently rapid to make in vivo applications feasible. Measuring cellular morphology in tissues and in vitro as well as diagnosing intraepithelial neoplasia and assessing the efficacy of chemopreventive and chemotherapeutic agents are possible applications. Prospectively grading tissue samples without tissue processing is also possible, demonstrating the potential of the technique as a biomedical diagnostic.
In one embodiment, a “swept-source” (SS) light source is used in LCI to obtain structural and depth information about a sample. The swept-source light source is used to generate a reference signal and a signal directed towards a sample. Light scattered from the sample is returned as a result and mixed with the reference signal to achieve interference and thus provide structural and depth-resolved information regarding the sample. With a “swept-source,” the light source is controlled or varied to sweep the center wavelength of a narrow band of emitted light over a given range of wavelengths, thus synthesizing a broad band source. Because the light is emitted in particular wavelengths or narrower ranges of wavelengths during emission, scattered light returned from the sample is known to be in response to a particular wavelength or range of wavelengths. Thus, the returned scattered light is spectrally-resolved and depth-resolved, because the returned light is in response to the light source emitted light over a narrow spectral range. This is opposed to a wider or broadband light source that generates all wavelengths of light in one light emission in time, wherein the returned scattered light from the sample contains scattered light at a broad range of wavelengths. In this instance, a spectrometer is used to spectrally-resolve the returned scattered light. However, when using a swept-source light source, the series of returned scattered lights from the sample at each wavelength are already in the spectral domain to provide spectrally-resolved information about the sample. The spectrally-resolved information about the sample can be detected.
Another embodiment involves using a swept-source light source in angle-resolved low-coherence interferometry (a/LCI), referred to herein as “swept-source Fourier domain a/LCI,” or “SS a/LCI.” The data acquisition time for SS a/LCI can be less than one second, a threshold which is desirable for acquiring data from in vivo tissues. The swept-source light source is employed to generate a reference signal and a signal directed towards a sample over the swept range of wavelengths or ranges of wavelengths. The light is either directed to strike the sample at an angle, or the light source or another component in the system (e.g., a lens) is moved to direct light onto the sample at an angle or plurality of angles (i.e. two or more angles), which may include a multitude of angles (i.e. more than two angles). This causes a set of scattered light to be returned from the sample at a plurality of angles, thereby representing spectrally-resolved and angle-resolved (also referred to herein as “spectral and angle-resolved”) scattered information about the sample from a plurality of points on the sample. The spectral and angle-resolved scattered information about the sample can be detected. This SS a/LCI embodiment can also use the Fourier domain concept to acquire depth-resolved information. It has recently been shown that improvements in signal-to-noise ratio, and commensurate reductions in data acquisition time are possible by recording the depth scan in the Fourier (or spectral) domain. In this embodiment, the SS a/LCI system can combine the Fourier domain concept with the use of a swept-source light source, such as a swept-source laser, and a detector, such as a line scan array or camera, to record the angular distribution of returned scattered light from the sample in parallel and the frequency distribution in time.
Lenses (L3) 28 and (L4) 30 are arranged to produce a collimated pencil beam 32 incident on the sample 17 (step 66,
The light scattered by the sample 17 is collected by lens (L4) 30 (step 68,
In this embodiment, the detector device 26 is a one-dimensional detection device in the form of a line scan array, which is comprised of a plurality of detectors. This allows the detector device 26 to receive light at the plurality of scatterer angles from the sample 17 and mixed with the reference beam 14 at the same time or essentially the same time to receive spectral information about the sample 17. Providing the line scan array 26 allows detection of the angular distribution of the combined beams 44, or said another way, at multiple scatter angles. Each detector in the detector device 26 receives scattered light from the sample 17 at a given angle at the same time or essentially the same time.
Because the emitted light from the swept-source light source 12 is broken up into particular wavelengths or narrower ranges of wavelengths during emission, returned scattered light 34 from the sample 17 is known to be in response to a particular wavelength or range of wavelengths. Thus, the returned scattered light 34 is spectrally-resolved, because the returned scattered light 34 is in response to the light source emitted light over a spectral domain. This is opposed to a wider or broadband light source that generates all wavelengths of light in one light emission at the same time, wherein the returned scattered light from the sample contains scattered light at all wavelengths. In this instance, a spectrometer is used to spectrally-resolve the returned scattered light. However, when using the swept-source light source 12, the series of returned scattered light 34 from the sample 17 at each wavelength is already in the spectral domain to provide spectrally-resolved information about the sample.
