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.

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.

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.

A system and method for transmitting implant data includes an orthopedic implant, a wireless receiver, and a processing circuit electrically coupled to the wireless receiver. The orthopedic implant is configured to transmit implant identification data and implant sensor data to the wireless receiver in response to a power signal. The orthopedic implant may transfer the data over, for example, a wireless network. The processing circuit receives the implant identification data and the implant sensor data from the wireless receiver and is configured to retrieve patient-related data from a database based on the implant identification data. The processing circuit may also be configured to update a patient queue, assign a patient room to a patient, and/or transmit the patient-related data and the implant sensor data to a client machine located in the patient room.

A surgical apparatus configured to be placed in the musculoskeletal system to precisely separate a first bone from a second bone. The surgical apparatus has one or more sensors to measure one or more parameters and supports one or more bone cuts for installing a prosthetic component. The surgical apparatus has three distraction mechanisms configured to increase or decrease a height between a first support structure and a second support structure. The tilt mechanism adjusts the tilt between the first support structure relative to the second support structure. The tilt mechanism of the surgical apparatus is adjusted from a first tilt to a second tilt to support a bone cut on one of the first or second bones.

A multi-piece implantable joint prosthesis includes an adapter to which at least two pieces are coupled, where the adapter has a coupler for coupling to a first piece and a different coupler for coupling to a second piece, where at least one piece, e.g., the first piece, may contain an electronic component such as a sensor that detects and measures movement of the prosthesis when the prosthesis is implanted in a patient, and can thus monitor the kinematic movement of the patient in real life situations, where the electronic component may also include a memory to store the data obtained by the sensor, and a communication interface to transmit the data to an external location where it may be analyzed, and a power source to provide power to the sensor, memory and communication interface.

Hip replacement prosthesis are provided, comprising a femoral stem, a femoral head coupled to the femoral stem, and an acetabular assembly coupled to the femoral head, and a plurality of sensors coupled to at least of the femoral stem, femoral head, and acetabular assembly.

Improvements in a dental/prosthetic implant is disclosed. The implant includes interior and exterior threaded surfaces. The use of both interior and exterior expanding threaded surfaces for integrations of the insert and a prosthetic with the same implant. The implant is immediately usable under load and promotes rapid integration with bone growth. The expanded insert essentially makes contact with the tapped bone surfaces where loads can be immediately applied so a person can utilize the prosthetic implant. The implant can further include security devices GPS, ID with medical records making removal of the implant difficult to extract. A cushioning member may be further integrated. The implant/abutment can include a surface with a plurality of contacts with sufficient gold contact points to attach residual nerve endings, during implanting surgery to provide nerve identification, send, receive, target so as to exploit proprioceptive memory or retraining.

A device for monitoring a medical prosthesis and the human body includes a sensor for generating signals depending on surrounding stresses, a processor for processing the signals emitted by the sensor in order to convert the signals into data, a storage device for storing the data, a device for wireless transmission of the stored data, and a supply of electrical energy. The device is included in at least one casing, which is made of biocompatible material and has a device for fixing to a bone.

Implantable in vivo sensors used to monitor physical, chemical or electrical parameters within a body. The in vivo sensors are integral with an implantable medical device and are responsive to externally or internally applied energy. Upon application of energy, the sensors undergo a phase change in at least part of the material of the device which is then detected external to the body by conventional techniques such as radiography, ultrasound imaging, magnetic resonance imaging, radio frequency imaging or the like. The in vivo sensors of the present invention may be employed to provide volumetric measurements, flow rate measurements, pressure measurements, electrical measurements, biochemical measurements, temperature, measurements, or measure the degree and type of deposits within the lumen of an endoluminal implant, such as a stent or other type of endoluminal conduit. The in vivo sensors may also be used therapeutically to modulate mechanical and/or physical properties of the endoluminal implant in response to the sensed or monitored parameter.