This document describes techniques and apparatuses enabling determination of health state trends for a consistent patient situation. Various noninvasive health monitors can be used to sense a patient's situation and health states, including disease progression, at those states. These noninvasive health monitors may also act passively and in a patient's normal course of life, which enhances many patient's desire to submit to monitoring, as well as increase consistency of use, as in many cases the patient does little or nothing to cause his or her health monitoring and health-trend determination. With health states determined for a consistent patient situation, more accurate and more robust health trends can be determined.

The invention discloses a radio wave transducer for the detection of spinal segmental dysfunction, comprising two radio wave emitters and at least one switch; the two radio wave emitters are electrically connected to the switch; each of the two radio wave emitters has a RLC circuit consisting of a resistor, an inductor and a capacitor, one end of the resistor is electrically connected to one end of the inductance, the other end of the inductance is electrically connected to one end of the capacitor, the other end of the resistor is electrically connected to one end of the switch, the other end of the capacitor is electrically connected to the other end of the switch. This invention also discloses a method for detection of spinal segmental dysfunction.

A early detection device to diagnose scoliosis in adolescents without exposure to harmful x-rays provides a portable, accurate and inexpensive hand-held diagnostic tool to determine deviations from the Cobb Angle in the spine, the detection device connecting to a receiver unit to receive data obtained from the detection device completing the diagnostic testing for visual review and diagnosis on the receiver unit. It is also provided in alternative embodiment to test the integrity of structural components in various industries, including surface irregularities and defects and cracks in beams and wall, pipes or beams.

A cervical spine movement measuring device (100) having a main frame (102) having a plurality of arms (104) for maintaining the head of a person in position and a torsion system adjustably attached to the main frame (102) for positioning the torsion system, with an input shaft (110), relative to the main frame (102) The measuring device (100) can have a main frame (102) with a plurality of arms (104). Each of the plurality of arms (104) can have at least one pad (106). The at least one pad (106) is configured to hold a head of a patient. The input shaft (110) can connect to an isokinetic dynamometer (101) via an interphase connector (108). An isokinetic dynamometer (101) can be configured to measure range of motion and torque of the wearer during an assessment. The device (100) can have an input shaft (110) that is positionable about a plurality of pivot points. The input shaft (110) can be adjustably secured to the main frame. The measuring device (100) allows for assessment and evaluation of cervical spine flexion, extension, right lateral flexion, left lateral flexion, right rotation, and left rotation.

A system and method for electrical stimulation in an orthopedic implant that includes at least one implantable component with an implant body, a plurality of electrodes, and implant circuitry is effective to convert an external wireless power transmission to an electrical current and effective to control the plurality of electrodes; and at least one non-implant with a power source, and transmitter circuitry to generate the electromagnetic field that couples with the implant circuitry.

The present invention is directed to a system for monitoring a physiological parameter of a cyclist, and methods of using the system. The system comprises a garment, a sensor, and a signal processor. The garment is configured to be worn by the cyclist. The sensor is fixedly coupled to the garment and configured to measure a signal representative of the physiological parameter during pedaling. The signal processor is operatively coupled to the sensor and configured to determine a diagnosis based on the measured signal. An alert is generated in response to the diagnosis substantially in real time.

A magnetic resonance imaging apparatus according to an embodiment includes a specifying unit and an acquiring unit. The specifying unit specifies, on a basis of a detection result of target sites of a subject detected from an image on which the target sites are visualized, a first region and a second region which is different from the first region on the image. The acquiring unit acquires data of the second region by using an imaging condition which is different from an imaging condition on an imaging slice and used for acquiring data of the first region.

A method of determining a local cerebrospinal fluid flow rate. The method including the steps of positioning a distal end of the catheter in a flow of cerebrospinal fluid of the patient, the catheter including an infusion port and at least one temperature sensor positioned at a fixed distance from the infusion port, infusing a bolus of a temperature controlled fluid through the infusion port into the flow of cerebrospinal fluid, and monitoring a temperature sensed by the at least one temperature sensor, wherein a change in the temperature sensed by the at least one temperature sensor over time is representative of a local cerebrospinal fluid flow rate in proximity to the infusion port.

Provided are bone quality and/or strength measuring devices. In some embodiments, the devices include a body and a detector disposed therein designed to interact with a bone, determine the quality and/or strength thereof, and communicate an evaluation thereof to a user. The presently disclosed devices can also include a torque and/or force sensor that facilitates placement of the device and/or that is in communication with the detector to cause the detector to evaluate the bone; an output that feedback to a user based on the quality and/or strength of the bone determined by the detector, and/or a piston that interacts with the detector to cause the detector to interact with and thereby evaluate the bone. Also provided are methods for determining if a region of a bone is appropriate for placement of an orthopedic hardware piece and methods for reducing risk of a complication of spinal surgery associated with failure of an orthopedic hardware piece.

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.