I(λm,yn)=|Er(λm,yn)|2+2ReEs(λm,yn)Er*(λm,yn)cos φ, (1)
where Φ is the phase difference between the two fields and . . . denotes an ensemble average in time. The interference term is extracted by measuring the intensity of the scattered light 34 and reference beam 14 independently and subtracting them from the total intensity. In one method of obtaining depth-resolved information about the sample 17, the wavelength spectrum at each scattering angle is interpolated into a wavenumber (k=2π/λ) spectrum and Fourier transformed to give a spatial cross correlation, ΛSR(Z) for each vertical pixel yn:
ΛSR(z,yn)=∫dkeikzEs(k,yn)Er*(k,yn)cos φ. (2)
The reference field takes the form:
E
r(k)=Eoexp[−((k−ko)/Δk)2]exp[−((y−yo)/Δy)2]exp[ikΔl] (3)
where ko (yo and Δk (Δy) represent the center and width of the Gaussian wavevector (spatial) distribution and Δl is the selected path length difference. The scattered sample field takes the form
E
s(k,θ)=Eoexp[−((k−ko)/Δk)2]exp[iklj]Sj(k,θ) (4)
where Sj represents the amplitude distribution of the scattering originating from the jth interface, located at depth lj. The angular distribution of the scattered sample field is converted into a position distribution in the Fourier image plane of lens (L4) 30 through the relationship y=f4 θ. For the exemplary pixel size of the line scan array 26 of eight (8) to twelve (12) micrometers (μm), this yields an angular resolution of 0.00028 to 0.00034 mradians and an expected angular range of 286 to 430 mradians for a 1024 element array. Inserting Eqs. (3) and (4) into Eq. (2) and noting the uniformity of the reference field (Δy>>camera height) yields the spatial cross correlation at the nth vertical position on the detector:
Evaluating this equation for a single interface yields:
ΛSR(z,yn=|Eo|2exp[−((z−Δl+lj)Δk)2/8]Sj(ko,θn=yn/f4)cos φ. (6)
Here, it is assumed that the scattering amplitude S does not vary appreciably over the bandwidth of the source. This expression shows obtaining a depth-resolved profile of the scattering distribution with each vertical pixel corresponding to a scattering angle. The techniques described in U.S. patent application Ser. No. 11/548,468 entitled “Systems and Methods for Endoscopic Angle-Resolved Low Coherence Interferometry,” which is incorporated herein by reference in its entirety, may be used for obtaining structural and depth-resolved information regarding scattered light from a sample.
To obtain the same or similar data set as is obtained from a single frame capture from an imaging spectrometer using a broadband light source, the SS a/LCI apparatus and system 10 can capture a series of data acquisitions from the line scan array 26 at each wavelength and combine them. In this embodiment, the data acquisition rate of the line scan arrays 26 is less than the sweep rate of the swept-source light source 12. If one were to assume that 1000 wavelength (frequency) points are needed (and thus points in time for the swept-source), ten (10) to twenty (20) data acquisitions of scattered information from the sample 17 may be recovered per second using a line scan array. For example, this scenario could yield a time per acquisition of 50 to 100 milliseconds, which is satisfactory for clinical and commercial viability.
Line scan arrays and camera detector devices are widely available for both the visible and the near infrared wavelengths. Visible line scan arrays can operate from approximately ˜400 nm to ˜900 nm, for example, and may be based on silicon technology. Near infrared line scan arrays may operate from approximately ˜900 nm to ˜1700 nm or further. Table 1 below gives some typical specification from several manufacturers as examples.
As previously discussed above, a swept-source laser may be employed as the swept-source light source 12. Some examples are provided in Table 2 below.
Faster acquisition times are possible. Swept-source light sources at shorter wavelengths will allow use of a high speed detector 26, such as silicon detectors for example. For example, some Atmel® silicon-based cameras can achieve 100,000 lines per second, potentially allowing 100 data point acquisitions per second or 10 milliseconds per acquisition. Alternately, as another example, the line scan array 26 may be based on InGaAs technology and may be faster, reaching readout rates of 50,000 to 100,000 lines per second and thus reducing the acquisition time to 10 milliseconds. It is expected that the sweep rate, power, wavelength range, and other performance characteristics of the swept-source light sources can enable high performance versions of the a/LCI apparatuses and systems, including the SS a/LCI apparatus and system 10 of
In addition to obtaining depth-resolved information about the sample 17, the scattering distribution data (i.e., a/LCI data) obtained from the sample 17 using the disclosed data acquisition scheme can also be used to make a size determination of the nucleus using the Mie theory. A scattering distribution of the sample 17 is illustrated in
In order to fit the scattered data to Mie theory, the a/LCI signals are processed to extract the oscillatory component which is characteristic of the nucleus size. The smoothed data are fit to a low-order polynomial (2nd order is typically used but higher order polynomials, such as 4th order, may also be used), which is then subtracted from the distribution to remove the background trend. The resulting oscillatory component can then be compared to a database of theoretical predictions obtained using Mie theory from which the slowly varying features were similarly removed for analysis.
