METHOD AND APPARATUS FOR PERFORMING QUALITATIVE AND QUANTITATIVE ANALYSIS OF BURN EXTENT AND SEVERITY USING SPATIALLY STRUCTURED ILLUMINATION

US 20140213910A1
Filed: 01/24/2014
Published: 07/31/2014
Est. Priority Date: 01/25/2013
Status: Abandoned Application

First Claim

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1. A method using spatial frequency domain imaging (SFDI) for quantitative noninvasive, noncontact assessment of severity of burn injury to tissue in vivo comprising:

performing wide-field quantitative mapping of tissue optical properties including pixel-by-pixel demodulation and fitting of spatial frequency data performed with multispectral imaging to extract the local absorption and reduced scattering optical coefficients;

performing quantitative analysis of burn injury of tissue by separately analyzing absorption spectra at each pixel to yield a spatial map of blood oxygenation, water concentration, optical scattering changes or a combination thereof; and

classifying the severity of the burn injury to tissue according to the depth of the injury.

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Abstract

Frequent monitoring of early-stage burns is necessary for deciding optimal treatment and management. Superficial-partial thickness and deep-partial thickness burns, while visually similar, differ dramatically in terms of clinical treatment and are known to progress in severity over time. The disclosed method uses spatial frequency domain imaging (SFDI) far noninvasively mapping quantitative changes in chromophore and optical properties that may be an indicative of burn wound severity. A controlled protocol of graded burn severity is developed and applied to 17 rats. SFDI data is acquired at multiple near-infrared wavelengths over a course of 3 h. Burn severity is verified using hematoxylin and eosin histology. Changes in water concentration (edema), deoxygenated hemoglobin concentration, and optical scattering (tissue denaturation) are statistically significant measures, which are used to differentiate superficial partial-thickness burns from deep-partial thickness burns.

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20 Claims

1. A method using spatial frequency domain imaging (SFDI) for quantitative noninvasive, noncontact assessment of severity of burn injury to tissue in vivo comprising:
- performing wide-field quantitative mapping of tissue optical properties including pixel-by-pixel demodulation and fitting of spatial frequency data performed with multispectral imaging to extract the local absorption and reduced scattering optical coefficients;
  
  performing quantitative analysis of burn injury of tissue by separately analyzing absorption spectra at each pixel to yield a spatial map of blood oxygenation, water concentration, optical scattering changes or a combination thereof; and
  
  classifying the severity of the burn injury to tissue according to the depth of the injury.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15)
- - 2. The method of claim 1 further comprising tracking wound progression of burn injury in tissue in vivo over time.
  - 3. The method of claim 1 where performing quantitative analysis of burn injury of tissue by separately analyzing absorption spectra at each pixel to yield the spatial map of blood oxygenation comprises performing quantitative analysis of burn injury of tissue by separately analyzing absorption spectra at each pixel to the yield spatial map of local oxy-hemoglobin (ct0₂Hb), deoxy hemoglobin concentration (ctHHb), and water concentration (ctH₂0).
  - 4. The method of claim 3 where performing quantitative analysis of burn injury of tissue by separately analyzing absorption spectra at each pixel to the yield spatial map of local oxy-hemoglobin (ct0₂Hb), deoxy hemoglobin concentration (ctHHb), and water concentration (ctH₂0) further comprises performing quantitative analysis of burn injury of tissue by separately analyzing absorption spectra at each pixel to yield the spatial map of total hemoglobin (ctHbT) and oxygen saturation (St0₂) calculated as ctHbT=ctHHb+ctHHb+ct0₂Hb and St0₂=100*ct0₂Hb/ctHbT, respectively.
  - 5. The method of claim 4 further comprising tracking wound progression in burns using total hemoglobin (ctHbT) and oxygen saturation (St0₂).
  - 6. The method of claim 1 where performing quantitative analysis of burn injury of tissue by separately analyzing absorption spectra at each pixel to the yield spatial map of optical scattering changes comprises recovering the reduced scattering parameters at discrete wavelengths on a pixel by pixel basis using SFDI and fitting the reduced scattering parameters to a power law (μ
    - _s′
      
