Assessment of micro-organism presence

The invention claimed is: 1. A sample partition device, comprising: one or more components that, when assembled, comprise: a well plate structure comprising a plurality of wells and a plurality of mesofluidic channels linking each well to at least one other well; a compliant layer positioned over at least the wells and mesofluidic channels, wherein the compliant layer interfaces with the mesofluidic channels to create an enclosed flow path or regulate flow; and a cover plate positioned over the compliant layer so as to secure the compliant layer to the well plate so as to create a sealed environment within the plurality of wells and the plurality of mesofluidic channels. 2. The sample partition device of claim 1 , wherein the well plate comprises a microtiter plate. 3. The sample partition device of claim 1 , wherein the compliant layer comprises a membrane having a thickness between 50 μm and 500 μm. 4. The sample partition device of claim 1 , wherein the cover plate, the compliant layer, and the well plate comprise complementary alignment features which engage to align the cover plate, the compliant layer, and the well plate when assembled. 5. The sample partition device of claim 1 , further comprising an inlet through which a sample is introduced to the well plate and an outlet through which air exits as the well plate is filled with the sample. 6. The sample partition device of claim 1 , further comprising: an engagement layer comprising a plurality of protruding structures corresponding to locations of at least the wells within the well plate and configured to deform the compliant layer at least at the locations of the wells when engaged with the cover plate. 7. The sample partition device of claim 6 , wherein the protruding structures of the engagement layer further correspond to locations of mesofluidic channels within the well plate and are configured to deform the compliant layer at the locations of the mesofluidic channels as well when engaged with the cover plate. 8. The sample partition device of claim 6 , further comprising: a secure plate configured to secure the engagement layer to the cover plate, the compliant layer, and the well plate when assembled, wherein the secure plate comprises a plurality of protrusions corresponding to the locations of the protruding structures of the engagement layer. 9. The sample partition device of claim 1 , wherein the sample partition device is configured to receive a sample of between 5 mL to 200 mL and to automatically partition the sample into the plurality of wells such that the sample is contained within at least a subset of the plurality of wells. 10. The sample partition device of claim 1 , wherein the plurality of mesofluidic channels link the plurality of wells in a serpentine path forming a single fluid path connecting the plurality of wells. 11. The sample partition device of claim 1 , wherein the plurality of mesofluidic channels link the plurality of wells in an open arrangement such that fluid flows during use from a respective well to any adjacent well. 12. The sample partition device of claim 1 , wherein the compliant layer is secured to the well plate so as to create the sealed environment prior to use so that a sample is loaded into the sealed environment. 13. A method for partitioning a sample, comprising: introducing a sample via an inlet to a sample partition device and air exits the sample partition device via an outlet as the sample partition device is filled with the sample, wherein the sample partition device comprises a plurality of wells fluidically interconnected by a plurality of mesofluidic channels and wherein the sample is automatically partitioned between the wells by flowing through the plurality of mesofluidic channels; pressing a compliant layer toward the wells and mesofluidic channels so as to deform the compliant layer at the locations of the wells so as to seal the plurality of wells once filled. 14. The method of claim 13 , wherein pressing the compliant layer toward the wells and mesofluidic channels comprises applying an engagement layer comprising a plurality of protruding structures corresponding to locations of at least the wells within the well plate, wherein the engagement layer, when applied, deforms the compliant layer at least at the locations of the wells so as to seal the wells. 15. The method of claim 14 , further comprising clearing the mesofluidic channels of sample prior to sealing the wells using additional protruding structures of the engagement layer corresponding to the locations of the mesofluidic channels. 16. The method of claim 14 , further comprising applying a secure plate to secure the engagement layer to the well plate, wherein the secure plate comprises a plurality of protrusions corresponding to the locations of the protruding structures of the engagement layer so as to apply continued pressure on the engagement layer toward the well plate at the locations of at least the wells. 17. The method of claim 13 , wherein the sample is automatically partitioned between only a subset of the wells. 18. The method of claim 13 , further comprising clearing the mesofluidic channels of sample prior to sealing the wells using a flow of air between the compliant layer and the well plate. 19. The method of claim 13 , wherein the sample partition device comprises a well plate comprising the plurality of wells and the plurality of mesofluidic channels, the compliant layer, and a cover plate securing the compliant layer to the well plate so as to create a sealed environment prior to introducing the sample. 20. The method of claim 13 , wherein each individual well is of less volume than the sample but an aggregate volume of the wells is of greater volume than the sample.