A direct comparison between the filtered a/LCI data and Mie theory data 78 may not be possible, as the Chi-squared fitting algorithm tends to match the background slope rather than the characteristic oscillations. The calculated theoretical predictions include a Gaussian distribution of sizes characterized by a mean diameter (d) and standard deviation as well as a distribution of wavelengths, to accurately model the broad bandwidth source.
The best fit (
As an alternative to processing the a/LCI data and comparing to Mie theory, there are several other approaches which could yield diagnostic information. These include analyzing the angular data using a Fourier transform to identify periodic oscillations characteristic of cell nuclei. The periodic oscillations can be correlated with nuclear size and thus will possess diagnostic value. Another approach to analyzing a/LCI data is to compare the data to a database of angular scattering distributions generated with finite element method (FEM) or T-Matrix calculations. Such calculations offer superior analysis as they are not subject to the same limitations as Mie theory. For example, FEM or T-Matrix calculations can model non-spherical scatterers and scatterers with inclusions while Mie theory can only model homogenous spheres. Other techniques are described in U.S. Pat. No. 7,102,758 entitled “Fourier Domain Low-Coherence Interferometry for Light Scattering Spectroscopy Apparatus and Method,” which is incorporated herein by reference in its entirety.
In another embodiment of the invention, an SS a/LCI apparatus and system can be provided, including for endoscopic applications, by using optical fibers to deliver and collect light from the sample of interest. These alternative embodiments are illustrated in
Turning now to
In the fiber optic SS a/LCI system 10′, the angular distribution of scattered light from the sample is captured by locating the distal end of the fiber bundle in a conjugate Fourier transform plane of the sample using a collecting lens. This angular distribution is then conveyed to the distal end of the fiber bundle where it is imaged using a 4f system onto the line scan array. A beam splitter is used to overlap the scattered sample field with a reference field prior to the line scan array so that low-coherence interferometry can also be used to obtain depth resolved measurements.
Turning to
The scattered sample field is detected using a coherent fiber bundle. The scattered sample field is generated using light in the signal arm 82 which is directed toward the sample of interest using lens (L2) 98. As with the free space system, lens (L2) 98 is displaced laterally from the center of single-mode fiber (F2) such that a collimated beam is produced which is traveling at an angle relative to the optical axis. The fact that the incident beam strikes the sample at an oblique angle is essential in separating the elastic scattering information from specular reflections. The scattered light 34′ is collected by a fiber bundle consisting of an array of coherent single mode or multi-mode fibers. The distal tip of the fiber is maintained one focal length away from lens (L2) 98 to image the angular distribution of scattered light. In the embodiment shown in
As illustrated in
There are several possible schemes for creating the fiber probe which are the same from an optical engineering point of view. One possible implementation would be a linear array of single mode fibers in both the signal and reference arms. Alternatively, a reference arm 96 could be composed of an individual single mode fiber with the signal arm 82 consisting of either a coherent fiber bundle or linear fiber array.
The probe 93 can also have several implementations which are substantially equivalent. These would include the use of a drum or ball lens in place of lens (L2) 98. A side-viewing probe could be created using a combination of a lens and a minor or prism or through the use of a convex minor to replace the lens-minor combination. Finally, the entire probe can be made to rotate radially in order to provide a circumferential scan of the probed area.
