Abstract: An optical probe comprises three optical elements including at least one light source and at least one light detector. The three optical elements are positioned in a triangular configuration. Three optical fibers are each coupled to one of the three optical elements and have an exposed distal end portion. At least one light shroud is disposed radially around the exposed distal end portions of at least one of the optical fibers coupled to the at least one light source.

Abstract: The present invention is directed to an ultrasound device for use in implementing therapeutic treatments and transdermal analyte delivery. The device includes a piezoelectric transducer that efficiently and safely converts electrical energy to ultrasonic waves, and has a unique structure including a piezoelectric element positioned between two opposing, flexible concave covers. The device may be used for various therapeutic purposes including wound healing, tissue stimulation and transdermal analyte delivery. The invention is further directed to a novel analyte delivery system including the ultrasound device and an encapsulated analyte.

Abstract: An optical probe comprises three optical elements including at least one light source and at least one light detector. The three optical elements are positioned in a triangular configuration. Three optical fibers are each coupled to one of the three optical elements and have an exposed distal end portion. At least one light shroud is disposed radially around the exposed distal end portions of at least one of the optical fibers coupled to the at least one light source.

Abstract: One aspect of the invention provides a method for assessing peripheral arterial function in a subject. The method includes: conducting diffuse correlation spectroscopy on a local region of the subject; applying pressure to restrict blood flow to the local region for a period of time; conducting diffuse correlation spectroscopy on the local region while the pressure is applied; releasing the pressure; and conducting diffuse correlation spectroscopy on the local region after the pressure is released. Another aspect of the invention provides a system including: a diffuse correlation spectroscopy device and a pressure cuff.

Abstract: Multi-frequency Diffuse Photon Density Wave (DPDW) methodology at near infrared wavelengths is used to non-invasively measure the optical absorption and reduced scattering coefficients of tissue at depths of several millimeters to quantify the depth and degree of tissue damage. A digitally-controlled stepper motor and variable RF generator enable the user to select the distance between the light source and detector and the modulation frequency through software. This allows for the collection of virtually unlimited number of data points, enabling precise selection of the volume and depth of tissue that will be characterized.

Abstract: The present invention is directed to an ultrasound device for use in implementing therapeutic treatments and transdermal analyte delivery. The device includes a piezoelectric transducer that efficiently and safely converts electrical energy to ultrasonic waves, and has a unique structure including a piezoelectric element positioned between two opposing, flexible concave covers. The device may be used for various therapeutic purposes including wound healing, tissue stimulation and transdermal analyte delivery. The invention is further directed to a novel analyte delivery system including the ultrasound device and an encapsulated analyte.

Abstract: Optical changes of tissue during wound healing measured by Near Infrared and Diffuse Reflectance Spectroscopy are shown to correlate with histologic changes. Near Infrared absorption coefficient correlated with blood vessel in-growth over time, while Diffuse Reflectance Spectroscopy (DRS) data correlated with collagen concentration. Changes of optical properties of wound tissue at greater depths are also quantified by Diffuse Photon Density Wave (DPDW) methodology at near infrared wavelengths. The diffusion equation for semi-infinite media is used to calculate the absorption and scattering coefficients based on measurements of phase and amplitude with a frequency domain or time domain device. An increase in the absorption and scattering coefficients and a decrease in blood saturation of the wounds compared to the non wounded sites was observed. The changes correlated with the healing stage of the wound.

Abstract: Optical changes of tissue during wound healing measured by Near Infrared and Diffuse Reflectance Spectroscopy are shown to correlate with histologic changes. Near Infrared absorption coefficient correlated with blood vessel in-growth over time, while Diffuse Reflectance Spectroscopy (DRS) data correlated with collagen concentration. Changes of optical properties of wound tissue at greater depths are also quantified by Diffuse Photon Density Wave (DPDW) methodology at near infrared wavelengths. The diffusion equation for semi-infinite media is used to calculate the absorption and scattering coefficients based on measurements of phase and amplitude with a frequency domain or time domain device. An increase in the absorption and scattering coefficients and a decrease in blood saturation of the wounds compared to the non wounded sites was observed. The changes correlated with the healing stage of the wound.

Abstract: A device for measuring the progress of healing of a wound over time includes at least one diode laser source that provides respective input wavelengths into at least one source fiber, a first optical switch that sequentially switches wavelengths among the respective input wavelengths into the at least one source fiber, a probe that does not touch the wound dunng use, the probe including the at least one source fiber and at least two detectors spaced thereon, an optical system that provides source light from the at least one source fiber to the wound and that detects light scattered by the wound surface and provides the scattered light to the detectors, and a processing unit responsive to outputs of the detectors for providing at least four independent measurements for calculation of an absorption coefficient/Ia and a scattering coefficient/I's of the light by the wound

Abstract: Optical changes of tissue during wound healing measured by Near Infrared and Diffuse Reflectance Spectroscopy are shown to correlate with histologic changes. Near Infrared absorption coefficient correlated with blood vessel in-growth over time, while Diffuse Reflectance Spectroscopy (DRS) data correlated with collagen concentration. Changes of optical properties of wound tissue at greater depths are also quantified by Diffuse Photon Density Wave (DPDW) methodology at near infrared wavelengths. The diffusion equation for semi-infinite media is used to calculate the absorption and scattering coefficients based on measurements of phase and amplitude with a frequency domain or time domain device. An increase in the absorption and scattering coefficients and a decrease in blood saturation of the wounds compared to the non wounded sites was observed. The changes correlated with the healing stage of the wound.