Parametric model based computer implemented methods for determining the stiffness of a bone and systems for estimating the stiffness of a bone in vivo. The computer implemented methods include determining a complex compliance frequency response function Y(f) and an associated complex stiffness frequency response function H(f) and independently fitting a parametric mathematical model to Y(f) and to H(f). The systems include a device for measuring the stiffness of the bone in vivo and a data analyzer to determine a complex compliance frequency response function Y(f) and an associated complex stiffness frequency response function H(f).

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.

The invention relates to an automatic reflection hammer system, which comprises the following components: a reflective hammer chassis, an outer side having a detachable reflection hammer head, and a pulley, a universal joint, a vertical height adjustment mechanism, and a fixing bracket. Wherein, the reflection hammer chassis links with the universal joint, the universal joint links to the vertical height adjustment mechanism, and the vertical height adjustment mechanism links with the fixing bracket.

The invention relates to an automatic reflection hammer system, which comprises the following components: a reflective hammer chassis, an outer side having a detachable reflection hammer head, and a pulley, a universal joint, a vertical height adjustment mechanism, and a fixing bracket. Wherein, the reflection hammer chassis links with the universal joint, the universal joint links to the vertical height adjustment mechanism, and the vertical height adjustment mechanism links with the fixing bracket.

Provided is a probe for detecting in vivo hydrogen sulfide, specifically, a probe for detecting hydrogen sulfide including a complex compound into which a radioactive isotope Cu is introduced. According to specific embodiments of the present disclosure, as a result of real-time observing animal models, in which hydrogen sulfide involved in various diseases is generated in a large quantity, through optical and nuclear medicine imaging, the probe for detecting hydrogen sulfide according to the present disclosure may selectively bind with hydrogen sulfide to provide images of a site where hydrogen sulfide has abnormally increased in a cell or a tissue, thereby detecting a disease in an unexpected site without affecting the anatomical properties of the body. Accordingly, the probe may be effectively used as a means for diagnosing diseases, such as a composition for imaging, an imaging method, etc.

Devices, systems, and methods for measuring the distance and/or depth to a target bone for surgery using a robotic surgical system. The surgical robot system may be configured to depict the distance from a guide tube of the robot to a target bone of a patient as a vector. The vector may represent a view of the guide tube when the guide tube's central axis is coincident with a line of intersection of two viewplanes of a 2D image of the target bone, for example, one viewplane being sagittal and one viewplane being axial.

Provided is a probe for detecting in vivo hydrogen sulfide, specifically, a probe for detecting hydrogen sulfide including a complex compound into which a radioactive isotope Cu is introduced. According to specific embodiments of the present disclosure, as a result of real-time observing animal models, in which hydrogen sulfide involved in various diseases is generated in a large quantity, through optical and nuclear medicine imaging, the probe for detecting hydrogen sulfide according to the present disclosure may selectively bind with hydrogen sulfide to provide images of a site where hydrogen sulfide has abnormally increased in a cell or a tissue, thereby detecting a disease in an unexpected site without affecting the anatomical properties of the body. Accordingly, the probe may be effectively used as a means for diagnosing diseases, such as a composition for imaging, an imaging method, etc.

The present invention relates generally to a system and method for measuring the structural characteristics of an object. The object is subjected to an energy application processes and provides an objective, quantitative measurement of structural characteristics of an object. The system may include a device, for example, a percussion instrument, capable of being reproducibly placed against the object undergoing such measurement for reproducible positioning. The system does not include an external on/off switch or any remote on/off switching mechanism. The system also includes a disposable feature or assembly for minimizing cross-contamination between tests. The structural characteristics as defined herein may include vibration damping capacities, acoustic damping capacities, structural integrity or structural stability.

Systems and methods for digital reflex quantization and signature analysis. Movement of a stimulating device invoking a reflex response in an organism is captured as stimuli data. Electromyographic (EMG) of the reflex response is captured as EMG data. Movement resulting from the reflex response of a limb/appendage of the organism is captured as motion data. One or more of the stimuli data, the EMG data, and the motion data are analyzed to determine one or both of a motion signature and an EMG signature defining quantitative evaluation of the reflex response.