Abstract: Devices and methods configured to determine characteristics of tissue specimens are provided. Representative tissue analysis devices include a sensing module and a reference module. The sensing module includes a first post and a second post configured to have the tissue specimen affixed thereto, and a displacement sensor configured to output a displacement signal corresponding to a displacement of the first post. The reference module includes a reference sensor configured to output a reference signal corresponding to a reference input such as an ambient magnetic field. The devices further include instructions that determine: a displacement value based upon the displacement signal; a reference value based upon the reference signal; a reference-canceled displacement value based upon the displacement value and the reference value; and a characteristic of the tissue specimen based upon the reference-canceled displacement value.

Abstract: Systems and methods disclosed stimulate nerve growth by applying a tensile (axial pulling) load on a proximal stump of the nerve. This load may be imposed once, at the time of repair. This implementation may be advantageously employed to remove tension away from the repair site, for any number of soft tissues, e.g., nerves, ligaments, tendons, and so on. Alternately, for a larger gap, by progressively elongating a nerve through tensile stimulation, the nerve may regenerate and be fully functional, particularly if elongated at a proper rate. After sufficient regrowth, nerve ends may be reattached, resulting in more complete functional recovery. Two implementations, which have been embodied in prototype devices, also include particularly useful features, one of which uses a screw and clamp with slotted insert design, and the other of which enables the use of sutures or straps to secure the tissue to the clamp.

Abstract: Systems and methods disclosed stimulate nerve growth by applying a tensile (axial pulling) load on a proximal stump of the nerve. This load may be imposed once, at the time of repair. This implementation may be advantageously employed to remove tension away from the repair site, for any number of soft tissues, e.g., nerves, ligaments, tendons, and so on. Alternately, for a larger gap, by progressively elongating a nerve through tensile stimulation, the nerve may regenerate and be fully functional, particularly if elongated at a proper rate. After sufficient regrowth, nerve ends may be reattached, resulting in more complete functional recovery. Two implementations, which have been embodied in prototype devices, also include particularly useful features, one of which uses a screw and clamp with slotted insert design, and the other of which enables the use of sutures or straps to secure the tissue to the clamp.