A force-limiting and damping device has a body, a tapping element, a shock-absorbing element, and a limiting module. The body has a connecting segment and a holding segment. The tapping element is connected to the body to move relative to the connecting segment and has a mounting segment, a tapping segment, and a fixing segment. The mounting segment is movably connected to the connecting segment. The tapping segment is disposed on an end of the mounting segment below the connecting segment. The fixing segment is connected to the mounting segment and abuts the connecting segment. The shock-absorbing element is mounted on the mounting segment and abuts the connecting segment and the tapping segment. The limiting module is mounted between the body and the tapping element and has a force-limiting element mounted between the mounting segment and the connecting segment to provide a force-limiting reminder effect and a damping effect.

Disclosed herein are bi-spring surgical impact tools and methods of use thereof. The bi-spring surgical impact tools can include a housing, a shuttle, a pinion, and first and second springs. The housing can define a cavity having a first end and a second end. The shuttle can be located within the cavity and define a plurality of indentations. The pinion can be located proximate the shuttle and have a plurality of protrusions sized to mesh with the plurality of indentations during rotation of the pinion. The first and second springs can be mechanically coupled to the housing and the shuttle. Rotation of the pinion in a first direction can translate the shuttle in a first direction towards the first end of the housing and rotation of the pinion in a second direction can translate the shuttle in a second direction towards the second end of the housing.

Disclosed herein are orthopedic impact tools and methods of use thereof. The orthopedic impact tools can include a housing, a tube assembly, a reverse impact plate, an anvil and an impact mechanism. The housing can include a hand grip portion and an impact mechanism housing portion. The tube assembly can include a first tube portion and a second tube portion. The reverse impact plate can be disposed in between the first tube portion and the second tube portion. The anvil can include a forward impact surface. The impact mechanism can include a motor, a piston, a ram, and a rotary to linear conversion mechanism drivingly connecting the motor to the piston. The piston can be disposed within the first tube portion and the ram can be disposed in the second tube portion and movable into contact between the reverse impact plate and the forward impact surface.

A toggle-type suture anchor that incorporates individual suture tensioning and locking without knot tying. The anchor includes an elongate toggle body having a working suture pre-threaded into a first passage and back up and out a second passage with a length running longitudinally adjacent the side of the anchor. A locking suture loop is pre-threaded into a third passage between the first and second passage and includes a collapsible loop that encircles a portion of the length of suture running longitudinally adjacent the side of the anchor. With the loop open, the working suture can slide through the anchor, however, when the loop is closed the working suture is locked in position to retain tension on the working suture. The anchor can be utilized in a pre-strung connected array of anchors.

A toggle-type suture anchor for transtendinous implantation in bone to secure soft tissue thereto during repair of a tear, especially a rotator cuff repair. The anchor can include an elongate body with side surfaces defining a maximum diameter of the body. The body can also include proximal, middle and distal bores extending from the top surface to the bottom surface, each bore located at spaced intervals along the elongate body with a single suture passing into the proximal bore top surface and out the bottom surface, then back up through the distal bore bottom surface out the top surface leaving a length of suture extending past the middle bore bottom surface. To assure toggling in transtendinous delivery into bone, the elongate body can include a pair of fins extending both proximally and radially outward from the elongate body to prevent back out once placed in a bone hole.

A hand-held spring-driven impact device (e.g., spring tool) configured with removable and replaceable tips. The spring tool may include a helical spring that is coupled to a first anvil at one end and a second anvil at the other end. The spring tool may include a locking mechanism on the first anvil and/or the second anvil. The locking mechanism may be configured to securely fasten a tip to the spring tool. The tip may include a single-sided tip or a double-sided tip. The spring tool may include an ergonomically curved gripping surface and/or a friction component to assist in holding the spring tool. In some examples, the spring tool may include a ball bearing situated between the first anvil and the second anvil to transfer impact force when applied at an angle. Additionally, the spring tool may include a cover to protect the spring during use.

A motor-driven orthopedic impacting tool is provided for orthopedic impacting in the hips, knees, shoulders and the like. The tool is capable of holding a broach, chisel, or other end effector, which when gently tapped in a cavity with controlled percussive impacts, can expand the size or volume of an opening of the cavity or facilitate removal of the broach, implant, or other surgical implement from the opening. A stored-energy drive mechanism stores potential energy and then releases it to launch a launched mass or striker to communicate a striking force to an adapter in either a forward or reverse direction. The tool may further include a combination anvil and adapter and an energy adjustment mechanism to adjust the striking force the launched mass delivers to the adapter in accordance with a patient profile.

A toggle-type suture anchor that incorporates individual suture tensioning and locking without knot tying. The anchor includes an elongate toggle body having a working suture pre-threaded into a first passage and back up and out a second passage with a length running longitudinally adjacent the side of the anchor. A locking suture loop is pre-threaded into a third passage between the first and second passage and includes a collapsible loop that encircles a portion of the length of suture running longitudinally adjacent the side of the anchor. With the loop open, the working suture can slide through the anchor, however, when the loop is closed the working suture is locked in position to retain tension on the working suture. The anchor can be utilized in a pre-strung connected array of anchors.

A toggle-type suture anchor for transtendinous implantation in bone to secure soft tissue thereto during repair of a tear, especially a rotator cuff repair. The anchor can include an elongate body with side surfaces defining a maximum diameter of the body. The body can also include proximal, middle and distal bores extending from the top surface to the bottom surface, each bore located at spaced intervals along the elongate body with a single suture passing into the proximal bore top surface and out the bottom surface, then back up through the distal bore bottom surface out the top surface leaving a length of suture extending past the middle bore bottom surface. To assure toggling in transtendinous delivery into bone, the elongate body can include a pair of fins extending both proximally and radially outward from the elongate body to prevent back out once placed in a bone hole.

A force-limiting and damping device has a body, a tapping element, and an elastic element. The body has a connecting segment and a holding segment. The connecting segment is formed on an end of the body and has a mounting hole. The holding segment is formed on the body opposite the connecting segment. The tapping element is connected to the body to move relative to the connecting segment. The elastic element is mounted between the tapping element and the connecting segment to abut against the tapping element and to enable the tapping element to move relative to the connecting segment. The structural relationship between the connecting segment, the tapping element, and the elastic element may provide a delayed rebound and damping effect to the reaction force, and the applied force is continuously transferred to a tapping object, and this may reduce noise and the loss of energy.