In one embodiment, a suture anchor installation system for orthopedic surgery is disclosed including a reusable or disposable handle, and one or more reusable or disposable screw-on tool nosepieces for orthopedic surgery that are configured to be coupled to the handle. The one or more reusable or disposable screw-on tool nosepieces include an awl, a tap, a suture anchor install tool, and a suture anchor adjustment tool for orthopedic surgery. The nosepieces may alternatively press-on or snap-on with a barb/groove configuration or rectangular driver/ball/socket universal joint configuration with an engineering fit such as a running, sliding, or slip fit, a locational or transition fit, a force fit, a friction fit, or an interference fit.

Described are a multipurpose handles that can be incorporated into medical device delivery systems. Also described are medical devices, including medical snare devices, that can incorporate the handles or features thereof. An actuation button of the multipurpose handle can be moved longitudinally to move a device portion (e.g. snare loop) longitudinally, e.g. for deployment or retraction. The actuation button can also be rotated to rotate a device portion (e.g. snare loop). Sealing arrangements can be provided and can provide sealing functions in respect of a controlled medical device structure while the actuation button is moved longitudinally or rotated. Methods of using the handles and medical snare or other devices incorporating them are also described.

A surgical instrument assembly includes a surgical instrument having an instrument body, an elongate member with a distal end configured to be inserted into an anatomical passageway of a patient, a sensor operable to generate a signal corresponding to a location of the elongate member, and a first electrical connector electrically coupled with the sensor. The assembly further includes a cable assembly having a cable that communicates with a processor, and a coupling that releasably couples with the instrument body. The coupling includes a coupling body having first and second lateral sides that extend parallel to one another and are configured to extend parallel to a side of the instrument body when the coupling is coupled with the instrument body. The coupling includes a second electrical connector that electrically couples with the first electrical connector to transmit the signal from the sensor proximally through the cable and toward the processor.

A sacroiliac joint screw has a screw body having a head and a treaded shank with a self-drilling cutting tip. The screw body is cannulated and configured to receive a Steinmann pin for the purpose of a minimally invasive approach (MIS) for delivery to the sacroiliac joint (SI) while minimizing soft tissue damage. The self-drilling cutting tip creates a pilot hole. The threaded shank has a plurality of spiral cutting flutes, the spiral cutting flutes extend along a length of the threaded shank and are configured to provide a constant self-tapping feature. A plurality of bone harvesting windows are positioned in the spiral cutting flutes and are configured to pull in bone as the screw is advanced into the joint.

A medical device system may include a sheath, a pusher wire, and a locking element. The sheath may have a first outer diameter adjacent to the proximal end and an enlarged outer diameter region having a second outer diameter greater than the first adjacent to the intermediate region. The pusher wire may be slidably disposed within a lumen of the sheath. The locking element may have a lumen extending therethrough. The locking element may have a first inner diameter adjacent to the distal end and a second inner diameter smaller than the first adjacent to the intermediate region. The locking element may configured to freely slide over a region of the sheath having the first diameter. When the locking element is disposed over the enlarged outer diameter region of the sheath having the second outer diameter, the locking element may be configured to depress the sheath radially inwards.

Disclosed herein are insertion and extraction instruments for orthopaedic procedures that are used for inserting and extracting trials and implants. The instruments include a body extending along a central axis having first and second arms extending from the body along first and second axes. The first and second arms may be moveable with the distal ends of the arms being configured to engage first and second engagement feature of a trial or an implant. The first and second axes define an angle therebetween such that when the distal end of the first arm is received in a first engagement feature of the implant and the distal end of the second arm is in the second engagement feature, the distal ends of the arms are urged against respective first and second side walls of the first and second arms to secure the instrument to the trial or implant.

A retractor for retracting tissue and suctioning fluids, having a handle and a blade and a fluid passage therethrough connecting to a suction source, the fluid passage directing suction to perforations in the blade through which undesirable fluids, including surgical plume, may be evacuated. The retractor may be, in whole or part, transparent to observe suctioning. The blade may include a fanned tip for wide tissue-engagement. One or more perforations in the fanned tip may create a wide field of suction. Other perforations in the blade may present suction at differing elevations with respect to the surgical field. The handle may include one or more thumb/finger depressions for improved grip and maneuverability. The handle may include knurling ridges to reduce slippage. When not in use for retraction, the retractor may be clipped to another retractor where it may still suction fluids without being held.

A drive-enhanceable handheld advancer is provided for advancing an elongate device through a pathway defined in an advancer body that includes a rotatable manual thumbwheel partially embedded in the body for receiving a user-exerted manual control movement from a thumb, and a manual drive having a nip, a transmission, and a reverse clutch. The transmission operatively connects the thumbwheel to the nip for driving advancement, and the reverse clutch maintains a first interference grip connection between the nip and the elongate device. The manual control thumbwheel can move inward responsive to user-applied grip movements to increase grip with the elongate device. The reverse clutch applies augmented force from grip movements to the nip for increasing the grip drive connection, which can be applied at a different angle from the inward movements. The reverse clutch can include slotted pivot supports for the thumbwheel and drive rollers on the advancer body.

A three-dimensional (3-D) orthopedic drill guide device for accommodating a bone drill during an orthopedic surgery is disclosed. By establishing two specific angles in relation to the bone fascia, the device acts as a guide for bone drilling locations. In one specific instance, it is an optimal 3-D drill guide for the direction and Gamma angle (resulting from the devices Alpha and Beta angles of the device) of a drill hole in a femoral bone when used to replace an injured anterior cruciate ligament (ACL).

Drill guides and related methods are disclosed herein, e.g., for use in surgical procedures. In some embodiments, a drill guide can include an adjustment mechanism that permits one-handed adjustment of the guide depth and does not require that the drill guide be removed from the patient or that the drill be removed from the drill guide when making an adjustment. The adjustment mechanism can include a trigger that moves first and second detents into and out of engagement with a guide stem to allow step-wise adjustment of the guide depth.