Synthetic tissue-graft scaffold

1 . In a synthetic tissue-graft scaffold including a set of one or more nominally identical scaffold cages that are configured to facilitate regrowth of tissue of an organism in and around the scaffold cages, each one of the scaffold cages in the set comprising: a volumetric enclosure bounded by a perforated wall structure and having interior and exterior surfaces and first and second opposite ends, the volumetric enclosure defining a central longitudinal axis that extends through the first and second opposite ends, the interior surface defining a boundary of an interior chamber of the volumetric enclosure, and the interior and exterior surfaces defining between them a thickness of the perforated wall structure; first and second annular inlets positioned at, respectively, the first and second ends of the volumetric enclosure, the first and second inlets forming, respectively, first and second conjoining surfaces that are transverse to the central longitudinal axis and configured so that, whenever confronting annular inlets of a pair of the scaffold cages in the set are conjoined, confronting ones of the first or second conjoining surfaces of the pair of scaffold cages form complementary surfaces to each other; a perforated platform bounded by the interior surfaces of the volumetric enclosure and set in transverse relation to the central longitudinal axis, the perforated platform providing a passageway within the interior chamber of the volumetric enclosure between its first and second opposite ends; and corridors extending through the thickness of the perforated wall structure and communicating with the passageway within the interior chamber of the volumetric enclosure to enable migration of material within and out of the scaffold cage. 2 . The synthetic scaffold of claim 2 , in which the first and second annular inlets are positioned at, respectively, the second and first opposite ends. 3 . The synthetic scaffold of claim 1 , in which the set includes an array of multiple nominally identical scaffold cages in the form of a scaffold cage sheet, the multiple scaffold cages oriented such that their associated central longitudinal axes are in generally parallel alignment and the exterior surfaces ( 20 ) of mutually adjacent cages are fused to each other and thereby form a fused perforated wall structure, the fused perforated wall structure having a fused-wall thickness through which spatially aligned corridors extend to allow migration of material between the interior chambers of the mutually adjacent scaffold cages. 4 . The synthetic scaffold of claim 1 , in which the set includes an array of multiple nominally identical scaffold cages in the form of a scaffold cage tier, the multiple scaffold cages oriented such that their associated central longitudinal axes are collinear and define, collectively, a tier axis, and confronting ones of first and second conjoining surfaces of scaffold cages aligned along the tier axis are fused to each other and thereby form a fused inlet structure, the fused inlet structure having a fused-inlet thickness through which spatially aligned annular inlets extend, the aligned annular inlets collectively providing a tier passageway to allow migration of material between the interior chambers of conjoined scaffold cages. 5 . The synthetic scaffold of claim 4 , in which the set includes an array of multiple scaffold cage tiers in the form of a tiered cage sheet, the multiple cage tiers oriented such that their associated tier axes are in generally parallel alignment and the exterior surfaces of a pair of mutually adjacent scaffold cages from the aligned cage tiers are fused to each other and thereby form a fused perforated wall structure between the pair, the fused perforated wall structure having a fused-wall thickness through which spatially aligned corridors extend to allow migration of material between the interior chambers of the pair of scaffold cages. 6 . The synthetic scaffold of claim 5 , in which the exterior surfaces of multiple mutually adjacent scaffold cages from the aligned cage tiers are fused to each other and thereby form fused perforated wall structures, each fused perforated wall structure having a fused-wall thickness through which spatially aligned corridors extend to allow migration of material between the interior chambers of the fused scaffold cages. 7 . The synthetic scaffold of claim 1 , in which the synthetic scaffold is made of β-tricalcium phosphate. 8 . The synthetic scaffold of claim 1 , in which the synthetic scaffold is made of α-tricalcium phosphate, dicalcium phosphate, calcium carbonate, zirconium oxide, or aluminum oxide. 9 . The synthetic scaffold of claim 1 , in which the synthetic scaffold is manufactured using a lithography-based three-dimensional printing technology. 10 . The synthetic scaffold of claim 1 , in which the synthetic scaffold is manufactured using a mold-based, a sculpting-based, or a subtractive manufacturing method. 11 . The synthetic scaffold of claim 1 , in which the first conjoining surface of the first annular inlet is generally shaped as a circle, ellipse, or polygon. 12 . The synthetic scaffold of claim 1 , in which the second conjoining surface of the second annular inlet is generally shaped as a circle, ellipse, or polygon. 13 . The synthetic scaffold of claim 1 , in which the perforated platform constitutes a first perforated platform, and further comprising a second perforated platform, the second perforated platform set transverse to the central longitudinal axis of the volumetric enclosure of the cage and proximal to the second end of the volumetric enclosure relative to the first perforated platform to define a platform pair, the platform pair providing a passageway within the interior chamber of the volumetric enclosure between the first and second ends. 14 . The synthetic scaffold of claim 1 , in which the exterior surface of the perforated wall structure constitutes one or more wall aspects, and the perforated wall structure includes no corridor extending through its fused-wall thickness at one or more of the wall aspects. 15 . The synthetic scaffold of claim 1 , in which the passageway within the interior chamber terminates at and therefore does not extend through one of the first and second opposite ends of the volumetric enclosure. 16 . The synthetic scaffold of claim 1 , further comprising a tissue-graft material inserted into the interior chamber of the volumetric enclosure.