The present invention relates to methods and devices for measuring the musculature of animal. In some embodiments, the musculature of the animal is measured using by generating traces of the animal using a flexicurve ruler and comparing the traces to a reference and/or previous traces of the animal. The methods can be used to improve an animal's musculature by evaluating the muscle development of the animal and changing the animal's diet or exercise regime based on the results of the evaluation.

Anatomical measurements of non-visible aspects of features of living organisms that include a visible contoured shape on the anatomical region of the living organism is disclosed. The system and method include an imager configured to take a series of images of an anatomical region of a living organism, such as a human patient in a clinic, doctor's office, or hospital. The system and method create a three-dimensional digital anatomical model of the exterior or visible part of the anatomical region that includes a target feature, such as a breast, nose, foot, or tumor. The target feature within the three-dimensional digital model is then isolated and manipulated to find measurements of non-visible aspects of the feature, such as mass, distances between visible points which pass through invisible tissues, e.g., depth and base width, surface distance between visible points, volume, area, surface area, circumference, and surface angle measurements of the feature.

Methods for tracking gum line changes by comparing digital 3D models of teeth and gingiva taken at different times. The digital 3D models are segmented to digitally identify the teeth from the gingiva, and the segmented digital 3D models are compared to detect gum line changes by determining differences between them relating to the gum line. Gum line changes can also be estimated by comparing one of the digital 3D models with a 3D model having a predicted original location of the gum line. Gum line change maps can be displayed to show the gum line changes determined through the tracking or estimating of changes. The digital 3D models can also be displayed with periodontal measurements placed upon them.

A foot imaging apparatus includes a support structure and a flexible membrane suspended from the support structure and configured to receive a foot thereon. The apparatus also includes a three-dimensional imager located under the flexible membrane and configured to acquire a topographical plantar image of the foot on the flexible membrane. The apparatus further includes a monitoring unit for monitoring a monitored region in order to evaluate a positioning of the foot on the flexible membrane. The monitoring unit includes a camera having a field of view, and at least one light deflector arranged to deflect light from the monitored region into the field of view of the camera. The camera acquires a monitoring image of the monitored region after deflection by the at least one light deflector. The monitoring image contains information about the positioning of the foot on the flexible membrane. A foot imaging method is also provided.

Methods for tracking gum line changes by comparing digital 3D models of teeth and gingiva taken at different times. The digital 3D models are segmented to digitally identify the teeth from the gingiva, and the segmented digital 3D models are compared to detect gum line changes by determining differences between them relating to the gum line. Gum line changes can also be estimated by comparing one of the digital 3D models with a 3D model having a predicted original location of the gum line. Gum line change maps can be displayed to show the gum line changes determined through the tracking or estimating of changes. The digital 3D models can also be displayed with periodontal measurements placed upon them.

A foot imaging apparatus includes a support structure and a flexible membrane suspended from the support structure and configured to receive a foot thereon. The apparatus also includes a three-dimensional imager located under the flexible membrane and configured to acquire a topographical plantar image of the foot on the flexible membrane. The apparatus further includes a monitoring unit for monitoring a monitored region in order to evaluate a positioning of the foot on the flexible membrane. The monitoring unit includes a camera having a field of view, and at least one light deflector arranged to deflect light from the monitored region into the field of view of the camera. The camera acquires a monitoring image of the monitored region after deflection by the at least one light deflector. The monitoring image contains information about the positioning of the foot on the flexible membrane. A foot imaging method is also provided.

Methods for tracking gum line changes by comparing digital 3D models of teeth and gingiva taken at different times. The digital 3D models are segmented to digitally identify the teeth from the gingiva, and the segmented digital 3D models are compared to detect gum line changes by determining differences between them relating to the gum line. Gum line changes can also be estimated by comparing one of the digital 3D models with a 3D model having a predicted original location of the gum line. Gum line change maps can be displayed to show the gum line changes determined through the tracking or estimating of changes. The digital 3D models can also be displayed with periodontal measurements placed upon them.

The system includes an instrument for determining the anatomical, biomechanical, and physiological properties of a body segment that includes one or more force sensitive probes is provided. A human operator actuates one or more force sensitive probes, wherein the force sensitive probes are positioned at the surface of the body segment. The operator pushes on the force sensitive probes with varying force applied on the body segment to measure tissue deflection forces. The instrument may include one or more of gyroscopes, accelerometers, and magnetometers capable of measuring changes in tissue deflection caused by the force sensitive probes relative to a grounded reference frame in 3-D space, wherein the tissue deflection force data and the change in tissue deflection data are used to compute segment tissue viscoelastic properties. The instrument may also be untethered or wireless.

The present disclosure provides systems, methods and components of a mechanical palpation sensing device system. The mechanical palpation sensing device includes a plurality of probe tips. A plurality of force transfer pins extend from the plurality of probe tips. A transfer plate is coupled to the plurality of probe tips. The transfer plate houses the plurality of force transfer pins. The plurality of force transfer pins are independently slidable within the transfer plate. The mechanical palpation sensing device includes a sensor plate including a plurality of contact points. The plurality of sensors are positioned on at least one of the plurality of force transfer pins and the sensor plate intermediate the sensor plate and the plurality of force transfer pins to contact the plurality of contact points.

The invention relates to a method for registering non-radiographic virtual models of a mandibular arch and a maxillary arch of an individual with a non-radiographic digital model of the face of said individual, comprising: fastening a mandibular marker rigidly on the mandibular arch of the individual, said mandibular marker defining a first frame of reference, providing a non-radiographic virtual model of the mandibular arch and a non-radiographic virtual model of the maxillary arch, digitising at least one portion of the surface of the teeth or a prosthetic device integral with said arch and at least one rigid portion of said marker by means of an intra or extra-oral camera, so as to produce a digital recording of said portions of the mandibular arch and the marker in a same second frame of reference, from said recording and the virtual models of the mandibular arch and the mandibular marker, matching the digital model of the mandibular marker with the marker, and the virtual model of the mandibular arch with said arch, and localizing the virtual model of the mandibular arch in the first frame of reference, acquiring a non-radiographic digital model of the face of the patient, and localizing the digital model of the face in the first frame of reference, so as to register the virtual models of the maxillary and mandibular arches with said digital model of the face.