RU2615035C1 - Device for recording images of cross-polarization low-coherence optical interferometry - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: device for recording images of the cross-polarization low-coherence optical interferometry, comprises an optical radiation source, a guide element optically coupled to the optical radiation source, a delivery device forming and delivering an optical beam to the test sample containing the input and output (distal) part, the output of which comprises a polarization-independent reference reflector, the delivery device provides the formation of the combined optical radiation, comprises a conversion device backscattered from the test sample and reflected from the polarization-independent reference radiation reflector transforming the device, designed for separating the combined optical radiation, incoming from the delivery device through the guide element, into, at least, two parts and subsequent joining these parts after their obtaining the preset optical delays. Herewith, at least, one of the optical paths comprises a polarization ruler intended for generating the polarization state of the first optical radiation part orthogonal against the polarization state of the second optical radiation part, an optoelectronic recording device optically coupled to the converting device designed for the spectral registration of, at least, one of: the cross-polarized component of the combined optical radiation returned from the test object, and the component of the combined optical radiation returned from the test object that preserved the original state of the radiation polarization . In addition, the polarization ruler is made electronically controlled to provide, in the consistent registration process, images of the polarization state consistent change of the first optical radiation part from the orthogonal to the parallel against the polarization state of the second optical radiation part and vice versa.

EFFECT: implementing the visualization of the depolarizing properties of the biological tissue surface layers and evaluating the presence of the organized depolarizing structures such as collagen fibers.

8 cl, 5 dwg

Description

The invention relates to devices for obtaining and processing images of optical interferometry (optical coherence tomography). The invention can be used for intravital imaging and quantification of depolarizing properties of individual sections of biological tissues, including human.

For the purposes of diagnosing a number of diseases, including oncological and inflammatory ones, as well as evaluating, including early, the effectiveness of certain types of therapy, information on the depolarizing properties of biological tissue, which is determined, in particular, by the presence of collagen fibers in the biological tissue, as well as the nature of the distribution of collagen fibers in biological tissue. Data on the nature and degree of damage to the collagen network can be used in the clinic for differential diagnosis of diseases, detection of early neoplastic processes, determining the response of connective tissue stroma to treatment, and determining the quality of collagen-based transplants.

It is known that pathological conditions, changing the properties and integrity of healthy tissues, change their polarization properties (birefringence, depolarization). For this reason, a promising method is the use of polarized optical interferometry to detect tissue pathology, in particular polarization-sensitive optical interferometry, which studies birefringence of the tissue, and cross-polarized optical interferometry, which detects random radiation depolarization.

A device is known for isolating and visualizing information about the polarization properties of areas of biological tissue. In particular, a method is known, described in Johannes F. de Boer and Thomas E. Milner, "Review of polarization sensitive optical coherence tomography and Stokes vector determination", J. Biomed. Opt. 7 (3), 359-371 (Jul 01, 2002) .; http://dx.doi.org/10.1117/1.1483879 by Johannes F. de Boer and Thomas E. Milner, in which a specially prepared reference wave and independent registration of image components by independent recording devices are used to form the image. The disadvantage of the described approach is the use of elements of free space optics and the unrealizability of the device in the fiber version, which allows the use of flexible probes, which make it possible to observe and analyze the internal structure of a number of internal organs.

For the prototype of the present invention, a device for recording images of cross-polarized low-coherent optical interferometry is selected, containing an optical radiation source, a directing element optically coupled to an optical radiation source, a delivery device forming and delivering an optical beam to the sample to be studied, containing input and output (distal) parts , the output part of which contains a polarization-independent reference reflector, a delivery device providing combined optical radiation, contains a conversion device designed to separate the combined optical radiation coming from the delivery device through the guide element into at least two parts and then combining these parts after acquisition, backscattered from the test sample and reflected from the polarization-independent reference radiation reflector. predefined optical delays, where at least one of the optical paths contains a polarizer a device intended to form a polarization state of the first part of the optical radiation orthogonal with respect to the polarization state of the second part of the optical radiation, an optoelectronic recording device optically coupled to a conversion device intended for spectral recording of at least one of the cross-polarized components of the combined optical radiation returned from the object under study, and the components of the combined optical radiation returned and h of the studied object, which retained the initial state of radiation polarization (patent US 7728985 B2 "Polarization-sensitive common path optical coherence reflectometry / tomography device", authors Feldchtein, Felix I., Gelikonov, Valentin M., Gelikonov, Grigory V. 1.)

