Automatically determining a medical recommendation for a patient based on multiple medical images from multiple different medical imaging modalities. In some embodiments, a method may include receiving a first and second medical images of a patient from first and second medical imaging modalities, mapping a first region of interest (ROI) on the first medical image to a second ROI on the second medical image, generating first annotation data related to the first ROI and second annotation data related to the second ROI, generating first medical clinical data related to the first ROI and second medical clinical data related to the second ROI, inputting, into a machine learning classifier, the first and second annotation data and the first and second medical clinical data, and automatically determining, by the machine learning classifier, a medical recommendation for the patient related to a medical condition of the patient.

Two types of information processing devices includes circuitry to display, on a display device, a position representation area indicating a position of each of a group of sensors that detects biomedical signals of a test subject, display on the display device a selection acceptance area accepting selection of a plurality of positions of a plurality of desired sensors, the plurality of positions being selected from the group of sensors using an operating unit, and display on the display device a waveform display area displaying a waveform output from the plurality of desired sensors corresponding to the plurality of selected positions. In the first type of information processing device, single-region data indicating a region including the plurality of selected positions is displayed in the position representation area. In the second type of information processing device, the plurality of selected positions are enlarged and displayed in the position representation area.

A wearable monitor device has a monitor having a mobile cell phone with a video camera configured to be worn on a wearer's wrist. The wearable monitor device further has a plurality of ports on the monitor for connecting health monitoring devices and a pair of clips on the monitor configured to attach the monitor to a pressure cuff or a wearable strap.

A photoacoustic apparatus, comprises a light source that irradiates an object with light; a plurality of acoustic wave detectors that receive acoustic waves generated from the object, convert the acoustic waves into an electrical signal, and output the electrical signal; and an information acquisition unit that acquires information of the object, based on the electrical signals, wherein the information acquisition unit acquires, for each of the acoustic wave detectors, a change in the intensity of the electrical signal, after the object that has been injected with a contrast agent is irradiated with light that decomposes the contrast agent, and acquires information relating to blood flow, based on the change in the intensity of the electrical signal.

Systems and methods are presented for evaluating a dental condition. A first digital representation of at least a portion of an oral cavity of a first patient is compared to a second digital representation of the oral cavity of the same patient. The first digital representation is representative of the oral cavity of the first patient at a first time and the second digital representation is representative of the oral cavity of the first patient at a second, later time. At least one clinically-significant difference between the first digital representation and the second digital representation are automatically identified and the first digital representation is displayed in a way that highlights the at least one clinically significant difference.

The present technology relates to an information processing device, an information processing method, and a program capable of facilitating fixed-point observation on skin condition. The information processing device according to an aspect of the present technology acquires an image that shows a predetermined feature point of a user who is a measurer of skin condition, and a measurement portion of skin condition, and analyzes the image, and then recognizes a position of the feature point. Furthermore, information indicating the measurement portion is displayed at a predetermined position on the image while setting, as a reference, the recognized position of the feature point. The present technology is applicable to information processing devices such as a tablet terminal, a smartphone, and a personal computer.

Disclosed herein is a device defining a generally closed volume therein, henceforth known as a “shuttle”, not permanently fixed to a probe or other surface inside the cryostat, into which gas and/or liquid—most preferably helium gas or liquid—can pass into or out of in a controlled and predictable manner. The passage of gas or liquid into the shuttle is preferably via a porous barrier so that sterile conditions can be maintained in the interior of the shuttle.

There is employed an information processing system including: a photoacoustic image acquiring unit that acquires photoacoustic image data derived from photoacoustic waves generated by an object that is irradiated with light; a setting unit that sets a simulation condition; a reference image acquiring unit that acquires simulation image data being photoacoustic image data corresponding to the simulation condition set by the setting unit; and a display controlling unit that causes a photoacoustic image based on the photoacoustic image data and a reference image based on the simulation image data, to be displayed on a display unit.

Methods and devices are provided for optically interrogating subsurface tissues of a body. Optical interrogation includes illumination of a target tissue through an external body surface and detection of light emitted in response to the illumination. Parameters of such optical interrogation are controlled according to operational modes that are selected to maximize detector sensitivity to a target property of the target subsurface tissues. Operational modes are selected based on detected properties of the target tissue and of intervening tissues (e.g., thickness of intervening tissues between the target tissue and an external body surface) between the target tissue and an interrogating optical device. Operational modes can be determined based on simulated optical interrogation of subsurface tissue across a range of optical detector configurations and tissue conditions. Operational modes can include calibration curves specifying optical interrogation parameters based on intervening tissue properties.

Embodiments relate to a method and system to improve fat suppression and reduce motion and off-resonance artifacts in magnetic resonance imaging (MRI) by using a background-suppressed, reduced field-of-view (FOV) radial imaging. The reduction of such artifacts provides improved diagnostic image quality, higher throughput of MRI scans for the imaging center, and increased patient comfort. By using a small FOV radial acquisition that only encompasses the structures of interest, structures that cause motion artifacts, such as the anterior abdominal wall, bowel loops, or blood vessels with pulsatile flow, are excluded from the image. According to an embodiment, combining a small FOV radial acquisition with one or more background-suppression techniques minimizes the impact of artifacts caused by anatomy outside of the FOV.