Extracorporeal Membrane Oxygenator With Partitioned Sides

What is claimed is: 1 . An oxygenator for oxygenating blood, the oxygenator comprising: an oxygenator assembly comprising a blood inlet, an oxygenation chamber, a blood outlet, and elongated gas permeable conduits that extend across the oxygenation chamber, wherein the oxygenator assembly is configured so that a blood flow received via the blood inlet is contacted with exterior surfaces of the elongated gas permeable conduits and exits the oxygenator assembly through the blood outlet, wherein each of the elongated gas permeable conduits comprises a gas permeable outer wall configured to accommodate transfer of oxygen from within the elongated gas permeable conduit to the blood flow and transfer carbon dioxide from the blood flow into the elongated gas permeable conduits, wherein a first set of the elongated gas permeable conduits is oriented parallel to a first direction; and wherein a second set of the elongated gas permeable conduits is oriented parallel to a second direction that is transverse or opposite to the first direction; and a housing comprising a gas inlet and configured to distribute a gas flow received through the gas inlet to the elongated gas permeable conduits so as to flow a first portion of the gas flow through the first set of the elongated gas permeable conduits in the first direction and flow a second portion of the gas flow through the second set of the elongated gas permeable conduits in the second direction. 2 . The oxygenator of claim 1 , wherein the housing further comprises: a first inlet chamber configured to deliver the first portion of the gas flow to the first set of the elongated gas permeable conduits; and a second inlet chamber configured to deliver the second portion of the gas flow to the second set of the elongated gas permeable conduits. 3 . The oxygenator of claim 2 , wherein the housing further comprises: a first outlet chamber configured to receive a first outlet gas flow exiting from the first set of the elongated gas permeable conduits; and a second outlet chamber configured to receive a second outlet gas flow exiting from the second set of the elongated gas permeable conduits. 4 . The oxygenator of claim 3 , wherein the housing further comprises: an inlet plenum configured to receive the gas flow from the gas inlet, distribute the first portion of the gas flow to the first inlet chamber, and distribute the second portion of the gas flow to the second inlet chamber; a gas outlet; and an outlet plenum configured to collect the first outlet gas flow from the first outlet chamber, collect the second outlet gas flow from the second outlet chamber, and deliver the first outlet gas flow and the second outlet gas flow to the gas outlet. 5 . The oxygenator of claim 1 , wherein: a third set of the elongated gas permeable conduits is oriented parallel to a third direction; the housing is configured to distribute a third portion of the gas flow so as to flow through the third set of the elongated gas permeable conduits in the third direction; a fourth set of the elongated gas permeable conduits is oriented parallel to a fourth direction that is transverse to the first direction and transverse or opposite to the third direction; and the housing is configured to distribute a fourth portion of the gas flow so as to flow through the fourth set of the elongated gas permeable conduits in the fourth direction. 6 . The oxygenator of claim 5 , wherein: the blood flow flows through the oxygenation chamber in a blood flow direction; and the third set and the fourth set of the elongated gas permeable conduits are offset from the first set and the second set of the elongated gas permeable conduits along the blood flow direction or perpendicular to the blood flow direction. 7 . The oxygenator of claim 6 , wherein the third direction is transverse to the first direction. 8 . The oxygenator of claim 1 , wherein the oxygenation chamber has a circular, a square, a rectangular, a hexagonal, or an octagonal cross-sectional shape. 9 . The oxygenator of claim 1 , wherein the elongated gas permeable conduits comprise hollow fibers. 10 . The oxygenator of claim 1 , further comprising a heat exchanger disposed within the housing and configured to regulate a temperature of the blood flow. 11 . The oxygenator of claim 10 , further comprising: a temperature regulation fluid inlet, a temperature regulation fluid outlet, and heat exchanger conduits; a first set of the heat exchanger conduits is oriented parallel to a heat exchanger conduit first direction; a second set of the heat exchanger conduits is oriented parallel to a heat exchanger conduit second direction that is transverse or opposite to the heat exchanger conduit first direction; the heat exchanger is configured so that the blood flow received via the blood inlet is contacted with exterior surfaces of the heat exchanger conduits, a first portion of a flow of temperature regulation fluid received through the temperature regulation fluid inlet flows through the first set of the heat exchanger conduits in the first direction, and a second portion of the flow of temperature regulation fluid flows through the second set of the heat exchanger conduits in the second direction. 12 . The oxygenator of claim 1 , wherein the blood flow is perpendicular to the first direction and the second direction. 13 . A method of oxygenating blood, the method comprising: passing a blood flow received through a blood inlet of an oxygenator assembly over exterior surfaces of elongated gas permeable conduits that extend across an oxygenation chamber of the oxygenator assembly; and distributing a gas flow including oxygen received through a gas inlet of a housing to the elongated gas permeable conduits such that a first portion of the gas flow flows through a first set of the elongated gas permeable conduits in a first direction and a second portion of the gas flow flows through a second set of the elongated gas permeable conduits in a second direction that is transverse to or opposite to the first direction to transfer oxygen from the gas flow to the blood flow and to transfer carbon dioxide from the blood flow to the gas flow. 14 . The method of claim 13 , wherein the blood flow flows through the oxygenator perpendicular to each of the first direction and the second direction. 15 . The method of claim 14 , wherein the housing further comprises: a first inlet chamber configured to deliver the first portion of the gas flow to the first set of the elongated gas permeable conduits; and a second inlet chamber configured to deliver the second portion of the gas flow to the second set of the elongated gas permeable conduits. 16 . The method of claim 15 , further comprising distributing the gas flow such that a third portion of the gas flow flows through a third set of the elongated gas permeable conduits oriented parallel to a third direction, and a fourth portion of the gas flow flows through a fourth set of the elongated gas permeable conduits oriented parallel to a fourth direction that is transverse to the first direction and transverse or opposite to the third direction. 17 . The method of claim 16 , wherein the third set and the fourth set of the elongated gas permeable conduits are offset from the first set and the second set of the elongated gas permeable conduits along the blood flow direction or perpendicular to the blood flow direction. 18 . The method of claim 17 , wherein the third direction is transverse to or perpendicular to the first direction.