A system and method for embedded electronics within a medical implant comprising: an implant body; a circuitry surface, containing at least one electronic component, wherein the circuitry surface is at least partially embedded within a defined cavity of the implant along at least one path; sheathing, comprising a protective structure, wherein the at least partially embedded portion of the circuitry surface is enclosed within the sheathing; electronic components connected to, or directly on, the circuitry surface, comprising a set of electrodes and an antenna; and wiring, connecting the circuitry surface and electronic components. The system and method may further include a casing, wherein the casing is a sealed structure directly connected to the implant body including a printed a circuit board (PCB) contained within the casing itself.

An orthopedic system configured for use in a pre-operative, intra-operative, and post-operative assessment. The orthopedic system comprises a first screw, a second screw, a first device, a second device, and a computer. The first device and the second device are respectively coupled to a first bone and a second bone of a musculoskeletal system. The first and second devices each include electronic circuitry, one or more sensors, and an IMU. A bracket, wrap, or sleeve can be used to hold the first and second devices to the musculoskeletal system. The first and second devices are configured to send measurement data to a computer. The first and second devices each have an antenna system. Electronic circuitry in the first or second devices are configured to harvest energy from a received radio frequency signal to recharge a battery to maintain operation.

Laser-based implant guide systems and methods that align an implant with an axis of an anatomical structure of interest are disclosed. The systems include a target base configured to couple to a patient in alignment with the axis, and a target member configured to couple to the target base that includes a visual indication of the location of the axis. The systems further include an implant guide that includes a laser device and a resection guide. The implant guide is configured to adjust at least one of the position and the orientation of the laser device with respect to the anatomical structure of interest such that a laser line projecting from the laser device is aligned with the visual indication of the target member, and the resection guide facilities implantation of the implant in a resected portion of the anatomical structure of interest in alignment with the axis.

A method and system for monitoring analytes in the circulatory system of an individual is provided. A biological sensor is implanted in the bone marrow of a patient and may be self contained within a housing. The biological sensor measures physiological parameters of a patient, including analytes, on a fixed or adjustable schedule. The biological sensor includes a control unit having a transmitter and an energy source for providing energy to the control unit. The biological sensor may be used to adjust other medical treatments and devices in a closed or semi closed loop mechanism and/or predict patient treatment.

The invention is a system and a handheld device for use in open or minimally invasive surgical procedures, such as a bone implant fixation procedure. The handheld device is configured to perform various functions during a bone implant fixation procedure, including performing at least one of: penetration of a bone to form a hole or opening for receipt of a screw; neuromonitoring, in cooperation with a neuromonitoring device, of the hole during, or post-, formation of the hole so as to sense any nearby nerves adjacent to the hole that may be in the path of a screw, or otherwise affected, when a screw is placed within the hole; neurostimulation, in cooperation with a neuromonitoring device, of nerves adjacent to the hole during, or post-, formation of the hole; and measuring of a depth of the hole and providing a digital measurement of the depth to assist the surgeon in selecting the appropriate length of screw.

A system for monitoring a patient includes a sensor unit having a housing and sensors disposed in or around the housing; and a base having a shell and configured and arranged to be adhesively attached to skin of the patient. The sensors can be used to monitor physical therapy and rehabilitation of the patient. The sensor unit can provide information to a patient or clinician device to facilitate the monitoring. The sensor data can be used to determine measurements such as tilt angle of the sensor unit and range of motion measurements (such as extension, flexion, or forces associated with movement) of the anatomical region to which the sensor unit is attached. The sensor data can also be used for automated identification or classification of exercises performed by the patient.

An energy transfer system includes a spinal implant having an antenna, an antenna extender attached to a portion of the spinal implant in proximity to the antenna, and a reader device configured to send energy to the spinal implant via the antenna extender. The antenna extender extends away from the spinal implant. The spinal implant is configured to be positioned within a spinal area of a patient.

An energy transfer system includes a spinal implant having one or more antennae, and the spinal implant is configured to be positioned within a spinal area of a patient, and a relay device configured to be positioned within the patient between the implant and the skin of the patient when implanted. The relay device is configured to receive energy from a reader device located externally to the patient and convey at least a portion of the received energy to the one or more antennae of the spinal implant.

An implantable sensor configured to be inserted in an intramedullary canal can include a primary insert, a secondary insert, and an antenna. The primary insert can include a distal end, a proximal end opposite the distal end, and a central bore that can extend from an opening in the distal end towards the proximal end. A secondary insert can be receivable within the central bore through the opening. The secondary insert can include a body and a sensor module. The body can be removably engageable with an inside surface of the central bore. The sensor module can be disposable within the body and can be configured to produce a sensor signal as a function of a first sensed parameter indicative of infection. The antenna can be disposed in the central bore. The antenna can be configured to transmit a wireless signal as a function of the sensor signal.

An orthopedic system to monitor a parameter related to the muscular-skeletal system is disclosed. The orthopedic system includes electronic circuitry, at least one sensor, and a computer to receive measurement data in real-time. The orthopedic system comprises a first plurality of shims of a first type, a second plurality of a second type, a measurement module, and the computer. The measurement module houses the electronic circuitry and at least one sensor. The measurement module is adapted to be used with the first plurality of shims and the second plurality of shims. The measurement module has a medial surface that differs from a lateral surface by shape, size, or contour.