Abstract: Flexible apparatus for ablating unhealthy spinal tissue. A housing includes a distal end and a proximal end. Multiple thermocouples mounted on the housing measure spinal tissue temperatures at locations between the proximal end and the distal end. A sensor measures spinal tissue impedance. The measured spinal tissue impedance corresponds to various physical state data of the spinal tissue. The spinal tissue impedance and the spinal tissue temperatures are displayed to the surgeon, enabling the surgeon to determine with certainty the location of the unhealthy spinal tissue, and to exercise control over the ablation apparatus. Nerve stimulation by IMP/STM switch system to detect nerve responses before and after treatment.

Abstract: A training device simulating ablation of a disc space between adjacent vertebral bodies. A heating apparatus includes an upper surface. A lower plate is provided on the upper surface of the heating apparatus. An upper substantially transparent plate is fixed by a frame above the lower plate. The upper plate is etched with an outline of a vertebral body. Fixed in position proximate the lower frame, the upper plate holds a biological material compressed between the plates. Tool-holding clamps, attached to the frame, are positioned to insert a surgical tool, in a proper location and orientation, into the biological material between the upper and lower plates.

Abstract: Flexible apparatus for ablating unhealthy spinal tissue. A housing includes a distal end and a proximal end. Multiple thermocouples mounted on the housing measure spinal tissue temperatures at locations between the proximal end and the distal end. A sensor measures spinal tissue impedance. The measured spinal tissue impedance corresponds to various physical state data of the spinal tissue. The spinal tissue impedance and the spinal tissue temperatures are displayed to the surgeon, enabling the surgeon to determine with certainty the location of the unhealthy spinal tissue, and to exercise control over the ablation apparatus. Nerve stimulation by IMP/STM switch system to detect nerve responses before and after treatment.

Abstract: Flexible apparatus for ablating unhealthy spinal tissue. A housing includes a distal end and a proximal end. Multiple thermocouples mounted on the housing measure spinal tissue temperatures at locations between the proximal end and the distal end. A sensor measures spinal tissue impedance. The measured spinal tissue impedance corresponds to various physical state data of the spinal tissue. The spinal tissue impedance and the spinal tissue temperatures are displayed to the surgeon, enabling the surgeon to determine with certainty the location of the unhealthy spinal tissue, and to exercise control over the ablation apparatus. Nerve stimulation by IMP/STM switch system to detect nerve responses before and after treatment.

Abstract: A training device simulating ablation of a disc space between adjacent vertebral bodies. A heating apparatus includes an upper surface. A lower plate is provided on the upper surface of the heating apparatus. An upper substantially transparent plate is fixed by a frame above the lower plate. The upper plate is etched with an outline of a vertebral body. Fixed in position proximate the lower frame, the upper plate holds a biological material compressed between the plates. Tool-holding clamps, attached to the frame, are positioned to insert a surgical tool, in a proper location and orientation, into the biological material between the upper and lower plates.

Abstract: A training device simulating ablation of a disc space between adjacent vertebral bodies. A heating apparatus includes an upper surface. A lower plate is provided on the upper surface of the heating apparatus. An upper substantially transparent plate is fixed by a frame above the lower plate. The upper plate is etched with an outline of a vertebral body. Fixed in position proximate the lower frame, the upper plate holds a biological material compressed between the plates. Tool-holding clamps, attached to the frame, are positioned to insert a surgical tool, in a proper location and orientation, into the biological material between the upper and lower plates.

Abstract: A training device simulating ablation of a disc space between adjacent vertebral bodies. A heating apparatus includes an upper surface. A lower plate is provided on the upper surface of the heating apparatus. An upper substantially transparent plate is fixed by a frame above the lower plate. The upper plate is etched with an outline of a vertebral body. Fixed in position proximate the lower frame, the upper plate holds a biological material compressed between the plates. Tool-holding clamps, attached to the frame, are positioned to insert a surgical tool, in a proper location and orientation, into the biological material between the upper and lower plates.

Abstract: Flexible apparatus for ablating unhealthy spinal tissue. A housing includes a distal end and a proximal end. Multiple thermocouples mounted on the housing measure spinal tissue temperatures at locations between the proximal end and the distal end. A sensor measures spinal tissue impedance. The measured spinal tissue impedance corresponds to various physical state data of the spinal tissue. The spinal tissue impedance and the spinal tissue temperatures are displayed to the surgeon, enabling the surgeon to determine with certainty the location of the unhealthy spinal tissue, and to exercise control over the ablation apparatus. Nerve stimulation by IMP/STM switch system to detect nerve responses before and after treatment.

Abstract: A method of performing therapy on tissue using a medical apparatus. The apparatus includes a shaft configured for insertion into a hollow anatomical structure (HAS) and has a tissue sensor and a therapeutic energy application device both located on the shaft. The method comprises: receiving electrical power at a first power level and directing the first-level power to the tissue sensor and not to the therapeutic energy application device, thereby enabling tissue sensing with the tissue sensor; receiving electrical power at a second power level higher than the first-level power; and, in response to receipt of the second-level power, directing the second-level power to the therapeutic energy application device, thereby enabling performance of therapy on the tissue with the therapeutic energy application device. Additional methods and apparatus are disclosed as well.

Abstract: An apparatus for treating a hollow anatomical structure can include a light delivery device. The light delivery device comprises an optical fiber that is located in a lumen of a shaft suitable for insertion into the hollow anatomical structure and has a fiber tip located proximal of a distal end of the shaft during treatment of the hollow anatomical structure. The apparatus can further include a liquid source for providing a liquid flow over the optical fiber at a predetermined liquid flow rate.