Another exemplary embodiment of a fiber optic SS a/LCI system is the illustrated a/LCI system 10″ in
Turning to
The use of a swept-source light source also opens up the possibility of another system architecture that has the capability to acquire scattering information from more than one scattering plane from a sample. This implementation is referred to as a “Multiple Angle Swept-source a/LCI” system or MA SS a/LCI. An example of an MA SS a/LCI system 10″ is illustrated in
The MA SS a/LCI system 10″ is exemplified in
The MA SS a/LCI system 10″ may also be implemented using a broadband light source, such as a superluminescent diode (SLD), and using a spectrometer detection device. In either case, whether using a broadband light source or swept-source light source 12″, in the fiber optic embodiment of a MA SS a/LCI system 10″, the fiber bundle 94 that receives the combined beams 44″ from the sample 17 can be captured by a plurality of optical fibers 119 in the fiber bundle 94, as illustrated in
One possible distribution of the scattering angles across the CCD camera 26″ is shown in
Potential components for the CCD camera 26″ include but are not limited to a Cascade:Photometrics™ 650 CCD camera as the image detector. For the light source, the Thorlabs INTUN™ continuously tunable laser is an example of one of many suitable sources. This example would be useful because the center wavelength is 780 nm, which is compatible with standard NIR optical elements, including the Cascade camera, and offers a tuning range of 15 nm, which is comparable to the line width used in SS a/LCI systems previously described. The tuning speed of 30 nm/s for this source is optimal for synchronization with the Cascade CCD camera as better than 0.1 nm resolution can be achieved based on the 300 Hz frame rate which can be realized when using a region of interest with the Cascade CCD. The SS a/LCI scheme will improve acquisition time and upgrade the a/LCI system to a state-of-the-art technology for studies of cell mechanics at faster time scales.
The data acquisition may be limited by the frame rate of the CCD camera 26″ and not by the sweep speed of the swept-source light source 12″. Table 3 below lists exemplary CCD cameras. The fastest listed is only 1000 frames per second, so if 1000 wavelength points are required, a full scan will take approximately 1 second. It may be possible to scan faster if fewer pixels are needed in this example, or if fewer points in wavelength can be used. Several of these cameras will let the user target specific regions of interest to acquire images, thus speeding up the frame rate. For example, with the Atmel® camera, if one uses a region of interest that is 100×100 pixels for a total of 10000 pixels, then the frame rate might be as high at 15,000 frames per second allowing a scan time of 70 milliseconds for 1000 wavelength points. It is expected that the speed of the CCD cameras will increase over time and the increased camera speed will translate into higher performance of the MA SS a/LCI system.
In addition to the SS a/LCI and MA SS a/LCI implementations described herein, a time-domain a/LCI implementation is also possible. An example of this a/LCI system 130 implementation is shown by example in
The system 130 uses photodiode arrays #1 and #2 132, 134 to collect angular scattered light from the sample (not shown). The system 130 provides a swept-source light source 136 in the form of a Ti:Sapphire laser operating in a pulsed mode in this embodiment. The swept-source light source 136 directs light 138 to a beam splitter (BS 1) 140, which splits the light 138 into a reference signal 141 and sample signal 142. The reference signal 141 goes through acousto optic modulator (AOM) 144 with w+10 MHz, and then through retroreflector (RR) 154 mounted on a reference arm 153, wherein the retroreflector (RR) 154 is moved by a distance, δz to change the depth in the sample to perform depth scans. The sample signal 142 goes through AOM 146 with frequency ‘ω’ and then through imaging optics 148. Imaging optics 148 shine collimated light onto the sample and then collect the angular scattered light from the sample. The reference signal 141 and the angular scattered light are combined at beamsplitter (BS2) 152 and then imaged onto the photodiode arrays #1 and #2 132, 134. Signals 135, 137 from each photodiode 132 or 134 are subtracted from the photodiode in the other array 132 or 134 which corresponds to the same angular location. A multi-channel demodulator 160 is used on the subtracted signal 139. All signals then go to a computer 162 for processing. Processing of the time-domain depth information from the subtracted signal 139 and received by the multi-channel demodulator 160 can be performed just as previously described in above in paragraphs 0055 through 0058 for this embodiment, as possible examples or methods.
For the embodiments illustrated in
Note that this system uses some means of subtracting the signals 135, 137 on the photodiodes 132, 134 by photodiode basis and then demodulating each channel. This may be accomplished in a serial or parallel fashion. One implementation would be to digitally acquire data from the photodiode arrays (as in the case of a line scan camera) and then use a digital signal processor (DSP) chip or similar to subtract and demodulate the data. This may require that the offset frequency between the two AOMs be less than the line rate of the line scan arrays. Since line scan arrays exist that receive signal data up to 100,000 lines/second, an offset of <50 KHz may be acceptable.
A second implementation would be to use the photodiode arrays 132, 134 and perform the subtraction in an analog basis. It may be the case that the two photodiode arrays are actually two sections of the same two-dimensional array. There also may then be a dedicated demodulator for each photodiode pair or, again, a digitizer and appropriate digital signal processor (DSP) chips.