However, when implementing the known device in the case of spectral registration of optical radiation using one optoelectronic recording device, it is possible to register only one of the cross-polarized components of the combined optical radiation returned from the object under study, and the components of the combined optical radiation returned from the object under study, which retained the initial state of polarization radiation. For spectral recording of the second component, a second converting device and a second optoelectronic recording device are introduced in the closest analogue, which significantly complicates and increases the cost of the final product.

The technical effect to which this invention is directed is the development of a device for recording images of cross-polarized low coherent optical interferometry, which allows to expand its functionality, namely, to ensure the registration of cross-polarized components of the combined optical radiation returned from the object under study, and the components of the combined optical radiation returned from the investigated object, which retained the initial state of polarization radiation using one optoelectronic recording device.

The indicated technical effect is achieved by the fact that in the device for recording images of cross-polarized low-coherent optical interferometry containing an optical radiation source, a directing element optically coupled to an optical radiation source, a delivery device that generates and delivers an optical beam to the test sample containing input and output ( distal) parts, the output part of which contains a polarization independent reference reflector, the delivery device provides combined optical radiation contains a conversion device, which is backscattered from the test sample and reflected from the polarization-independent reference radiation reflector, for separating the combined optical radiation from the delivery device through the guide element into at least two parts and the subsequent combination of these parts after acquisition predefined optical delays, where at least one of the optical paths contains a field manager of polarization, designed to form the polarization state of the first part of the optical radiation, orthogonal with respect to the polarization state of the second part of the optical radiation, an optoelectronic recording device optically coupled to the conversion device, intended for spectral recording of at least one of the cross-polarized components of the combined optical radiation returned from the object under study and the components of the combined optical radiation returned of the examined object, retained the original state of polarization, polarization ruler controlled electronically configured to provide a consistent image registration process consistent state change of the first portion of the optical radiation with the orthogonal polarization in parallel with respect to the state of polarization of optical radiation of the second part and vice versa. The polarization controller is magneto-optical. The conversion device contains at least one polarization-independent element designed to separate and subsequently combine parts of the combined optical radiation after they acquire predefined optical delays; all optical paths end with regular mirrors. The conversion device contains at least the first and second polarization-independent elements, the first intended for separating the combined optical radiation from the delivery device through the guide element into at least two parts and the second for the subsequent combination of these parts after they acquire predefined optical delays.

The technical result is achieved by the fact that in the known device for recording images of cross-polarized low-coherent optical interferometry containing an optical radiation source, a converting device optically coupled to an optical radiation source containing at least two optical paths for separating combined optical radiation from the device delivery through the guide element to at least two parts and the subsequent combination of these parts after the acquisition by them of predefined optical delays, where at least one of the optical paths contains a polarization manager designed to generate a polarization state of the first part of the optical radiation orthogonal to the polarization state of the second part of the optical radiation, a guiding element optically coupled to the conversion device, the delivery device and optoelectronic recording device, a delivery device that forms and delivers an optical beam to the studied For example, the delivery device contains an input and output (distal) parts, the output part contains a polarization-independent reference reflector, the delivery device provides the formation of combined optical radiation containing backscattered from the test sample and reflected from a polarization-independent reference radiation reflector, an optoelectronic recording device, optically connected with a conversion device designed for spectral recording of at least one of: ss-polarized components of the combined optical radiation returned from the object under investigation and components of the combined optical radiation returned from the object under study that retained the initial state of radiation polarization, the polarization manager is electronically controlled to ensure that during the sequential recording of images a sequential change in the polarization state of the first part of the optical radiation from orthogonal to parallel with respect to the state polarization of the second part of the optical radiation and vice versa. The polarization controller is magneto-optical. The conversion device contains at least one polarization-independent element, designed to separate and subsequently combine parts of the radiation coming from the optical radiation source after they acquire predefined optical delays, all optical paths end with regular mirrors. The conversion device contains at least the first and second polarization-independent elements, the first intended to separate the radiation from the optical radiation source entering the delivery device through the guide element into at least two parts, and the second to combine these parts after acquisition predefined optical delays.

