An implant having a porous layer and a molding method thereof includes: a substrate having a bone contact surface being in part in direct contact with a bone of a patient; a porous layer having a void inside; a connecting layer disposed between the bone contact surface and the porous layer to attach the bone contact surface to the porous layer; and a rib detachably coupled to the porous layer, wherein the connecting layer includes at least one constituent component identical to one of constituent components in the bone contact surface to be integrated into the porous layer and the bone contact surface, thereby firmly attaching the porous layer to the bone contact surface. Accordingly, bonding of dissimilar metals is facilitated by inducing the attachment of the bone contact surface of the implant to the porous layer having a void inside, formed by dissimilar metals, through the connecting layer including at least one constituent component identical to one of constituent components of the bone contact surface.

An implantable prosthesis that includes a biased coiling member and a conforming coiling member. The biased coiling member may be biased to curve from a substantially linear configuration to a nonlinear configuration. The conforming coiling member may be engaged with and curved by the biased coiling member from the substantially linear configuration to the nonlinear configuration. The biased coiling member may define a longitudinal axis when in the substantially linear configuration. The biased coiling member and the conforming coiling member may move relative to each other along the longitudinal axis. The prosthesis may be implanted in a surgical procedure that minimizes incision sizes and may be considered less invasive than typical implant procedures, especially spinal implant procedures.

In the present disclosure, an artificial joint stem includes a base extending in a vertical direction when a proximal side of a human body in use is defined as an upward direction, and a coating film containing a calcium phosphate-based material and an antimicrobial material disposed on a part of the base. The base includes one or more boundary lines on the base defined by a presence or absence of the coating film. The one or more boundary lines include a first boundary line located on a lower side of the base with respect to the coating film. The first boundary line is located so as to intersect the vertical direction. A component along the vertical direction of the first boundary line is smaller than a component along a width direction of the base.

An orthopedic implant includes a porous insert having a first insert portion having a first insert thickness and a second insert portion having a second insert thickness. The implant includes a non-metallic structure having a first non-metallic portion having a first non-metallic thickness and a second non-metallic portion having a second non-metallic thickness. The first non-metallic portion is attached to the first insert portion and the second non-metallic portion is attached to the second insert portion. Either or both of the second insert thickness being different from the first insert thickness and the second non-metallic thickness being different from the first non-metallic thickness. The porous insert includes a porous projection extending into the non-metallic structure.

An implant may include a curved implant body and a flange extending from the implant body, the flange being thinner than the implant body, the implant body and the flange having a first exterior surface and a second exterior surface opposite the first surface in which the implant body and the flange formed by at least partially fused particles. The particles at the first surface define a first average pore size and the particles at the second surface define a second average pore size; with the first average pore size being greater than the second average pore size. The first surface may be a tissue ingrowth surface and the second surface may be a tissue ingrowth barrier.

Provided is a bio-coating, including a surface layer. The surface layer includes multiple first single bodies connected in an unordered manner, multiple first through holes formed between the multiple first single bodies and inside the multiple first single bodies. The surface layer arranged on the outermost side of the bio-coating includes the multiple first single bodies connected in an unordered manner, and the multiple first through holes are formed between the multiple first single bodies and inside the multiple first single bodies, i.e., the multiple first single bodies in the surface layer are connected in an unordered manner. Therefore, the multiple first through holes in the surface layer are able to be in an unordered state, facilitating the growing of corresponding bone tissue cells into the surface layer, and thus improving a bone ingrowth effect and long-term stability.

An implant for repairing a cartilage defect comprising a first layer and a second layer. The first layer comprises a membrane-like structure and the second layer comprises a sponge-like structure with directional and/or interconnected pores. The first layer is facing the synovial space and the second layer is located towards bone.

A surgical implant and a method for the making the surgical implant is provided. The surgical implant includes various granules incorporated into an upper surface and a lower surface of a body portion thereof. The granules can be pressed into the upper surface and the lower surface via physical force using at least one mold portion. The physical force applied by the at least one mold portion can deform and/or extrude the upper surface and the lower surface to impregnate these surfaces with the granules. The granules can provide the implant with bioresorbable and/or mechanically-reinforced properties.

A method for structuring a surface of an implant (100) made from a plastic material by means of a counter-body (200) comprises the following steps: providing (S110) of a counter-body (200) including a surface (210); forming (S120) of a first surface structure (212) on the surface (210) of the counter-body, wherein a first surface structure (212) comprises a non-regular, randomly distributed pattern; and forming (S130) of a second surface structure (112) on the implant (100) by using the counter-body (200), wherein the second surface structure and the first surface structure (212) are complementary to each other.

A fixation facilitator mechanically associated with an intraosseous dental implant fixture.