In another embodiment and approach to collecting information about a sample of interest, a step forward from time domain a/LCI systems is taken to still collect the angular information in a serial fashion. However, depth information is collected from a sample of interest using a Fourier domain approach. The light source that may be used can include a broadband light source in combination with a spectrometer to process spectrally-resolved information about the sample. Alternatively, a swept-source light source with a photodiode or another implementation may be used.
Since this system 170 does not use a time domain data acquisition approach, the AOMs 144, 146 and the moving retroreflector (RR) 154 in the reference arm 153, as provided in the systems 130 in
As illustrated in
Another implementation of a/LCI is a multi-spectral a/LCI system. Embodiments of multi-spectral a/LCI systems 210, 210′ are illustrated in
The system 210 of
The super-continuum light source 213 directs light 212 to a beam splitter (BS1) 215, which splits the light 216 into a reference signal 217 and sample signal 218. The reference signal 217 goes through AOM 221, and then through retroreflector (RR) 219 mounted on a reference arm 220, wherein the retroreflector (RR) 219 is moved by the reference arm 220 to change the depth in the sample to perform depth scans. The sample signal 218 goes through AOM 222 with frequency ‘co’ and then through imaging optics 223. Imaging optics 223 shine light from the super-continuum light source 213 onto a sample and then collects the angular scattered light from the sample. The reference signal 217 and the angular scattered light are combined at beamsplitter (BS2) 224 and then imaged onto the photodiode arrays #1 and #2 211, 212. Signals 225, 226 from each photodiode 211 or 212 are subtracted from the photodiode in the other array 211 or 212 which corresponds to the same angular location. A multi-channel demodulator 228 is used on the resulting subtracted signal 227. The subtracted signal 227 travels to a computer 230 for processing.
Another approach to the multi-spectral a/LCI system 210 in
As illustrated in
It is possible to provide this system 210′ with one spectrometer, although the combination of multiple spectrometers allows for high spectral resolution for the Fourier domain depth detection and the broad range of wavelengths needed to acquire the multi-spectral information. The system 210′ can be expanded to as many sections of the optical spectrum as needed. Fiber implementations based on fiber couplers and fiber filters are also possible.
The system 210′ may also be provided with a broadband swept-source light source for the acquisition of depth information and the acquisition of multi-spectral information. Another approach is to multiplex together multiple sources at different wavelengths to obtain the multi-spectral information. For example, an 830 nm center wavelength, 20 nm 3 dB width SLD could be multiplexed together with a 650 nm center wavelength, 15 nm 3 dB width SLD to obtain a/LCI information at two wavelengths. Further, as the various wavelengths become farther apart, it may be necessary to put in compensation components to account for the variation in index of refraction at the different wavelengths. For example, if one is using a 400 nm and an 800 nm wavelength, it may be the case that when the interferometer arms are path length matching for the 400 nm wavelength, they are mismatched for the 800 nm wavelength by more than the imaging depth available with the spectrometer (typically 1 to 2 mm).
The a/LCI systems and methods described herein can be clinically viable methods for assessing tissue health without the need for tissue extraction via biopsy or subsequent histopathological evaluation. The a/LCI systems and methods described herein can be applied for a number of purposes: for example, early detection and screening for dysplastic tissues, disease staging, monitoring of therapeutic action, and guiding the clinician to biopsy sites. The non-invasive, non-ionizing nature of the optical a/LCI probe means that it can be applied frequently without adverse affect. The potential of a/LCI to provide rapid results will greatly enhance its widespread applicability for disease screening.
Nuclear morphology measurement is also possible using the a/LCI systems and methods described herein. Nuclear morphology is a necessary junction between a cell's topographical environment and its gene expression. One application of the a/LCI systems and methods is to connect topographical cues to stem cell function by investigating nuclear morphology. There are several steps to achieve this. The first is improvement of the a/LCI systems and methods can be to use the swept-source light source approach described herein and create and implement light scattering models. The second is to provide nuclear morphology as a function of nanotopography. Finally, by connecting nuclear morphology with gene expression, the structure-function relationship of stem cells, e.g., human mesenchymal stem cells (hMSC), under the influence of nanotopographic cues can be established.
