An apparatus is disclosed. The apparatus has a skin assessment member. The skin assessment member is transparent. The skin assessment member is a single, integral member. The skin assessment member is nonporous. A length and a width of the skin assessment member are each between 20 times and 80 times larger than a thickness of the skin assessment member. A density of a material forming the skin assessment member is between 0.75 g/cm.sup.3 and 2.2 g/cm.sup.3. The skin assessment member includes a plurality of markings that are disposed flush with a flat surface of the skin assessment member or fully embedded within the skin assessment member.

Apparatuses and methods are disclosed for assessing the texture of skin using images thereof. In exemplary embodiments, a texture map of an area of skin is generated from a combination of a standard white light image, a parallel-polarized image, and a cross-polarized image of the area of skin. The texture map is then flattened to remove the underlying curvature of the skin. A texture roughness metric is then generated based on the flattened texture map. An image of the texture map and the metric can be displayed to provide visual and alphanumeric representations of the texture of skin, thereby facilitating the comparison of baseline and follow-up images of the skin, such as those taken before and after treatment.

The following disclosure discusses systems and methods of detecting and analyzing cutaneous conditions. According to one embodiment, a 2D image of the cutaneous condition and a set of 3D point clouds associated with the 2D image are captured using an image capturing device. The 2D image and the set of 3D point clouds are sent to a computing device. The computing device generates a 3D surface according to the set of 3D point clouds. Subsequently, the computing device receives a depth map for the 2D image based upon the 3D surface from another computing device such that the depth map comprises depth data for each pixel of the 2D image. The cutaneous condition may then be measured and analyzed based upon the depth map using the computing device.

An electronic device is disclosed. The electronic device of the present invention comprises a body; a head being extended from the body, the head including an internal space for accommodating; a light transmission circle being formed on the head; and a measurement module being installed in the internal space of the head, the measurement module facing the light transmission circle, wherein the measurement module includes: a plurality of first light source providing the light transmission circle with light for speckle imaging; a image sensor being positioned between the light transmission circle and the plurality of first light sources, the image sensor being spaced apart from the plurality of first light sources, the image sensor facing the light transmission circle; and a lens covering the image sensor, the lens being positioned between the image sensor and the light transmission circle.

The invention concerns a Thickness Shear Mode (TSM) biosensor (1) which comprises an ex vivo living skin explant (2), the skin explant (2) comprising at least one of the skin layers among: hypodermis, dermis (2A), epidermis (2B) and the stratum corneum (2C), a TSM transducer (3) which comprises: an AT cut quartz resonator 3C which has two opposite exterior surfaces (3A,3B), and two conducting electrodes (4A, 4B), each conducting electrode being deposited on one of the two exterior surfaces (3A,3B), the TSM transducer (3) allowing to determine micro rheological characteristics of the living skin explant (2) by piezoelectric transducing using shear waves, the TSM transducer (3) presenting: measuring means (30), monitoring and calculating means (31) which monitor an evolution in time of an electrical response of the living skin explant (2), and which calculate in time, from the electrical response, micro rheological characteristics of the living skin explant (2), a bottom surface of the skin explant (2) being in contact with the TSM transducer (3), a top surface of the skin explant (2) being in contact with air.

An apparatus for treating human skin includes an outer housing including a graspable portion and an applicator head engagement structure. The apparatus includes an image capture device that captures images of the human skin through an opening in the applicator head. A processor analyzes the images of the human skin to identify skin deviations. A cartridge includes a nozzle located in the applicator head. The applicator head includes an outer housing engagement structure that engages the applicator head engagement structure with the cartridge inserted into the outer housing to inhibit removal of the cartridge from the outer housing. A cap engages the applicator head. The cap has a locked configuration connected to the applicator head where the applicator head is removable from the outer housing and an unlocked configuration connected to the applicator head where removal of the applicator head from the outer housing is inhibited.

Exemplary embodiments relate to a skin-adherable electronic device including a semiconductor circuit unit including a circuit element including an electrode and an interconnect, and a semiconductor device including an insulating layer and an active layer; and a flexible patch that can adhere to skin and including a plurality of through-holes, wherein the insulating layer includes a plurality of through-holes corresponding to the plurality of through-holes of the flexible patch, and a method of manufacturing the same. When the active layer is made of a piezoelectric material, the electronic device may be used as a skin sensor that can acquire skin deformation and/or elasticity information.

Exemplary embodiments relate to a skin-adherable flexible patch including a flexible patch layer having one surface that can adhere to skin and configured to support a micro scale semiconductor device; and a plurality of holes passing through from one surface of the flexible patch to the other surface of the flexible patch, and a method for manufacturing the flexible patch.

The present technology relates to an information processing apparatus, an information processing method, and a program capable of checking a plurality of types of analysis results regarding one skin condition item intuitively and easily. The information processing apparatus according to one aspect of the present technology includes an acquisition unit configured to obtain information representing a plurality of types of analysis results on skin conditions obtained by analyzing an image of a skin at a same position, and a presentation unit configured to simultaneously display, on a same image, a plurality of types of visualized information obtained from visual representation of the plurality of types of analysis results. The present technology is applicable to a mobile terminal used together with a skin measurement instrument that photographs a skin image.

The invention provides a device for the mechanical detection of a specific underlying tissue in a subject, comprising a container, wherein the container comprises a probe, spring, sensor, and signal indicator, wherein when a mechanical force is applied to the probe, it is transmitted to the sensor, whereby the sensor provides the signal indicator with a signal and the signal indicator indicates to the user an indication of detection of the specific underlying tissue in the subject. The sensor of the invention can be an electrical sensor such as a piezoelectric force transducer or a balloon. The invention also provides a method of performing a cricothyrotomy using the device.