A method of determining a condition of bone structure in a living organism includes impacting a bone to induce vibration in multiple modes having a resonance frequency in a range of about 400 Hz to about 1000 Hz, detecting at least one modal vibration response of the bone for the at least one mode of vibration, and analyzing the at least one modal vibration response to determine a modal vibration characteristic of the bone. A system for determining a condition of bone structure in a living organism includes a force input device configured to impact a bone to induce vibration having a resonance frequency of about 400 Hz to about 1000 Hz, at least one sensor configured to sense at least one modal vibration response, and a computer configured to collect modal vibration response data and analyze the modal vibration response data to determine a vibration characteristic of the bone.

A method of determining a condition of bone structure in a living organism includes impacting a bone to induce vibration in multiple modes having a resonance frequency in a range of about 400 Hz to about 1000 Hz, detecting at least one modal vibration response of the bone for the at least one mode of vibration, and analyzing the at least one modal vibration response to determine a modal vibration characteristic of the bone. A system for determining a condition of bone structure in a living organism includes a force input device configured to impact a bone to induce vibration having a resonance frequency of about 400 Hz to about 1000 Hz, at least one sensor configured to sense at least one modal vibration response, and a computer configured to collect modal vibration response data and analyze the modal vibration response data to determine a vibration characteristic of the bone.

A system for analyzing a possibility of a stress fracture in a patient's bone by applying a vibration of a selected frequency to a patient at a selected anatomical location and analyzing the resulting vibration detected at another anatomical location. Analysis may be based on a database. A probability of the existence of a fracture may be displayed. System software may provide usage instructions.

A system for treating soft tissue of a patient. The system includes a treatment head and a computer portion. The treatment head includes a probe and an electrode operably coupled to the probe. The probe and electrode are configured to respectively deliver a mechanical force impulse and an electrical stimulation to the soft tissue when placed in operable contact with the soft tissue. The computer portion includes a CPU and is configured to coordinate the delivery of the mechanical force impulse and electrical stimulation relative to each other. The system is configured to sense a shockwave in the soft tissue of the patient, the shockwave resulting from the mechanical force impulse delivered to the soft tissue via the probe. The system is also configured to analyze a characteristic of the sensed shockwave and configure the electrical stimulation to be delivered to the soft tissue via the electrode based on the characteristic analysis of the sensed shockwave. The characteristic may be at least one of frequency of the sensed shockwave, amplitude of the sensed shockwave, and/or wave shape (form) of the sensed shockwave.

A system for treating soft tissue of a patient. The system includes a treatment head and a computer portion. The treatment head includes a probe and an electrode operably coupled to the probe. The probe and electrode are configured to respectively deliver a mechanical force impulse and an electrical stimulation to the soft tissue when placed in operable contact with the soft tissue. The computer portion includes a CPU and is configured to coordinate the delivery of the mechanical force impulse and electrical stimulation relative to each other. The system is configured to sense a shockwave in the soft tissue of the patient, the shockwave resulting from the mechanical force impulse delivered to the soft tissue via the probe. The system is also configured to analyze a characteristic of the sensed shockwave and configure the electrical stimulation to be delivered to the soft tissue via the electrode based on the characteristic analysis of the sensed shockwave. The characteristic may be at least one of frequency of the sensed shockwave, amplitude of the sensed shockwave, and/or wave shape (form) of the sensed shockwave.

A computer-implemented method for contextually controlling a surgical device is disclosed. The method includes receiving, by a computer system, perioperative data from the surgical device, the perioperative data associated with a surgical procedure; receiving, by the computer system, images from a scope, the images visualizing the surgical device during the surgical procedure; determining, by the computer system, an attribute of the surgical device from the images; determining, by the computer system, procedural context data based at least on the perioperative data and the attribute of the surgical device; and controlling, by the computer system, the surgical device according to the procedural context data.

The present invention relates to a system and method for objective, real-time acoustic measurement and feedback for proper fit and fill of hip implants during total hip replacement surgery, or other bone implant surgical procedures.

A device for measuring a mechanical property of a tissue includes a probe configured to perturb the tissue with movement relative to a surface of the tissue, an actuator coupled to the probe to move the probe, a detector configured to measure a response of the tissue to the perturbation, and a controller coupled to the actuator and the detector. The controller drives the actuator using a stochastic sequence and determines the mechanical property of the tissue using the measured response received from the detector. The probe can be coupled to the tissue surface. The device can include a reference surface configured to contact the tissue surface. The probe may include a set of interchangeable heads, the set including a head for lateral movement of the probe and a head for perpendicular movement of the probe. The perturbation can include extension of the tissue with the probe or sliding the probe across the tissue surface and may also include indentation of the tissue with the probe. In some embodiments, the actuator includes a Lorentz force linear actuator. The mechanical property may be determined using non-linear stochastic system identification. The mechanical property may be indicative of, for example, tissue compliance and tissue elasticity. The device can further include a handle for manual application of the probe to the surface of the tissue and may include an accelerometer detecting an orientation of the probe. The device can be used to test skin tissue of an animal, plant tissue, such as fruit and vegetables, or any other biological tissue.

Systems, methods, and devices include a neurological function assessment system involving a first assessment tool (e.g., hammer) with one or more first sensors. The system includes a second assessment tool being a wearable device operable to wrap around a body part of a subject. One or more second sensors are disposed on the wearable device operable to sense a target area at the body part. The system collects first sensor data, from the first assessment tool, corresponding to an assessment event at the first assessment tool; and collects second sensor data, from the second assessment tool, corresponding to the assessment event. Additionally, the system presents, at a display, an indication of an objective neurological assessment parameter value calculated based on the first sensor data and the second sensor data. An objective neurological assessment parameter value can be calculated based on the first sensor data and/or the second sensor data.

A system composed of different densities of materials making up a device for the assessment, treatment, diagnosis, advertisement, modelling, or otherwise impacting another object, person, living thing, or material. A method for distributing the centre of mass of a device by placing dense material or materials distal to the handle thereby managing the mechanical advantage of the instrument. The dense material is positioned within the shaft of the instrument, thereby allowing the distal head to be made partially or entirely out of an elastic polymer, organic, or inorganic substance. Modulation of the characteristics of the device allows for modulating of the impulse or striking force elicited by the device. The device may therefore be swung along an axis with resultant torque elicited. This device may be used for medical, industrial, personal, or other purposes.