The a/LCI methods and systems described herein can also be used for cell biology applications. Accurate measurements of nuclear deformation, i.e., structural changes of the nucleus in response to environmental stimuli, are important for signal transduction studies. Traditionally, these measurements require labeling and imaging, and then nuclear measurement using image analysis. This approach is time-consuming, invasive, and unavoidably perturbs cellular systems. The a/LCI techniques described herein offer an alternative for probing physical characteristics of living systems. The a/LCI techniques disclosed herein can be used to quantify nuclear morphology for early cancer detection, as well as for noninvasively measuring small changes in nuclear morphology in response to environmental stimuli. With the a/LCI methods and systems provided herein, high-throughput measurements and probing aspherical nuclei can be accomplished. This is demonstrated for both cell and tissue engineering research. Structural changes in cell nuclei or mitochondria due to subtle environmental stimuli, including substrate topography and osmotic pressure, are profiled rapidly without disrupting the cells or introducing artifacts associated with traditional measurements. Accuracy of better than 3% can be obtained over a range of nuclear geometries, with the greatest deviations occurring for the more complex geometries.
In one embodiment disclosed herein, the a/LCI systems and methods described herein are used to assess nuclear deformation due to osmotic pressure. Cells are seeded at high density in chambered coverglasses and equilibrated with 500, 400 and 330 mOsm saline solution, in that order. Nuclear diameters are measured in micrometers to obtain the mean value+/−the standard error within a 95% confidence interval. Changes in nuclear size are detected as a function of osmotic pressure, indicating that the a/LCI systems and methods disclosed herein can be used to detect cellular changes in response to factors which affect cell environment. One skilled in the art would recognize that many biochemical and physiological factors can affect cell environment, including disease, exposure to therapeutic agents, and environmental stresses.
To assess nuclear changes in response to nanotopography, cells are grown on nanopatterned substrates which create an elongation of the cells along the axis of the finely ruled pattern. The a/LCI systems and processes disclosed herein are applied to measure the major and minor axes of the oriented spheroidal scatterers in micrometers through repeated measurements with varying orientation and polarization. A full characterization of the cell nuclei is achieved, and both the major axis and minor axis of the nuclei is determined, yielding an aspect ratio (ratio of minor to major axes).
The a/LCI systems and methods disclosed herein can also be used for monitoring therapy. In this regard, the a/LCI systems and methods are used to assess nuclear morphology and subcellular structure within cells (e.g., mitochondria) at several time points following treatment with chemotherapeutic agents. The light scattering signal reveals a change in the organization of subcellular structures that is interpreted using a fractal dimension formalism. The fractal dimension of sub-cellular structures in cells treated with paclitaxel and doxorubicin is observed to increase significantly compared to that of control cells. The fractal dimension will vary with time upon exposure to therapeutic agents, e.g. paclitaxel, doxorubicin and the like, demonstrating that structural changes associated with apoptosis are occurring. Using T-matrix theory-based light scattering analysis and an inverse light scattering algorithm, the size and shape of cell nuclei and mitochondria are determined. Using the a/LCI systems and methods disclosed herein, changes in sub-cellular structure (e.g., mitochondria) and nuclear substructure, including changes caused by apoptosis, can be detected. Accordingly, the a/LCI systems and processes described herein have utility in detecting early apoptotic events for both clinical and basic science applications.
Although embodiments disclosed herein have been illustrated and described herein with reference to preferred embodiments and specific examples thereof, it will be readily apparent to those of ordinary skill in the art that other embodiments and examples can perform similar functions and/or achieve like results. The previous description of the disclosure is provided to enable any person skilled in the art to make or use the disclosure. Various modifications to the disclosure will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other variations without departing from the spirit or scope of the disclosure. All such equivalent embodiments and examples are within the spirit and scope of the present invention and are intended to be covered by the appended claims. It will also be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit and scope of the invention. Thus, the disclosure is not intended to be limited to the examples and designs described herein, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.
This patent application is a continuation of and claims priority to U.S. patent application Ser. No. 13/305,095, filed on Nov. 28, 2011, and entitled “Apparatuses, Systems, and Methods for Low-Coherence Interferometry (LCI), which is incorporated herein by reference in its entirety, and which is a continuation of and claims priority to U.S. patent application Ser. No. 12/210,620, filed on Sep. 15, 2008, and entitled “Apparatuses, Systems, and Methods for Low-Coherence Interferometry (LCI),” which is incorporated herein by reference in its entirety and which further claims priority to U.S. Provisional Patent Application Ser. No. 60/971,980, filed on Sep. 13, 2007 and entitled “Systems and Methods for Angle-Resolved Low Coherence Interferometry,” which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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60971980 | Sep 2007 | US |
Number | Date | Country | |
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Parent | 13305095 | Nov 2011 | US |
Child | 14523174 | US | |
Parent | 12210620 | Sep 2008 | US |
Child | 13305095 | US |