Systems, methods, apparatuses, and medical devices for harmonizing data from a plurality of non-invasive sensors are described. A physiological parameter can be determined by harmonizing data between two or more different types of non-invasive physiological sensors interrogating the same or proximate measurement sites. Data from one or more first non-invasive sensors can be utilized to identify one or more variables that are useful in one or more calculations associated with data from one or more second non-invasive sensors. Data from one or more first non-invasive sensors can be utilized to calibrate one or more second non-invasive sensors. Non-invasive sensors can include, but are not limited to, an optical coherence tomography (OCT) sensor, a bio-impedance sensor, a tissue dielectric constant sensor, a plethysmograph sensor, or a Raman spectrometer.

In some embodiments, a method of determining a personalized skincare recommendation is provided. A computing system receives data depicting a face of a subject. The computing system determines features based on the data depicting the face of the subject. The computing system provides the features to an ageotype classifier to generate a predicted skin ageotype for the subject. The computing system generates the personalized skincare recommendation based on at least the predicted skin ageotype.

The disclosure relates to a method and an apparatus for determining anthropological type of a user is provided. The apparatus includes a spectral optical sensor, a thickness sensor, memory storing one or more computer programs, and one or more processors communicatively coupled to the spectral optical sensor, the thickness sensor and the memory wherein the one or more computer programs include computer-executable instructions that, when executed by the one or more processors, cause the apparatus to calculate an overall melanin concentration value and a melanin concentration ratio value of a user's skin, compare the obtained scattering intensity values with values of scattering intensity corresponding to a special skin tone from a database of simulated data, compare the obtained thickness value with data of skin thickness from the database of simulated data, compare the calculated overall melanin concentration value and the calculated melanin concentration ratio value of the user's skin with data of an overall melanin concentration and a melanin concentration ratio from the database of simulated data, and assign an anthropological type to the user in accordance with the selected skin sample.

A personal care system having a treatment device for applying a treatment to the skin or hair of a user is provided. The treatment device has a camera for taking an image of the skin. The system may include or be in communication with an application programming interface (API) that can process the image. The system or an associated API can recommend the use of treatment regimens or topical products according to information determined from the digital image of the skin.

Disclosed herein are compositions and methods for use in conjunction with assessment of facial wrinkles related to tendon repair. Embodiments disclosed herein can assess facial wrinkles using artificial intelligence platform.

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.

An imaging device includes a camera 31, a light source 32, a polarizer 35 arranged between the camera 31 plus the light source 32 and an object 11, and a spatial light modulator 40A arranged between the polarizer 35 and the object 11 to control a revolution angle of an emitting light polarization plane relative to an incident light polarization plane.

A sensor system for measuring an elastic modulus and a shear modulus and a method for evaluating a tissue. The invention pertains to a method for determining the presence of and/or characterizing abnormal growths, using a piezoelectric finger sensor (PEFS) system. The PEFS system may be particularly useful for screening for tumors and various forms of cancer. Additionally, the PEFS system may be useful for various dermatological applications.

The present invention pertains to methods of determining where, on the skin, a diagnostic, therapeutic, or cosmetic agent is likely to be most effectively applied (e.g., injected), and to methods for monitoring a patient after such an agent has been administered. The monitoring can produce information useful in determining whether a diagnostic, therapeutic (e.g., surgical), or cosmetic regime should be initiated, continued, continued in a modified fashion, or terminated (e.g., for a brief or prolonged period of time). The methods can be repeated periodically and use a non-invasive, in vivo form of digital image speckle correlation (DISC) to track deformation of the skin.

Methods and systems for providing depth-resolved real-time visual feedback to a physician during cosmetic dermal filler injections with micrometer spatial resolution utilizing a noninvasive optical coherence tomography/elastography, 2D-3D virtual and real time system. This system can be automated to direct proper volumes and viscosity of the necessary injection substances. The methods and systems allow for assessment of the elasticity of the tissue before and after the injection to evaluate the efficacy of the injection, with predetermined virtual results before and matched post injection images. The elasticity assessment method preferably utilizes a focused air-pulse to induce a micrometer scale displacement in the skin and the optical coherence tomography system to image this displacement. By utilizing a model-based reconstruction method, the viscoelasticity of the tissue at a specific measurement position can be obtained and virtual and post injection real time projections can be imaged.