Example traction devices, systems and methods for use thereof are provided. An example traction device may include (a) a frame comprising a top support having first and second ends, where the first end of the top support is coupled to a first vertical support and the second end of the top support is coupled to a second vertical support and (b) a balance bar moveably coupled to the top support via a wire, where opposing ends of the balance bar are each coupled to an attachment ring or define a receptacle.

A patient support apparatus includes a surgical table and a limb support unit coupled to the surgical table. The limb support unit includes a support platform coupled to the surgical table in a fixed position, a first limb holder coupled to the support platform in a fixed position relative to the support platform, and a second limb holder coupled to the support platform and spaced apart from the first limb holder. The first limb holder includes a multi-axis joint coupled to the support platform in a fixed position and a spar coupled to the multi-axis joint to move relative to the support platform while supporting a patient's limb that has been coupled to the spar.

A patient support apparatus includes a surgical table and a limb support unit coupled to the surgical table. The limb support unit includes a support platform coupled to the surgical table in a fixed position, a first limb holder coupled to the support platform in a fixed position relative to the support platform, and a second limb holder coupled to the support platform and spaced apart from the first limb holder. The first limb holder includes a multi-axis joint coupled to the support platform in a fixed position and a spar coupled to the multi-axis joint to move relative to the support platform while supporting a patient's limb that has been coupled to the spar.

The present disclosure relates to software used in planning the correction of bone deformities preoperatively or postoperatively, and in particular relates to virtually manipulating rings and struts of an external fixation frame in order to plan the steps for making a desired correction to two or more bone portions of a patient. The software can be used prior to surgery, allowing a user to virtually define a bone deformity, and virtually add and manipulate fixation rings and struts to the bone deformity. Based on the virtual manipulations, a correction plan can be generated that describes length adjustments that should be made to the plurality of model struts over a period of time to correct the bone deformity. The software can also be used after surgical fixation of the fixation frame and struts to the deformed bone.

Apparatus for distracting the hip joint of a patient, said apparatus comprising:

a perineal post for engagement with a leg of the patient, said perineal post comprising a first portion and a second portion, wherein said first portion is configured for mounting to a table, and further wherein said second portion is movable relative to said first portion so as to change the geometry of the perineal post relative to a patient supported on the table.

Apparatus for distracting the hip joint of a patient, said apparatus comprising:

a perineal post for engagement with a leg of the patient, said perineal post comprising a first portion and a second portion, wherein said first portion is configured for mounting to a table, and further wherein said second portion is movable relative to said first portion so as to change the geometry of the perineal post relative to a patient supported on the table.

A surgical assembly (20) comprises a post (100) having a longitudinally extending axis (104), a support (56) for resisting movement of the post in a negative longitudinal direction, and a platform (70) offset from the support in a positive longitudinal direction. The platform includes an opening (82) through which the post projects. The opening includes a throat (86). The post has a first dimension which renders the post incapable of passing through the throat and a second dimension which renders the post capable of passing through the throat. Alternate embodiments in which the post can be removably engaged with the support and platform and disengaged therefrom without translating the post in the longitudinal direction are also disclosed.

A surgical assembly (20) comprises a post (100) having a longitudinally extending axis (104), a support (56) for resisting movement of the post in a negative longitudinal direction, and a platform (70) offset from the support in a positive longitudinal direction. The platform includes an opening (82) through which the post projects. The opening includes a throat (86). The post has a first dimension which renders the post incapable of passing through the throat and a second dimension which renders the post capable of passing through the throat. Alternate embodiments in which the post can be removably engaged with the support and platform and disengaged therefrom without translating the post in the longitudinal direction are also disclosed.

A fixation clamp for use in an external fixation system for holding bone fragments adjacent to each other with the help of fixation elements has at least one clamping assembly having a pair of jaws with at least two different size grooves to accommodate a bone fixation element such as a pin or rod. An alternate clamping assembly has at least three grooves wherein at least two of the grooves have a different size adapted to accommodate a correspondingly sized bone fixation element such as a bone pin. The longitudinal axes of the grooves define a polygon. The jaw pairs can be rotated about a central longitudinal axis to present different size reception cavities towards the pins or rocks depending on their diameter.

Rate-dependent, elastically-deformable devices according to various embodiments can be stretched and recovered at low elongation rates. Yet they become stiff and resistive to stretching at high elongation rates. These device can be utilized in orthotics, braces, and circulation-enhancing compression garments for the prevention of injury, promotion of personal health, and/or enhancement in human performance. The rate-responsive properties of the devices are critical performance enablers, as they allow the devices to provide a unique balance of comfort and performance that cannot be achieved with conventional, passive straps, braces, and compression garments.