      =A*λ
      
      ^−
      
      b) at each pixel, where A is a parameter proportional to the number of scattering particles in the turbid medium and b is a parameter proportional the average size of the scattering particles in the tissue.
  - 7. The method of claim 6 further comprising measuring the wavelength dependent A and b parameters in a two dimensional spatial map to provide an indication of the thermal damage to the collagen fibril network, where the changes in A and b are caused by denaturation of collagen fibrils and can then be correlated to burn severity and extent.
  - 8. The method of claim 1 further comprising assessing wound healing as characterized by changes in scattering that reflect the different phases of a healing process.
  - 9. The method of claim 6 further comprising selecting regions of the spatial map to compare the A and b parameters for all selected regions where the A value and bare larger for selected regions with a more severe burn.
  - 10. The method of claim 9 where the severity of the burn is assessed to be related to the amount of change in the A and b parameters.
  - 11. The method of claim 6 where a change in A and b is due to a change in collagen fibril structures, where A is proportional to the number of scattering particles in the tissue and b is proportional the average size of the scattering particles in the tissue, when the tissue is burned, the collagen fibrils are denatured due to thermal interactions and the average scattering size gets smaller so that b increases, and the number of scattering particles will increase so that A increases, such that use of SFDI measures of the A and b parameters when displayed in a two dimensional map provide an indication of the thermal damage to the collagen fibril network with the changes in A and b being caused by denaturation of collagen fibrils correlated to burn severity and extent.
  - 12. The method of claim 1 where performing quantitative analysis of burn injury of tissue by separately analyzing absorption spectra at each pixel to yield a spatial map of optical scattering changes further comprises using optical absorption data to map tissue chromophores for determining burn treatment.
  - 13. The method of claim 1 performing quantitative analysis of burn injury of tissue by separately analyzing absorption spectra at each pixel to yield a spatial map of water concentration to predict buildup of edema and ischemia progression.
  - 14. The method of claim 1 further comprising predicting burn injury healing progression based on SFDI-related parameters.
  - 15. The method of claim 1 further comprising using multimodal imaging using SFDI and perfusion-based imaging to characterize and analyze vascular changes occurring within a burn wound.

16. A method using spatial frequency domain imaging (SFDI) for quantitative noninvasive, noncontact assessment of severity of burn injury to tissue in vivo comprising:
- performing wide-field quantitative mapping of tissue optical properties;
  
  separately analyzing optical properties to generate a spatial map of blood oxygenation, water concentration, optical scattering changes or a combination thereof; and
  
  determining the severity of the burn injury to tissue according to the spatial map of blood oxygenation water concentration, optical scattering changes or a combination thereof.
- View Dependent Claims (17, 18, 19, 20)
- - 17. The method of claim 16 further comprising tracking progression of burn injury in tissue in vivo over time to determine treatment of the burn injury.
  - 18. The method of claim 16 further comprising treating the burn injury according to the spatial map of burn injury in terms of blood oxygenation, water concentration, optical scattering changes or a combination thereof.
  - 19. The method of claim 16 where separately analyzing optical properties to generate a spatial map of blood oxygenation, water concentration, optical scattering changes or a combination thereof comprises separately analyzing absorption spectra at each pixel to generate the spatial map of local oxy-hemoglobin (ct0₂Hb), deoxy hemoglobin concentration (ctHHb), and water concentration (ctH₂0).
  - 20. The method of claim 16 where separately analyzing optical properties to generate a spatial map of blood oxygenation, water concentration, optical scattering changes or a combination thereof comprises recovering the reduced scattering parameters at discrete wavelengths on a pixel by pixel basis using SFDI and fitting the reduced scattering parameters to a power law μ
    - _s=A*λ
      
      ^−
      
      b) at each pixel, where A is a parameter proportional to the number of scattering particles in the turbid medium and b is a parameter proportional the average size of the scattering particles in the tissue.

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Current Assignee
Regents of the University of California (University of California)
Original Assignee
Regents of the University of California (University of California)
Inventors
Durkin, Anthony J., Mazhar, Amaan, Nguyen, John Quan Minh

Application Number

US14/163,568
Publication Number

US 20140213910A1
Time in Patent Office

Days
Field of Search
US Class Current

600/477
CPC Class Codes

A61B 5/0075   by spectroscopy, i.e. measu...

A61B 5/445   Evaluating skin irritation ...

G06T 2207/30088   Skin; Dermal

G06T 7/0012   Biomedical image inspection

G06T 7/0016   involving temporal comparison

METHOD AND APPARATUS FOR PERFORMING QUALITATIVE AND QUANTITATIVE ANALYSIS OF BURN EXTENT AND SEVERITY USING SPATIALLY STRUCTURED ILLUMINATION

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METHOD AND APPARATUS FOR PERFORMING QUALITATIVE AND QUANTITATIVE ANALYSIS OF BURN EXTENT AND SEVERITY USING SPATIALLY STRUCTURED ILLUMINATION

First Claim

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Abstract

29 Citations

20 Claims

Specification

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