A dynamic splint for use with a user's hand, including a hand support section, at least one strut including a base portion disposed adjacent the hand support section and a body portion extending outwardly therefrom to a distal end, the body portion defining at least one recess, and at least one tensioner including a proximal end, a distal end configured to be secured to a digit of the user's hand, an elongated body extending therebetween, and at least one node disposed on the elongated body, wherein the at least one node is selectively received in the at least one recess in a press-fit, and the elongated body of the at least one tensioner has flexural strength to resist bending of the digit.

A cervical traction device is provided. A frame presents an anterior support under the maxilla of a user, while a posterior support is applied to the lower portion of the occiput of the user. Thus, pressure is avoided on the potentially unstable mandible, and the lower and upper teeth are not compressed against one another. A series of suspension points on the frame allows the angle at which traction may be applied to the cervical vertebrae to be varied.

A cervical traction device is provided. A frame presents an anterior support under the maxilla of a user, while a posterior support is applied to the lower portion of the occiput of the user. Thus, pressure is avoided on the potentially unstable mandible, and the lower and upper teeth are not compressed against one another. A series of suspension points on the frame allows the angle at which traction may be applied to the cervical vertebrae to be varied.

The present invention is generally directed to corrective spinal traction systems and methods. It is further directed to use of such spinal traction systems to treat various medical problems associated with abnormal spinal curvature. In one aspect, the present invention is directed to a spine corrective traction system. The system comprises an overhead system allowing a patient's spine to be pulled in every and any vector the human spine moves in three dimensional space, and in two to three planes simultaneously. It further includes a seat assembly that allows for a patient to be seated upright, supine and every angle and vector between 90 degrees upright and 0 degrees horizontal.

The present invention is generally directed to corrective spinal traction systems and methods. It is further directed to use of such spinal traction systems to treat various medical problems associated with abnormal spinal curvature. In one aspect, the present invention is directed to a spine corrective traction system. The system comprises an overhead system allowing a patient's spine to be pulled in every and any vector the human spine moves in three dimensional space, and in two to three planes simultaneously. It further includes a seat assembly that allows for a patient to be seated upright, supine and every angle and vector between 90 degrees upright and 0 degrees horizontal.

A system for dynamically adjusting treatment angle under tension to accommodate variations in spinal morphology during spinal decompression therapy is provided. It provides a tensioning device including a patient-positioning means, a tension-producing actuator, a positioning device, a patient interface device, a control system and a display. The control system with feedback on the resultant tension vector applied to patient spine operationally configured to allow for adjustment of either tension producing actuator position, patient position, or both while applying tension to the patient spine during non-therapeutic tension levels. The control system automatically adjusts tension producing actuator work levels such that the resultant tension vector magnitude remains ideally constant during adjustment of resultant tension vector angle, reducing the risk of eliciting paraspinal muscle contraction due to changes in resultant tension vector magnitude.

A system for dynamically adjusting treatment angle under tension to accommodate variations in spinal morphology during spinal decompression therapy is provided. It provides a tensioning device including a patient-positioning means, a tension-producing actuator, a positioning device, a patient interface device, a control system and a display. The control system with feedback on the resultant tension vector applied to patient spine operationally configured to allow for adjustment of either tension producing actuator position, patient position, or both while applying tension to the patient spine during non-therapeutic tension levels. The control system automatically adjusts tension producing actuator work levels such that the resultant tension vector magnitude remains ideally constant during adjustment of resultant tension vector angle, reducing the risk of eliciting paraspinal muscle contraction due to changes in resultant tension vector magnitude.

A forearm and wrist fracture table includes base members, vertical bars, horizontal bars, an elbow support member and a hand support member. The vertical bars includes a first vertical bar and a second vertical bar attached to the support base members. The horizontal bars are attached between the support base members and vertical bars to provide horizontal stability and length adjustment between the support base members and the vertical bars. The elbow support member is attached to the first vertical bar to provide support for the elbow. The hand support member is attached to the second vertical bar to receive and support a hand extending from the elbow, wherein the fractured arm is supported between the elbow support member and the hand support member, wherein a surgeon is allowed to modulate an amount of needing pressure required to distract fracture fragments, and thereby reducing fracture and healing the fracture site.

A forearm and wrist fracture table includes base members, vertical bars, horizontal bars, an elbow support member and a hand support member. The vertical bars includes a first vertical bar and a second vertical bar attached to the support base members. The horizontal bars are attached between the support base members and vertical bars to provide horizontal stability and length adjustment between the support base members and the vertical bars. The elbow support member is attached to the first vertical bar to provide support for the elbow. The hand support member is attached to the second vertical bar to receive and support a hand extending from the elbow, wherein the fractured arm is supported between the elbow support member and the hand support member, wherein a surgeon is allowed to modulate an amount of needing pressure required to distract fracture fragments, and thereby reducing fracture and healing the fracture site.

A spine-protecting and spine-correcting multi-functional health-care seat device employing gravity to achieve embrace-like support, pressure reduction, fixing, and correction, including a seat frame and a gravity embrace-like support and sitting device. The gravity embrace-like support and sitting device includes a sitting plate (1), sitting plate support rods (8) symmetrically arranged on two sides of a bottom of the sitting plate (1), rotating bearings (1101) symmetrically arranged on two sides of the seat frame, embrace-like support levers cooperatively arranged on the rotating bearings (1101), and embrace-like support palms (2) arranged at top ends of the embrace-like support levers. One end of each sitting plate support rod (8) is hinged to a bottom of the sitting plate (1), and the other end is hinged to a bottom of each embrace-like support lever through a support rod rotating shaft (15).