The authors see the novelty of the device in that the polarization manager is made in a controlled electronic manner to ensure, during the sequential registration of images, a sequential change in the polarization state of the first part of the optical radiation from orthogonal to parallel with respect to the polarization state of the second part of the optical radiation and vice versa. The polarization controller is magneto-optical. The conversion device contains at least one polarization-independent element designed to separate and subsequently combine parts of the combined optical radiation after they acquire predefined optical delays; all optical paths end with regular mirrors. The conversion device contains at least the first and second polarization-independent elements, the first intended to separate the combined optical radiation coming from the delivery device through the guide element into at least two parts and the second to combine these parts after they acquire predefined optical delays .

The authors see the novelty of the device in that the polarization manager is made in a controlled electronic manner to ensure, during the sequential registration of images, a sequential change in the polarization state of the first part of the optical radiation from orthogonal to parallel with respect to the polarization state of the second part of the optical radiation and vice versa. The polarization controller is magneto-optical. The conversion device contains at least one polarization-independent element, designed to separate and subsequently combine parts of the radiation coming from the optical radiation source after they acquire predefined optical delays, all optical paths end with regular mirrors. The conversion device contains at least the first and second polarization-independent elements, the first intended to separate the radiation coming from the optical radiation source entering the delivery device through the guide element into at least two parts and the second to combine these parts after they are acquired preset optical delays.

The proposed device is illustrated graphic material.

In FIG. 1 is a schematic diagram of a device for recording images of cross-polarized low coherent optical interferometry, consisting of an optical radiation source 1, a guiding element 2, a delivery device 3, a conversion device 5, an optoelectronic recording device 6 and an object of study 4.

In FIG. 2 is a schematic diagram of a conversion device consisting in the first particular case of a polarization manager 7, a non-polarizing optical radiation divider 8, and mirrors 9.

In FIG. 3 is a schematic diagram of a conversion device consisting in the second particular case of a polarization manager 7, two non-polarizing optical radiation dividers 8.

In FIG. 4 is a schematic diagram of a device for recording images of cross-polarization low-coherent optical interferometry in the second particular implementation, consisting of an optical radiation source 1, a conversion device 5, a guiding element 2, a delivery device 3, an optoelectronic recording device 6 and an object of study 4.

In FIG. Figure 5 shows characteristic images of cross-polarized low-coherent optical interferometry (upper row) and histological images in polarized light, picrosirius red (lower row) staining of the cheek mucosa for conditions: a, d - KB degradation (acute inflammation), b, e - excessive accumulation of CV (weak fibrosis), c, e - excessive accumulation of collagen fibers (severe fibrosis).

The proposed device makes it possible to use the following technical effect when using it: register the cross-polarized component of the combined optical radiation returned from the studied object and the components of the combined optical radiation returned from the studied object, which retained the initial state of radiation polarization, using one optoelectronic recording device.

The work of the proposed device is as follows.

The radiation of the optical radiation source 1 (FIG. 1) is directed to the guiding element 2, which redirects the radiation to the delivery device 3. At the distal end of the delivery device 3, a reference reflection of the optical radiation is organized and a probe beam is formed that is directed to the object of study 4. The optical radiation is scattered by optical inhomogeneities the object of study 4 and partially returns to the delivery device 3. The reference and scattered in the object of study 4 optical radiation propagates according to the design delivery device 3 in the direction of the guide element 2, where it is redirected to the conversion device 5. The conversion device 5 contains at least two optical paths and is designed to separate the combined optical radiation coming from the delivery device 3 through the guide element 2 into at least two parts and the subsequent combination of these parts after acquiring predefined optical delays. At least one of the optical paths in the conversion device 5 comprises a polarization manager 7 (FIGS. 2, 3), designed to form a polarization state of the first part of the optical radiation, different from the polarization state of the second part of the optical radiation. The difference in optical delays acquired by the portions of combined optical radiation when passing through the conversion device 5 coincides with the difference in optical delays acquired by the reference and scattered optical radiation in the object of study 4, which makes it possible to spectrally record images of cross-polarized low coherent optical interferometry using an optoelectronic recording device 6. In the process of sequential registration of images cross-polarization In the case of low coherent optical interferometry, the polarization manager 7 sequentially switches between the states providing the output state of the converter 5 of the polarization of the component passed through the polarization manager 7 with the orthogonal and parallel polarization state of the component that passed through the second optical path. Thanks to these switches, the signals corresponding to the cross-polarized images of the components of the combined optical radiation returned from the object under study are sequentially generated at the output of the optoelectronic recording device 6.

