Surgical implants comprising graded porous structures

1 . A surgical implant, comprising: a porous structure having interconnected pores configured for ingrowth of bone into the porous structure, wherein the porous structure comprises an arrangement of fibers which are attached to one another, wherein the fibers are arranged in layers, and wherein the layers are stacked; and wherein the porous structure includes a surface including a plurality of regions having different porosities, the different porosities being determined by the arrangement of fibers. 2 . The surgical implant of claim 1 , wherein the porous structure is attached to a dense part, and wherein the surface is disposed opposite the dense part. 3 . The surgical implant of claim 2 , wherein the dense part includes an interface with the porous structure, wherein a direction of stacking of the layers of the porous structure is oriented along a direction of approach to the interface or a direction away from the interface. 4 . The surgical implant of claim 1 , wherein the surface has a first porosity in a first region of the surface and a second porosity in a second region of the surface, a difference between the first porosity and the second porosity being at least 4%. 5 . The surgical implant of claim 4 , wherein the difference between the first porosity and the second porosity is at least 6%. 6 . The surgical implant of claim 4 , wherein the first porosity is between 45% and 90% and wherein the second porosity is between 40% and 85%. 7 . The surgical implant of claim 6 , wherein the first porosity is between 70% and 90% and wherein the second porosity is between 40% and 60%. 8 . The surgical implant of claim 1 , wherein the porous structure has an average porosity between 50% and 80%. 9 . The surgical implant of claim 1 , wherein the fibers each have a diameter between 20 μm and 5 mm. 10 . The surgical implant of claim 1 , wherein fibers of consecutive layers interpenetrate, wherein a ratio between a penetration depth between the fibers of consecutive layers and a diameter of the fibers is between 0.05 and 0.5. 11 . The surgical implant of claim 10 , wherein the ratio is between 0.1 and 0.5. 12 . The surgical implant of claim 1 , wherein a spacing between adjacent fibers of a same layer is between 10 μm and 5 mm. 13 . The surgical implant of claim 12 , wherein the spacing between the fibers in at least one layer changes between a first region and a second region to obtain the different porosities. 14 . The surgical implant of claim 1 , wherein the porous structure comprises a porosity gradient in a direction orthogonal to the surface. 15 . The surgical implant of claim 1 , wherein the porous structure is attached to a dense part, wherein the surface is located opposite an interface of the porous structure with the dense part, and wherein the porous structure comprises a porosity gradient wherein the porosity decreases in a direction of approach to the dense part. 16 . The surgical implant of claim 14 , wherein a penetration depth between the fibers of consecutive layers changes along a direction of the porosity gradient. 17 . The surgical implant of claim 1 , wherein the fibers comprise micropores. 18 . The surgical implant of claim 1 , wherein the different regions having different porosities alternate on the surface. 19 . A method of making a surgical implant, the method comprising: forming fibers in layers, the layers being stacked; connecting the fibers of consecutive layers to one another to obtain a porous structure; and arranging the fibers in proximity of a surface of the porous structure with different interspaces in a plurality of regions of the surface such that the plurality of regions have different porosities. 20 . The method of claim 19 , further comprising making a dense part and attaching the porous structure to the dense part.