An automated and/or motorized spatial frame including a control unit and a plurality of motorized struts is disclosed. The control unit being configured as a controller for exchanging data with an external computing system, exchanging data with the plurality of motorized struts, and delivering power to the motorized struts. Thus arranged, the control unit may be configured as a fully integrated power supply and controller for powering and controlling the motorized struts. In some embodiments, the control unit includes a plurality of PCB modules, each positioned within the spaces or pockets formed between adjacent tabs on a ring of the frame. The PCB modules being detachably coupled to the ring. In some embodiments, the PCB modules may be detachably coupled to the ring via interconnecting male and female connectors. Alternatively, the PCB modules may be detachably coupled to the ring via a plurality of brackets.

An automated and/or motorized spatial frame including a control unit and a plurality of motorized struts is disclosed. The control unit being configured as a controller for exchanging data with an external computing system, exchanging data with the plurality of motorized struts, and delivering power to the motorized struts. Thus arranged, the control unit may be configured as a fully integrated power supply and controller for powering and controlling the motorized struts. In some embodiments, the control unit includes a plurality of PCB modules, each positioned within the spaces or pockets formed between adjacent tabs on a ring of the frame. The PCB modules being detachably coupled to the ring. In some embodiments, the PCB modules may be detachably coupled to the ring via interconnecting male and female connectors. Alternatively, the PCB modules may be detachably coupled to the ring via a plurality of brackets.

A kit of tarsometatarsal joint arthrodesis tools include a metatarsal multi-tool, a first ray multi-tool, a cuneiform cut guide, and a joint compressor-distractor. The metatarsal multi-tool is configured for securement to a first metatarsal establishing an anatomic reference for carrying out a surgical procedure and guiding a surgeon to perform the metatarsal base cut. The first ray multi-tool is configured for securement to the first metatarsal using a fixation method. The first ray multi-tool is also configured to be secured to the medial cuneiform. The cuneiform cut guide is configured for removable attachment to the first ray multi-tool and is configured to guide the surgeon to perform the cuneiform head cut. The compressor-distractor is configured to apply a force to the first ray multi-tool such that the position of the first metatarsal may be adjusted toward or away from the medial cuneiform.

Traction apparatuses can be used to facilitate spinal surgery. For example, this document provides traction apparatuses that engage with the skull of a patient, traction apparatuses that engage with the pelvis of a patient, and cervical traction systems for use in conjunction with the skull and/or pelvis traction apparatuses to facilitate correction of occipito-cervical-thoracic deformities, and to safely position the head during spinal surgery. Additionally, this document provides thoraco-lumbar-pelvic spinal deformity correction apparatuses to manipulate the position of the pelvis in relation to the spine during surgery.

Traction apparatuses can be used to facilitate spinal surgery. For example, this document provides traction apparatuses that engage with the skull of a patient, traction apparatuses that engage with the pelvis of a patient, and cervical traction systems for use in conjunction with the skull and/or pelvis traction apparatuses to facilitate correction of occipito-cervical-thoracic deformities, and to safely position the head during spinal surgery. Additionally, this document provides thoraco-lumbar-pelvic spinal deformity correction apparatuses to manipulate the position of the pelvis in relation to the spine during surgery.

An adjustment compliance device and systems and methods for use with an external fixator are disclosed. The adjustment compliance device can be attached to a strut of an external fixator and may include at least one indicator element to indicate adjustment parameters for an active step of an adjustment process for the external fixator. The adjustment parameters may include an active strut and/or a direction of adjustment for the strut. The adjustment compliance device may receive the adjustment parameters from a user device. The at least one indicator element may include a light element operative to emit light in a color corresponding to the active strut. The at least one indicator element may include a light element configured to indicate a direction of rotation of the active strut. As a result, a patient can more effectively comply with an adjustment prescription, thereby improving the likelihood of successful bone alignment.

An adjustment compliance device and systems and methods for use with an external fixator are disclosed. The adjustment compliance device can be attached to a strut of an external fixator and may include at least one indicator element to indicate adjustment parameters for an active step of an adjustment process for the external fixator. The adjustment parameters may include an active strut and/or a direction of adjustment for the strut. The adjustment compliance device may receive the adjustment parameters from a user device. The at least one indicator element may include a light element operative to emit light in a color corresponding to the active strut. The at least one indicator element may include a light element configured to indicate a direction of rotation of the active strut. As a result, a patient can more effectively comply with an adjustment prescription, thereby improving the likelihood of successful bone alignment.

Devices and methods for treating bone fractures involving a micromotional unit (6) that produces reciprocating displacement between two fracture fragments (1) to thereby apply controllable micromotion to a fracture site.

Devices and methods for treating bone fractures involving a micromotional unit (6) that produces reciprocating displacement between two fracture fragments (1) to thereby apply controllable micromotion to a fracture site.

Logic may determine how to reduce bone segments. Logic may communicate one or more images to display with at least two bone segments. Logic may identify a first reduction point and a third point on a first bone segment and identify a second reduction point and a fourth point on the second bone segment. Logic may identify a fifth point on the first bone segment and a sixth point on the second bone segment. Logic may also divide the one or more images along a line or plane between the bone segments, bring the second reduction point and the associated image segment to the first reduction point, align the line or plane of the second bone segment with a line or plane of the first bone segment. Furthermore, logic may adjust alignment and record the movement of the image segments or compare original and final positions, to determine deformity parameters.