In the particular case, the polarization manager can be made on the basis of a magnetically active element (Faraday element) that rotates the plane of polarization of radiation by 90 degrees when a corresponding voltage is applied to it and does not change the state of polarization of radiation in the absence of applied voltage.

In the first particular case of the implementation, the conversion device is made according to the Michelson interferometer scheme and consists of a polarization manager 7, a non-polarizing optical radiation divider 8 and two mirrors 9. The implementation of the conversion device according to the Michelson interferometer scheme allows for a wide range of variation of the difference in optical paths in the arms of the interferometer and optimally to build a conversion device on the elements of volumetric optics.

In the second special case of implementation, the conversion device is made according to the scheme of the Mach-Zander interferometer and consists of a polarization manager 7 and two non-polarizing dividers of optical radiation 8. The implementation of the conversion device according to the scheme of the Mach-Zander interferometer is optimal when the conversion device is implemented on fiber optic elements.

In the first particular case of the implementation of the device for recording images of cross-polarized low-coherent optical interferometry, the converting device 5 can be located in the optical path directly in front of the optoelectronic recording device 6 (Fig. 1), which makes it possible to use a part of the radiation coming from the second output of the non-polarizing optical radiation divider 8 , for operational adjustment of radiation power and its polarization state.

In the second particular case of the implementation of the device for recording images of cross-polarization low-coherent optical interferometry, the converting device 5 can be located in the optical path to the guiding element 2 (Fig 4), which allows to increase the value of the useful signal by reducing the loss of combined optical radiation.

An example of a specific implementation of a device for recording images of cross-polarized low coherent optical interferometry.

For a specific implementation, a device was assembled containing an optical radiation source with a wavelength of 1.3 μm, a conversion device optically coupled to an optical radiation source, implemented according to the Michelson interferometer scheme, containing a polarization controller based on a Faraday element, upon applying a voltage that rotates the incident polarization plane radiation at 45 degrees (with a double pass at 90 degrees), a guiding element implemented on the basis of a three-port optical circulator, devices delivery, consisting of a fiber optic cable with a lens system and electromechanical scanning at the distal end and an optoelectronic recording device, which is a spectrometer based on a diffraction grating and a linear array of photodetector elements. As an object of study, sections of the mucous membrane of the cheek were selected in case of a violation of the normal state of collagen fibers during pathological processes.

On the images of cross-polarization low-coherent optical interferometry, the character of the OCT signal in the orthogonal polarization was evaluated according to visual criteria. Typical images of cross-polarization low-coherent optical interferometry of the studied pathological conditions of the mucous membrane of the cheek are presented in FIG. 5 (a, b, c). On histological sections stained with picrosirius red, the color in which the collagen fibers were stained was visually assessed in polarized light: the predominance of dark areas indicated degradation of collagen fibers (Fig. 5g); zones with thin pale green collagen fibers - on the synthesis of new collagen during repair; the presence of thick red fibers indicated a state of fibrosis, and the density of bright red fibers reflected the degree of fibrosis (Fig. 5e, e).

Parallel histotomographic images revealed a pattern of changes in the OCT signal in orthogonal polarization during pathological benign conditions of the mucous membrane of the cheek: during structural disorganization (degradation) of collagen fibers into fragments during acute inflammation, a signal is relatively low relative to normal; with the structural organization (excessive accumulation) of collagen fibers during chronic inflammation, leading to local or extensive compaction of connective tissue, namely the development of weak or severe fibrosis, an OCT signal increased relative to the norm was observed (depending on the severity of the fibrosis process) (Fig. 5b, c).

