A well-characterized broadband (600-1100 nm) phantom recipe was presented to manufacture tissue-mimicking optical phantoms over a wider range of optical properties (absorption 0.1-1 cm-1, reduced scattering 5-25 cm-1) relevant to human organs. The recipe was well tested over broadband (600-1100 nm) range for linearity, reproducibility, homogeneity yielding a robust 4 % coefficient of variation (CV). Finally, we show various applications of the recipe to create standardized matrix phantoms and simply heterogeneous phantoms and anthropomorphic phantoms. The recipe could be exploited to characterize and calibrate the diffuse optical systems and explored for standardization and validation of technologies in Biophotonics
Optical tissue phantoms (OTPs) have been extensively applied to the evaluation of imaging systems an...
Because of their compatibility and precise results bio-optical methods based on measurements of the ...
Tissue-equivalent phantoms that mimic the optical properties of human and animal tissues are commonl...
A well-characterized broadband (600-1100 nm) phantom recipe was presented to manufacture tissue-mimi...
We present a tissue mimicking optical phantom recipe to create robust well tested solid phantoms. Th...
We present a tissue mimicking optical phantom recipe to create robust well tested solid phantoms. Th...
Tissue simulating phantoms can provide a valuable platform for quantitative evaluation of the perfor...
The design and characterization of optical phantoms which have the same absorption and scattering ch...
In diagnostic and therapeutic applications of light in medicine, it is vital to evaluate the optical...
Emerging biomedical instrumentation for imaging and diagnostics requires tissue-mimicking phantoms w...
A lack of accepted standards and standardized phantoms suitable for the technical validation of biop...
A novel methodology is presented to mimic diffuse reflectance spectra of arbitrary biological tissue...
Optical tissue phantoms (OTPs) have been extensively applied to the evaluation of imaging systems an...
Because of their compatibility and precise results bio-optical methods based on measurements of the ...
Tissue-equivalent phantoms that mimic the optical properties of human and animal tissues are commonl...
A well-characterized broadband (600-1100 nm) phantom recipe was presented to manufacture tissue-mimi...
We present a tissue mimicking optical phantom recipe to create robust well tested solid phantoms. Th...
We present a tissue mimicking optical phantom recipe to create robust well tested solid phantoms. Th...
Tissue simulating phantoms can provide a valuable platform for quantitative evaluation of the perfor...
The design and characterization of optical phantoms which have the same absorption and scattering ch...
In diagnostic and therapeutic applications of light in medicine, it is vital to evaluate the optical...
Emerging biomedical instrumentation for imaging and diagnostics requires tissue-mimicking phantoms w...
A lack of accepted standards and standardized phantoms suitable for the technical validation of biop...
A novel methodology is presented to mimic diffuse reflectance spectra of arbitrary biological tissue...
Optical tissue phantoms (OTPs) have been extensively applied to the evaluation of imaging systems an...
Because of their compatibility and precise results bio-optical methods based on measurements of the ...
Tissue-equivalent phantoms that mimic the optical properties of human and animal tissues are commonl...
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