The present application is a National Phase entry of PCT Application No. PCT/CN2017/113691, filed Nov. 30, 2017, which claims priority to Chinese Patent Application No. 201711038893.9, filed Oct. 30, 2017, the disclosures of which are hereby incorporated by reference herein in their entirety.
The invention particularly relates to an optical imaging method based on a mapping of layered structure.
In the field of optical imaging, the composition of biological tissues is complex and diverse, while all the detected substances are not isotropic substances. In fact, the biological tissues are anisotropic substances, and the detected regional substances are spatially and unevenly distributed (such as melanin of skin exists only in the epidermis, and oxyhemoglobin and deoxyhemoglobin exist in the dermis), but in actual treatment, in order to simplify the actual path of the light entering the biological tissue, the detected substance is considered to be an isotropic substance, so that the substance content of each layer can be misestimated, and the spatial distribution, optical and physiological information of the detected substance cannot be accurately reduced. The large-area skin imaging method based on a mapping of layered structure fully considers the actual path of light entering biological tissues and the spatial distribution mode of measured substances. The spatial distribution, optical information and physiological information of the detected substance can be accurately obtained.
In order to solve the technical problem, the invention provides an optical imaging method based on a mapping of layered structure.
The invention provides an optical imaging method based on a mapping of layered structure,
mapping a layered structure to an equivalent uniform medium, wherein each layer of the layered structure has a respective absorption coefficient, the equivalent uniform medium having the same scattering characteristic as the layer, and the absorption coefficient being determined by a spatial modulation frequency of incident light and the absorption coefficient and thickness of each layer;
after obtaining optical parameters of the equivalent uniform medium in different incident light spatial modulation states by using transmission model of light in uniform medium, the scattering characteristic of medium and the absorption coefficient and thickness of each layer being inversely solved.
The layered structure is a bilayer layered structure or a multilayer layered structure.
Use of the optical imaging method based on a mapping of layered structure as described in skin parameter detection.
The use comprising the steps of:
I. acquiring optical parameters of corresponding layers through a large-area optical imaging method of a layered model, wherein the mapping of layered structure comprises the following steps of
(1) the absorption coefficients of epidermis and dermis being established
μa,epidermis(λ)=εmelanin(λ)cmelanin
μa,dermis(λ)=εHb(λ)cHb+εHbO
wherein cHbO
(2) establishing the following relationship
μa(q,λ)L(q,λ)=μa,epidermis(λ)h+μa,dermis(λ)(L−h),
wherein q is incident light spatial modulation angular frequency, μa(q,λ) is the absorption coefficient of the equivalent uniform medium, h is epidermal thickness, and an average depth of detection
wherein μt+≡μa+μs′, Q≡√{square root over (q3+3μa(μa+μs′))}, D0=⅓μs′, l is extrapolated length, and μs′ is reduced scattering coefficient;
(3) the absorption coefficient μa of the equivalent uniform medium being determined by step (2);
II. obtaining a content of each substance by Beer-Lambert law according to obtained optical parameters.
Use of an optical imaging method based on a mapping of layered structure as described in endoscopic tissue mucosal layer detection imaging.
An optical spectroscopic method based on a mapping of layered structure as described, mapping a layered structure to an equivalent uniform medium, wherein each layer of the layered structure has a respective absorption coefficient, the equivalent uniform medium having the same scattering characteristic as the layer, and the absorption coefficient being determined by a spatial modulation frequency of incident light and the absorption coefficient and thickness of each layer;
after obtaining optical parameters of the equivalent uniform medium in different incident light spatial modulation states by using transmission model of light in uniform medium, the scattering characteristic of medium and the absorption coefficient and thickness of each layer being inversely solved.
The invention has the beneficial effects that: the spatial distribution of biological tissues and the optical properties of each layer are fully considered, and the detection depth under the spatial modulation frequency of each wavelength is accurately evaluated, so that the spatial distribution of layered tissues and the material content of each layer can be accurately obtained, and the model is combined with the SFDI technology, and good results are obtained when the model is applied to forearm reactive hyperemia experiments and skin pigmented nevus detection.
The patent application contains at least one drawing executed in color. Copies of this patent with color drawings will be provided by the Patent and Trademark Office upon request and payment of the necessary fee.
