Polymer test cartridge mixer for cell lysis

The invention claimed is: 1. A multiple layer test cartridge comprising: an input opening to receive a sample containing cells; an input channel coupled to the input opening to receive the sample from the input opening; a first lysing channel structure coupled to the input channel and adapted to receive the sample from the input channel, the first lysing channel structure having two side channels coupled to and extending away from an input channel and adapted such that the sample in the input channel is split between the two side channels, the first lysing channel structure having a backbone channel orthogonally coupled to the two side channels and adapted to receive and recombine the split sample; a second lysing channel structure having two side channels coupled to and extending away from the backbone channel of the first lysing channel structure and adapted such that the sample in the backbone of the first lysing channel structure is split between the two side channels of the second lysing channel structure, the second lysing channel structure having a backbone channel orthogonally coupled to the two side channels of the second lysing channel structure and adapted to receive and recombine the split sample; wherein the first lysing channel structure is disposed in a first polymer layer of the multiple layer test cartridge and the second lysing channel structure is disposed in a second polymer layer of the multiple layer test cartridge different from the first polymer layer, wherein the first and second lysing channel structures are adapted to lyse the cells in the sample; and a test chamber coupled to the backbone channel of the second lysing channel structure and is adapted to receive the recombined sample from the backbone channel of the second lysing channel structure. 2. The test cartridge of claim wherein each lysing channel structure has a letter “F” shape comprising the backbone channel being a straight channel having a base portion and a top portion including the two side channels being two equal length parallel side channels extending orthogonally to the top portion of the backbone channel. 3. The test cartridge of claim 1 , wherein the second lysing channel structure is positioned on a different polymer layer from the first lysing channel structure and has ends of both side channels coupled to the base portion of the backbone channel to receive sample from a base portion of the backbone channel of the first lysing channel structure. 4. The test cartridge of claim 3 , further comprising at least two additional lysing channel structures each having the same shape as the first and second lysing channel structures, and each coupled to a backbone channel of a preceding lysing channel structure, wherein the at least two additional lysing channel structures are coupled in series between the first and second lysing channel structures to create a series of four lysing channel structures between the input channel and the test chamber, wherein each lysing channel structure in the series is in a different polymer layer from a preceding lysing channel structure to provide microfluidic mixing structures that provide for repeated splitting, turning and recombining of the sample as it progresses through the series of four lysing channel structures. 5. The test cartridge of claim 4 , further comprising a loop channel fluidically coupled between two of the coupled lysing channel structures in the series to facilitate mixing of a reagent with the sample. 6. The test cartridge of claim 3 , further comprising a diagonal portion fluidically coupled between a bottom of the side channel closest to the base portion of the backbone channel and the backbone channel of at least one of the first and second lysing channel structures. 7. The test cartridge of claim 1 , further comprising an exit channel fluidically coupled between the test chamber and the backbone channel of the second lysing channel structure. 8. The test cartridge of claim 1 , further comprising a reagent positioned in at least one of the input channel and the lysing channel structures. 9. The test cartridge of claim 1 , wherein the first and second polymer layers are adjacent layers. 10. The test cartridge of claim 1 , further comprising at least one polymer layer located between the first and second polymer layers. 11. A multiple layer test cartridge comprising: an input opening to receive a sample containing red blood cells; an input channel coupled to the input opening and adapted to receive the sample from the input opening; a sequence of multiple fluidically coupled lysing channel structures, wherein each of the lysing channel structures comprise a backbone channel and two side channels orthogonally connected to the backbone channel; wherein a first lysing channel structure in the sequence of lysing channel structures is fluidically coupled to the input channel and adapted to receive the sample from the input channel via the two side channels; wherein each of the lysing channel structures fluidically connected to and after the first lysing channel structure in the multiple lysing channel structure sequence have the side channels coupled orthogonally to the backbone channel of a preceding lysing channel structure; a plurality of adjacent layers; wherein the lysing channel structures are each disposed in a layer and each of the lysing channel structures are alternately disposed in different layers and adapted to pass the sample in the sequence of lysing channel structures between the lysing channel structures to provide microfluidic mixing structures that provide for repeated splitting, turning and recombining of the sample; and a test chamber coupled to the multiple lysing channel structures in the sequence and adapted to receive the sample from the multiple lysing channel structures. 12. The test cartridge of claim 11 wherein, each lysing channel structure comprises the backbone channel being a substantially straight channel having a base portion and a top portion including the two side channels being two equal length, substantially parallel side channels extending substantially orthogonal to the top portion of the backbone channel. 13. The test cartridge of claim 12 wherein, the lysing channel structures are arranged no that the first lysing channel structure receives the sample at and end of both side channels distal from the first lysing channel backbone channel, wherein a next lysing channel structure in the sequence of lysing channel structures is positioned on a different polymer layer from the first lysing channel structure and has and end of both side channels coupled to receive sample from the base portion of the backbone channel of the first lysing channel structure.