Claims (8)

1. A device for recording images of cross-polarized low-coherent optical interferometry, containing an optical radiation source, a guiding element optically coupled to an optical radiation source, a delivery device forming and delivering an optical beam to the sample to be studied, containing an input and output (distal) parts, an output part which contains a polarization-independent reference reflector, the delivery device provides the formation of combined optical radiation, with holds the conversion device, which is scattered from the test sample and reflected from the polarization-independent reference reflector, intended for separating the combined optical radiation coming from the delivery device through the guide element into at least two parts and subsequently combining these parts after they acquire predefined optical delays, where at least one of the optical paths contains a polarization manager designed to form polarization of the first part of the optical radiation orthogonal with respect to the polarization state of the second part of the optical radiation, an optoelectronic recording device optically coupled to a conversion device for spectrally recording at least one of the cross-polarized components of the combined optical radiation returned from the object under study , and the components of the combined optical radiation returned from the object under study, which retained the original -being of polarization, characterized in that the ruler is made of polarization-controlled electronically to provide a process of sequential image registration sequential state changes of the first portion of the optical radiation with the orthogonal polarization in parallel with respect to the state of polarization of optical radiation of the second part and vice versa. 2. The device for recording images of cross-polarized low coherent optical interferometry according to claim 1, characterized in that the polarization manager is made magneto-optical. 3. A device for recording images of cross-polarization low-coherent optical interferometry according to claim 1, characterized in that the converting device contains at least one polarization-independent element for separating and subsequently combining parts of the combined optical radiation after they acquire predefined optical delays, all optical paths end with regular mirrors. 4. The device for recording images of cross-polarization low-coherent optical interferometry according to claim 1, characterized in that the converting device contains at least the first and second polarization-independent elements, the first intended for separating the combined optical radiation from the delivery device through the guide element into at least two parts and a second for the subsequent combination of these parts after acquiring predefined optical delays. 5. A device for recording images of cross-polarized low-coherent optical interferometry, containing an optical radiation source, a conversion device, optically coupled to an optical radiation source, containing at least two optical paths, designed to separate the combined optical radiation from the delivery device through the guide element into at least two parts and the subsequent combination of these parts after they acquire pre-installed optical arrays lance, where at least one of the optical paths contains a polarization manager, designed to generate a polarization state of the first part of the optical radiation orthogonal to the polarization state of the second part of the optical radiation, a guiding element optically coupled to the conversion device, the delivery device and the optoelectronic recording device , a delivery device that generates and delivers an optical beam to the sample under study, the delivery device contains an input and output the distal part, the output part contains a polarization-independent reference reflector, the delivery device provides the formation of combined optical radiation containing backscattered from the test sample and reflected from the polarization-independent reference radiation reflector, an optoelectronic recording device, optically connected to the conversion device, intended for spectral registering at least one of: cross-polarized combined optical components radiation returned from the studied object, and components of the combined optical radiation returned from the studied object, preserving the initial state of radiation polarization, characterized in that the polarization manager is made in a controlled electronic manner to ensure, during the sequential registration of images, a sequential change in the polarization state of the first part of the optical radiation from orthogonal to parallel to the polarization state of the second part of the optical ray radiation and back. 6. The device for recording images of cross-polarized low coherent optical interferometry according to claim 5, characterized in that the polarization manager is magneto-optical. 7. The device for recording images of cross-polarization low-coherent optical interferometry according to claim 1, characterized in that the converting device contains at least one polarization-independent element designed to separate and subsequently combine parts of the radiation coming from the optical radiation source after they acquire predefined optical delays , all optical paths end with regular mirrors. 8. The device for recording images of cross-polarization low-coherent optical interferometry according to claim 1., characterized in that the converting device contains at least the first and second polarization-independent elements, the first intended to separate the radiation coming from the optical radiation source entering the delivery device through a guiding element, in at least two parts and a second for the subsequent combination of these parts after acquiring predefined optical delays .

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