Abstract: The present invention relates to methods and devices that may be used to extract spatial frequency information. In one embodiment, the invention provides an instrument configured to extract data using a two-dimensional (2D) Hilbert transform technique, and providing spatial frequency information from a sample. In another embodiment, the invention provides a spatial frequency domain imaging (SFDI) device adapted for demodulation using two or less imaging frames.

Abstract: The present invention relates to optical devices and methods of extracting optical properties, and depth and fluorescence information for visualizing samples. In one embodiment, the present invention provides a multi-frequency synthesis and extraction (MSE) method for quantitative tissue imaging. In another embodiment, the present invention provides a method of obtaining optical properties and depth information by illuminating a sample with binary square wave patterns of light, wherein a series of spatial frequency components are simultaneously attenuated and can be extracted. In another embodiment, the present invention provides an optical imaging apparatus comprising a Spatial Frequency Domain Imaging (SFDI) device modified to condense frequency information content into a single charged coupled device (CCD) frame, multi-pixel and/or single-pixel sensor using frequency-synthesized patterns.

Abstract: The present invention relates to methods and devices that may be used to extract spatial frequency information. In one embodiment, the invention provides an instrument configured to extract data using a two-dimensional (2D) Hilbert transform technique, and providing spatial frequency information from a sample. In another embodiment, the invention provides a spatial frequency domain imaging (SFDI) device adapted for demodulation using two or less imaging frames.

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.

Abstract: An apparatus for wide-field functional imaging (WiFI) of tissue includes a spatially modulated reflectance/fluorescence imaging (SI) device capable of quantitative subsurface imaging across spatial scales, and a laser speckle imaging (LSI) device capable of quantitative subsurface imaging across spatial scales using integrated with the (SI) device. The SI device and LSI device are capable of independently providing quantitative measurement of tissue functional status.

Abstract: A probe for obtaining quantitative optical properties and chromophore concentrations of tissue components in tissue in-vivo at superficial depths and at source-detector separations of 5 mm or less includes a source fiber providing light to expose the tissue, a diffuser layer into which light from the source fiber is directed and then from the diffuser layer to and/or into the tissue, and a detector fiber arranged relative to the diffuser layer for detecting backscattered and/or reflected light returned from the tissue without transmission through the diffuser layer.

Abstract: A method and an apparatus for noninvasively and quantitatively determining spatially resolved absorption and reduced scattering coefficients over a wide field-of-view of a food object, including fruit or produce, uses spatial-frequency-domain imaging (SFDI). A single modulated imaging platform is employed. It includes a broadband light source, a digital micromirror optically coupled to the light source to control a modulated light pattern directed onto the food object at a plurality of selected spatial frequencies, a multispectral camera for taking a spectral image of a reflected modulated light pattern from the food object, a spectrally variable filter optically coupled between the food object and the multispectral camera to select a discrete number of wavelengths for image capture, and a computer coupled to the digital micromirror, camera and variable filter to enable acquisition of the reflected modulated light pattern at the selected spatial frequencies.

Abstract: A method of noncontact imaging for performing qualitative and quantitative analysis of wounds includes the step of performing structured illumination of surface and subsurface tissue by both diffuse optical tomography and rapid, wide-field quantitative mapping of tissue optical properties within a single measurement platform. Structured illumination of a skin flap is performed to monitor a burn wound, a diabetic ulcer, a decubitis ulcer, a peripheral vascular disease, a skin graft, and/or tissue response to photomodulation. Quantitative imaging of optical properties is performed of superficial (0-5 mm depth) tissues in vivo. The step of quantitative imaging of optical properties of superficial (0-5 mm depth) tissues in vivo comprises pixel-by-pixel demodulating and diffusion-model fitting or model-based analysis of spatial frequency data to extract the local absorption and reduced scattering optical coefficients.

Abstract: A probe for obtaining quantitative optical properties and chromophore concentrations of tissue components in tissue in-vivo at superficial depths and at source-detector separations of 5 mm or less includes a source fiber providing light to expose the tissue, a diffuser layer into which light from the source fiber is directed and then from the diffuser layer to and/or into the tissue, and a detector fiber arranged relative to the diffuser layer for detecting backscattered and/or reflected light returned from the tissue without transmission through the diffuser layer.

Abstract: An improvement in a method for quantitative modulated imaging to perform depth sectioned reflectance or transmission imaging in a turbid medium, such as human or animal tissue is directed to the steps of encoding periodic pattern of illumination preferably with a fluorescent excitation wavelength when exposing a turbid medium to the periodic pattern to provide depth-resolved discrimination of structures within the turbid medium; and reconstructing a non-contact three dimensional image of the structure within a turbid medium. As a result, wide field imaging, separation of the average background optical properties from the heterogeneity components from a single image, separation of superficial features from deep features based on selection of spatial frequency of illumination, or qualitative and quantitative structure, function and composition information is extracted from spatially encoded data.

Abstract: Disclosed herein is a method of treating mammalian, for example, human, skin afflicted with a sebaceous follicle disorder, for example, acne. The method involves cooling an exposed surface of a region afflicted with the disorder and applying light, for example, light from a coherent or incoherent light source, to the region. The applied light reduces the size and/or density of lesions associated with the disorder in the treated region, and can reduce or otherwise alleviate lesion-associated skin inflammation in the treated region. Cooling preserves the surface, for example, epidermis, of the skin. The method, therefore, is effective at treating the disorder while at the same time avoiding or minimizing thermal damage to the exposed surface of the skin.

