A method of reinforcing a biological construct according to an exemplary aspect of the present disclosure includes, among other things, attaching a suture loop/needle construct to a reinforcement material and stitching the reinforcement material to a biological construct to form a reinforced biological construct. The reinforcement material is attached to the suture loop/needle construct prior to approximating the reinforcement material to the biological construct.

Systems and methods for knotless tissue repair employ a first suture construct routed through a tissue in a first inverted mattress stitch, including a loop portion and two free limbs. The loop portion of the first suture construct so routed is positioned adjacent to a superior surface of the tissue and the free limbs of the first suture construct so routed extend through an inferior surface of the tissue. A second suture construct, separate from the first suture construct, is inserted within the loop portion of the first suture construct such that two free limbs of the second suture construct extend from the loop portion of the first suture construct. The second suture construct comprises a plurality of braided filaments and possesses a substantially rectangular cross-sectional profile, and does not include a suture core surrounded by the braided filaments.

Systems and methods for knotless tissue repair employ a first suture construct routed through a tissue in a first inverted mattress stitch, including a loop portion and two free limbs. The loop portion of the first suture construct so routed is positioned adjacent to a superior surface of the tissue and the free limbs of the first suture construct so routed extend through an inferior surface of the tissue. A second suture construct, separate from the first suture construct, is inserted within the loop portion of the first suture construct such that two free limbs of the second suture construct extend from the loop portion of the first suture construct. The second suture construct comprises a plurality of braided filaments and possesses a substantially rectangular cross-sectional profile, and does not include a suture core surrounded by the braided filaments.

A biomimetic tissue scaffold for repairing an elongated tissue in need of repair can comprise a plurality of coiled flexible polymeric ribbons having a surface on which is formed an array of nanofibers, the ribbons forming a tubular body defining a first open end in which a first end of the elongated tissue is receivable, a second open end in which a second end of the elongated tissue is receivable, and a lumen extending between the first and second open ends.

Methods of making decellularized tendon matrix (DTM) and DTM hydrogels are provided. These compositions and hydrogels are useful for repairing tendon injuries and in some cases may be used by injection, arthroscopic procedures, or as adjuncts to traditional surgical repair.

Devices, systems and methods for fixating soft tissue to bone. In one embodiment, a repair device system for fixating soft tissue to bone includes a carrier member, multiple anchors, and a bone anchor. The carrier member includes multiple pad portions and a bone coupling portion. Each of the pad portions are aligned with an adjacent pad portion. The pad portions are configured to be positioned over a side of the soft tissue and the bone coupling portion is coupled to the multiple pad portions. Each anchor is sized and configured to extend through the at least one opening defined in one of the multiple pad portions and through the soft tissue. The bone anchor is configured to be coupled to the bone coupling portion and configured to be secured to the bone.

An artificial tongue is provided. The artificial tongue includes tongue tissue formed by a bioprinting process, an antenna embedded within the tongue tissue and configured to wirelessly receive power from an external device, a processor embedded within the tongue tissue and operatively coupled to the antenna, and a piezoelectric element embedded within the tongue tissue and operatively coupled to the processor. The piezoelectric element is configured to deform in response to an applied electric bias, and the processor is configured to cause the electric bias to be applied to the piezoelectric element based on the power received by the antenna.

An artificial tongue is provided. The artificial tongue includes tongue tissue formed by a bioprinting process, an antenna embedded within the tongue tissue and configured to wirelessly receive power from an external device, a processor embedded within the tongue tissue and operatively coupled to the antenna, and a piezoelectric element embedded within the tongue tissue and operatively coupled to the processor. The piezoelectric element is configured to deform in response to an applied electric bias, and the processor is configured to cause the electric bias to be applied to the piezoelectric element based on the power received by the antenna.

Apparatus for locating an attachment position for a reconstructed anterior cruciate ligament on an attachment surface of a bone comprises locating means 51, 61 arranged to locate at least one reference surface 4 of the bone and guide means 53, 54 arranged to define the attachment position in two dimensions on the attachment surface relative to the reference surface.

A rotator cuff balloon (10) is disclosed, the rotator cuff balloon (10) includes a limiting structure (100) and a protective structure (200) connected to the limiting structure (100). The limiting structure (100) defines a curvature along a coronal plane. The rotator cuff balloon (10) conforms to the physiological structure of the human shoulder joint limits itself in the subacromial space and can reduce a patient's foreign body sensation, dislocation, functional failure and other adverse events.