A system and method for automated body mass index is disclosed. The disclosed method operates within a system architecture including one or more computing devices, one or more servers, and one or more databases. A processor operating within the one or more servers executes one or more algorithms for detecting relevant features associated with a potential client's multimedia information. The method may include calculating feature values, such as abdomen circumference, face width, face height, cheekbone width, jaw width, and neck width, and the like as well as calculating the body mass index of the potential client using one or more regression algorithms. A baseline and updated BMI may be determined, and used for determining a baseline and updated value.

A method for identifying human joint characteristics, the method including the steps of: using a mobile imaging device, taking at least one image of the joint, and then identifying a joint pain location by identifying three different locations in the image near the joint, so that a center point between the locations can be triangulated.

A surgical access assembly comprises a trocar and a surgical instrument. The trocar comprises a housing and an access tube extending distally from the housing. The housing comprises a hollow light emitter. The housing and the access tube define a lumen extending through the housing and the access tube. The hollow light emitter is configured to project light in the lumen. The surgical instrument comprises an end effector and a shaft extending proximally from the end effector. The shaft comprises an optical receiver positioned within reach of the light from the hollow light emitter. The shaft further comprises a light guide extending from the optical receiver along at least a portion of the shaft toward the end effector.

Systems and methods of measuring feet and designing and creating orthopedic inserts are described. A leg length discrepancy of a user is measured and this data, along with foot size are input into a computer. The computer then creates a computer model of a custom shoe insert based on this information. The computer model is then sent to a 3D printer to print the insert. The insert consists of a base insert with partial correction, and several additional layers that are added successively over time until a full correction is obtained. This eliminates any pain associated with a fully corrective insert, and allows the body to adjust gradually to the correction.

A method and system for sizing an earpiece include situating a calibration device proximate a user's ear. The user holds an image capture device so as to aim the image capture device at the user's ear. The user then touches and holds a random area of the touch screen display and releases the touch screen display to activate the image capture device and capture an image of the user's ear and the calibration device. The captured image is then analyzed and an earpiece size is determined based on the analysis of the image.

The invention relates to a method for modeling the mandibular kinematics of a patient, comprising: acquiring at least one stereoscopic image of the face of the patient by means of a stereoscopic camera, constructing, from said stereoscopic image, a three-dimensional surface model of the face of the patient, identifying characteristic elements of the face of the patient on said stereoscopic image or on said three-dimensional surface model of the face of the patient, from said characteristic elements, determining, on said stereoscopic image, respectively said three-dimensional surface model of the face of the patient, reference points, axes and planes of the face of the patient, obtaining a three-dimensional model of the maxillary dental arch and a three-dimensional model of the mandibular dental arch of the patient, registering the three-dimensional models of the dental arches with respect to the reference planes of the three-dimensional surface model of the patient, recording the mandibular kinematics of the patient, applying said recorded mandibular kinematics to the three-dimensional models of the registered dental arches, so as to animate said three-dimensional models.

The patient couch (1) serves for carrying out radiological medical imaging examinations by X-ray, tomography, nuclear magnetic resonance and other imaging methods. The person rests thereon in lying position for the creation of tomographic and other images. The patient couch is equipped with a capturing device, for measuring the patient's body or certain sites of the patient's body by optical, laser-optical, mechanical or electromechanical methods and/or devices. The couch has footrests for positioning the soles of the feet as when standing on vertical supporting faces with natural spreading of the feet, as well as portions for capturing at least the positions of the knee joints, the hip joint, the pelvic bone, the shoulders and the head. Further, the couch is equipped with pressure sensors for measuring the local supported weights of the various supported body sites, for reproducibly capturing the position of the skeleton with regard to its center axis as well as any rotations of shoulder and/or hip.

To appropriately evaluate skin spots by grasping a quality (characteristic) of the skin spots. A skin spot evaluation apparatus includes an area extracting unit that extracts skin spot areas corresponding to skin spots from a skin image obtained by photographing a skin of a subject; and an evaluation unit that analyzes, based on the skin spot areas extracted by the area extracting unit, at least one of the number of the skin spots, dimension of each of the skin spots and density of each of the skin spots, and generates data obtained by quantifying characteristic of the skin spots of the skin image using the analyzed result.

A method of removing microvessels includes applying a burst of acoustic energy at a target location, applying a pulse of optical energy at the target location, and promoting cavitation at the target location. The burst of acoustic energy has a pressure below 5.0 MPa. The pulse of optical energy at the target location has a fluence less than 100 mJ/cm.sup.2. At least a portion of the pulse is concurrent with the burst and the optical energy has an optical area that is overlapping with an acoustic area of the acoustic energy at the target location.

A cannula insertion system includes: a contact sensor positioning system arranged to determine a suitable location for insertion of the cannula, where the contact sensor positioning system includes: a contact sensor having a contact surface to be placed at least partially on the human or animal body to enable measurement with the contact sensor, a positioning device configured to support and position the contact sensor, and a control device arranged to control the positioning device to position the contact sensor in a desired position. The contact sensor positioning system includes one or more sensors to determine a position and/or contact force related parameter representative for a position and/or contact force of the contact sensor, and a processing device to process the position and/or contact force related parameter and to provide a position control signal to the control device, where the contact sensor is an imaging sensor.