Abstract: An apparatus for wide-field functional imaging (WIFI) of tissue includes a spatially modulated reflectance/fluorescence imaging (SI) device capable of quantitative subsurface imaging across spatial scales, and a laser speckle imaging (LSI) device capable of quantitative subsurface imaging across spatial scales using integrated with the (SI) device. The SI device and LSI device are capable of independently providing quantitative measurement of tissue functional status.

Abstract: A digital imaging system provides color information of an entire port wine stain or other skin condition with a single image in CIE L*a*b* color space (L*, a*) derived from RGB pixel data (R, G, B). Cross-polarization optics produce marked reduction in specularly reflected light in the images. A patient positioning device allows for repeatable positioning of the patient's head or body portion. The digital nature of the system provides a near real-time mapping of melanin and erythema or other skin chromophore metrics. The cross-polarized diffuse reflectance color digital imaging system obtains subsurface skin color information and acquisition of facial images in a reproducible fashion at a fixed distance from an illumination source at optimized angles of view depending on the region of interest being imaged.

Abstract: A method and an apparatus for noninvasively and quantitatively determining spatially resolved absorption and reduced scattering coefficients over a wide field-of-view of a food object, including fruit or produce, uses spatial-frequency-domain imaging (SFDI). A single modulated imaging platform is employed. It includes a broadband light source, a digital micromirror optically coupled to the light source to control a modulated light pattern directed onto the food object at a plurality of selected spatial frequencies, a multispectral camera for taking a spectral image of a reflected modulated light pattern from the food object, a spectrally variable filter optically coupled between the food object and the multispectral camera to select a discrete number of wavelengths for image capture, and a computer coupled to the digital micromirror, camera and variable filter to enable acquisition of the reflected modulated light pattern at the selected spatial frequencies.

Abstract: A method of optically analyzing tissue in vivo in an individual to obtain a unique spectrum for the tissue of the individual includes the steps of optically measuring the tissue of the individual using broadband diffuse optical spectroscopy (DOS) to measure a normalized tissue water spectrum of the individual or noninvasively optically line scanning a tissue site on the individual at a plurality of points, then determining spectral differences between the normalized tissue water spectrum and a pure water spectrum at each point of a line scan, generating a bound water index (BWI) corresponding to the spectral differences, and identifying a tissue state corresponding to the scanned tissue based on the BWI.

Abstract: A device and method for accurately performing quantitative diffuse optical spectroscopy on a sample includes a light source and a source optical fiber that is optically coupled to the light source. A diffuser material is interposed between the source optical fiber and the sample, the diffuser material comprising a high scattering, low absorption material. The diffuser material effectively increases the photon path length from the light source to the sample, which limits the depth of interrogation to superficial volumes despite the penetrating nature of the radiation typically used. A detector optical fiber is provided adjacent to or laterally disposed from the source optical fiber. The detector optical fiber is coupled to a detector which detects photons collected in the detector optical fiber. The detector optical fiber and the source optical fiber may be separated by a distance of less than 5 mm while still permitting the diffusion approximation to remain valid.

Abstract: Illumination with a pattern of light allows for subsurface imaging of a turbid medium or tissue, and for the determination of the optical properties over a large area. Both the average and the spatial variation of the optical properties can be noninvasively determined. Contact with the sample or scanning is not required but may be desired. Subsurface imaging is performed by filtering the spectrum of the illumination in the Fourier domain but other filtering approaches, such as wavelet transform, principle component filter, etc may be viable as well. The depth sensitivity is optimized by changing the spatial frequency of illumination. A quantitative analysis of the average optical properties and the spatial variation of the optical properties is obtained. The optical properties, i.e. reduced scattering and absorption coefficients are determined from the modulated transfer function, MTF.

Abstract: Disclosed herein is a method of treating mammalian, for example, human, skin afflicted with a sebaceous follicle disorder, for example, acne. The method involves cooling an exposed surface of a region afflicted with the disorder and applying energy, for example, energy from a coherent or incoherent light source, to the region. The applied energy reduces the size and/or density of lesions associated with the disorder in the treated region, and can reduce or otherwise alleviate lesion-associated skin inflammation in the treated region. Cooling preserves the surface, for example, epidermis, of the skin. The method, therefore, is effective at treating the disorder while at the same time avoiding or minimizing thermal damage to the exposed surface of the skin.

Abstract: The invention provides methods for the use of Raman spectroscopy to non-invasively detect molecular characteristics of the constituents of the aqueous humor, vitreous humor, lens or retina. The method can be employed for the detection of molecular changes underlying ocular pathologies. In one embodiment of the invention, the method involves the steps of introducing light into the eye of the subject using a laser; collecting Raman spectra emitted from the eye; dispersing the collected Raman spectra onto a detector; and analyzing detected Raman spectral data to identify a molecular change related to an ocular pathology. The non-invasive method provided by the invention makes use of techniques and equipment that enable detection of Raman spectra with light intensities that fall within acceptable safety standards.

Abstract: A probe for the characterization of optical properties, including scattering and absorption properties of a sample, such as medical and industrial samples, includes an illumination fiber to radiate light toward an object and at least two collection fibers to receive light diffusely reflected from the object. At least two of the collection fibers are spaced at different distances from the illumination fiber. A region of the sample is illuminated with light from the illumination fiber. A portion of the light is diffusely reflected by the region. A portion of the diffusely reflected light is received by the two or more collection fibers. The region is characterized based on an amount of light received by each of the collection fibers. When the method is used for medical purposes, the characterization of the region may be used to make a diagnosis.