In
Embodiments of the present invention are further described below with reference to the accompanying drawings:
The invention provides an optical imaging method based on a mapping of layered structure,
mapping a layered structure to an equivalent uniform medium, wherein each layer of the layered structure has a respective absorption coefficient, the equivalent uniform medium having the same scattering characteristic as the layer, and the absorption coefficient being determined by a spatial modulation frequency of incident light and the absorption coefficient and thickness of each layer;
after obtaining optical parameters of the equivalent uniform medium in different incident light spatial modulation states by using transmission model of light in uniform medium, the scattering characteristic of medium and the absorption coefficient and thickness of each layer being inversely solved.
The layered structure is a bilayer layered structure or a multilayer layered structure.
The deduction of the optical imaging method based on a mapping of layered structure is explained by taking the skin as an example, and the structural characteristics of the skin are as follows: in a multilayer structure (
The epidermis of the skin is extremely thin, and it can be assumed that the epidermis and the dermis have the same scattering coefficient μs′, and the absorption of light is different in different layers. The dominant one is the melanin of the epidermis, and the second dominant one is the oxyhemoglobin (HbO) and the deoxyhemoglobin (Hb) in the dermis. Assuming that the epidermal thickness is h, considering the detection depth of the spatial modulation frequency L=L(q), the frequency of the spatially modulated light q=2πf (
The invention provides an optical imaging method based on a mapping of layered structure, which comprises the following steps:
I. acquiring optical parameters of corresponding layers through a large-area optical imaging method of a layered model, wherein the mapping of layered structure comprises the following steps of
(1) the absorption coefficients of epidermis and dermis being established
μa,epidermis(λ)=εmelanin(λ)cmelanin
μa,dermis(λ)=εHb(λ)cHb+εHbO
wherein cHbO
(2) establishing the following relationship
μa(q,λ)L(q,λ)=μa,epidermis(λ)h+μa,dermis(λ)(L−h),
wherein q is incident light spatial modulation angular frequency, μa(q,λ) is the absorption coefficient of the equivalent uniform medium, h is epidermal thickness, and an average depth of detection
wherein μt′≡μa+μs′, Q≡√{square root over (q3+3μa(μa+μs′))}, D0=⅓μs′, l is extrapolated length, and μs′ is reduced scattering coefficient;
(3) the absorption coefficient μa of the equivalent uniform medium being determined by step (2);
II. obtaining a content of each substance by Beer-Lambert law according to obtained optical parameters.
Λ is 623 nm, 540 nm, 460 nm.
The image acquisition device is one or other of a CCD, a spectrometer or an optical fiber probe.
The mapping model of layered structure and Monte Carlo simulation of equivalent uniform medium are carried out. In the mapping model of layered structure, in 0.1 mm of epidermis, melanin content is 3.485 mM, while oxyhemoglobin and deoxyhemoglobin in dermis are 0.0077 mM 0.0027 mM respectively. The scattering coefficient at 540 nm is 1.7 mm−1, the scattering capability is 0.76, the reflectivity is 1.4, and the anisotropy factor is 0.7.
The optical imaging method based on a mapping of layered structure can also be applied to endoscopic tissue mucosal layer detection imaging.
The mapping of layered structure can also be applied in optical spectroscopy methods.
Experimental Protocol:
Real-time detection of the dorsal surface of an arm of a volunteer (n=6) is performed using a real-time single snapshot multiple frequency demodulation—spatial frequency domain imaging (SSMD-SFDI) device. A digital micromirror device (DMD) projects a modulation pattern at wavelengths of 623 nm, 540 nm and 460 nm with a spatial frequency f=0.2. A detector (Point Grey Grasshop3 GS3-U3-51S5C) performs collection at a rate of 3 frames per second. Volunteers follow the following experimental protocol: 3 minutes of normal state, the pulse band generating pressure (200 mmg) for maintaining the arm for 4 minutes, the pulse band being released for resting for 3 minutes, performing collection for a total of 10 minutes, and direct-current and alternating-current information of the reflection pattern being rapidly demodulated by using an SSMD technology.
The phenomenon of the whole experiment is analyzed:
The pigmented nevus on the skin is detected using the SSMD-SFDI system in combination with a mapping model of layered structure.
With the SSMD-SFDI system, rich optical and physiological information can be used to distinguish the pigmented nevus area with the adjacent normal area, as shown in
Through the application of two experiments, the feasibility of SSMD-SFDI system and mapping model of layered structure is fully proved, by which we can obtain real-time, continuous and 2-dimensional time variation maps of multiple physiological parameters of a regional tissue.
The examples are not to be construed as limiting the invention, and any modifications based on the spirit of the invention are intended to be within the protection scope of the invention.
Number | Date | Country | Kind |
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201711038893.9 | Oct 2017 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2017/113691 | 11/30/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/085113 | 5/9/2019 | WO | A |
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