Abstract: Bodily implants that can be compacted in a distal-to-proximal direction, and which facilitate repositioning of the implant after compaction. The implants include at least one pull string for expanding the implant in a radial direction while compacting the implant in the longitudinal direction. Where multiple pull strings are provided, they can be secured to the implant at spaced locations along the implant length, and pulled successively to compact the implant in a distal-to-proximal direction. A guide member may also be provided to receive the pull strings and facilitate longitudinal compaction.

Abstract: Apparatus for introducing an implant into a hollow anatomical structure (HAS). The apparatus comprises a storage unit and an elongate vascular implant stored inside the storage unit and having a distal end. The apparatus further comprises a pushrod at least partially stored inside the storage unit and having a distal end coupled to the implant, and a pushrod drive unit configured to advance the pushrod distally and thereby deliver the implant. The pushrod drive unit includes a drive member having a grip portion that engages the pushrod, and an actuation portion extending from the grip portion.

Abstract: Bodily implants that can be compacted in a distal-to-proximal direction, and which facilitate repositioning of the implant after compaction. The implants include at least one pull string for expanding the implant in a radial direction while compacting the implant in the longitudinal direction. Where multiple pull strings are provided, they can be secured to the implant at spaced locations along the implant length, and pulled successively to compact the implant in a distal-to-proximal direction. A guide member may also be provided to receive the pull strings and facilitate longitudinal compaction.

Abstract: A method of performing therapy on tissue using a medical apparatus. The apparatus includes a shaft configured for insertion into a hollow anatomical structure (HAS) and has a tissue sensor and a therapeutic energy application device both located on the shaft. The method comprises: receiving electrical power at a first power level and directing the first-level power to the tissue sensor and not to the therapeutic energy application device, thereby enabling tissue sensing with the tissue sensor; receiving electrical power at a second power level higher than the first-level power; and, in response to receipt of the second-level power, directing the second-level power to the therapeutic energy application device, thereby enabling performance of therapy on the tissue with the therapeutic energy application device. Additional methods and apparatus are disclosed as well.

Abstract: An apparatus for treating a hollow anatomical structure can include a light delivery device. The light delivery device comprises an optical fiber that is located in a lumen of a shaft suitable for insertion into the hollow anatomical structure and has a fiber tip located proximal of a distal end of the shaft during treatment of the hollow anatomical structure. The apparatus can further include a liquid source for providing a liquid flow over the optical fiber at a predetermined liquid flow rate.

Abstract: An apparatus for treating a hollow anatomical structure can include a light delivery device. The light delivery device comprises an optical fiber that is located in a lumen of a shaft suitable for insertion into the hollow anatomical structure and has a fiber tip located proximal of a distal end of the shaft during treatment of the hollow anatomical structure. The apparatus can further include a liquid source for providing a liquid flow over the optical fiber at a predetermined liquid flow rate.

Abstract: An occlusion treatment device for the treatment of a body lumen that is at least partially blocked by an occlusion. The occlusion treatment device includes a catheter and a debriding mechanism that is configured and dimensioned for axial movement through the catheter and is extendable beyond a distal end of the catheter. The debriding mechanism includes a head assembly with a debriding tip having an outer surface with at least one aperture formed therein, wherein at least one of the apertures is complemented by a corresponding debriding member that extends outwardly from the outer surface of the debriding tip and directs debris from the occlusion through the at least one aperture to facilitate removal of the debris from the lumen. The debriding mechanism is rotatable to effect debriding of the occlusion.

Abstract: Apparatus for introducing an implant into a hollow anatomical structure (HAS). The apparatus comprises a storage unit and an elongate vascular implant stored inside the storage unit and having a distal end. The apparatus further comprises a pushrod at least partially stored inside the storage unit and having a distal end coupled to the implant, and a pushrod drive unit configured to advance the pushrod distally and thereby deliver the implant. The pushrod drive unit includes a drive member having a grip portion that engages the pushrod, and an actuation portion extending from the grip portion.

Abstract: A method of performing therapy on tissue using a medical apparatus. The apparatus includes a shaft configured for insertion into a hollow anatomical structure (HAS) and has a tissue sensor and a therapeutic energy application device both located on the shaft. The method comprises: receiving electrical power at a first power level and directing the first-level power to the tissue sensor and not to the therapeutic energy application device, thereby enabling tissue sensing with the tissue sensor; receiving electrical power at a second power level higher than the first-level power; and, in response to receipt of the second-level power, directing the second-level power to the therapeutic energy application device, thereby enabling performance of therapy on the tissue with the therapeutic energy application device. Additional methods and apparatus are disclosed as well.

Abstract: A method of performing therapy on tissue using a medical apparatus. The apparatus includes a shaft configured for insertion into a hollow anatomical structure (HAS) and has a tissue sensor and a therapeutic energy application device both located on the shaft. The method comprises: receiving electrical power at a first power level and directing the first-level power to the tissue sensor and not to the therapeutic energy application device, thereby enabling tissue sensing with the tissue sensor; receiving electrical power at a second power level higher than the first-level power; and, in response to receipt of the second-level power, directing the second-level power to the therapeutic energy application device, thereby enabling performance of therapy on the tissue with the therapeutic energy application device. Additional methods and apparatus are disclosed as well.