Assay cartridge

What is claimed is: 1. A cartridge for fluid manipulation, the cartridge comprising: a cartridge body defining a holding compartment and first and second fractioning compartments formed within the cartridge body, and the cartridge body defining a number of flow channels formed within the cartridge body, the compartments and flow channels configured such that, when the cartridge body is held in a first vertical orientation, a predetermined quantity of fluid can be held in the holding compartment, and such that the predetermined quantity of fluid can be poured from the holding compartment to the first fractioning compartment by rotating the cartridge body about a predefined rotation axis to a second vertical orientation, to spill the fluid from the holding compartment to the first fractioning compartment through a first one of the flow channels; a separate reservoir comprising two reservoir compartments, the reservoir mateable to the cartridge body to supply fluids to the cartridge body; and wherein the first fractioning compartment is of a shape, size, and position such that when the cartridge body is held in the second vertical orientation, not all of the predetermined quantity of fluid can be contained in the first fractioning compartment, and wherein the first fractioning compartment is connected to the second fractioning compartment by a second one of the flow channels, and wherein the compartments and flow channels are configured such that any of the fluid that overflows the first fractioning compartment when the cartridge body is held in the second orientation flows through the second flow channel to the second fractioning compartment; and wherein the cartridge further comprises two analysis areas, one analysis area respectively for each fractioning compartment, each of the analysis areas including a respective absorbent medium, and wherein the analysis areas are connected directly or indirectly to the respective fractioning compartments by respective ones of the flow channels, and the analysis areas are positioned such that fluid held in the fractioning compartments, when the cartridge body is in the second orientation, can be delivered to the respective analysis areas by one or more subsequent rotations of the cartridge body about the rotation axis, to spill fluid from the fractioning compartments and into the respective connections to the analysis areas to transport across the absorbent medium of the respective analysis area by capillary wicking action. 2. The cartridge of claim 1 , wherein the first and second fractioning compartments are shaped, sized, and positioned such that the predetermined quantity of fluid can be held in substantially equal quantities in the first and second fractioning compartments when the cartridge body is held in the second vertical orientation. 3. The cartridge of claim 1 , wherein: the cartridge body defines a third fractioning compartment; the first and second fractioning compartments are shaped, sized, and positioned such that the predetermined quantity of fluid cannot be contained within the first and second fractioning compartments when the cartridge body is held in the second vertical orientation; and the second fractioning compartment is connected by a third one of the flow channels to the third fractioning compartment, such that any of the fluid that overflows the second fractioning compartment when the cartridge body is held in the second vertical orientation flows through the third flow channel to the third fractioning compartment. 4. The cartridge of claim 3 , wherein the first, second, and third fractioning compartments are shaped, sized, and positioned such that the predetermined quantity of fluid can be held in substantially equal quantities in the first, second, and third fractioning compartments when the cartridge body is held in the second vertical orientation. 5. The cartridge of claim 1 , wherein the cartridge body further defines two mixing compartments, one mixing compartment respectively for each fractioning compartment, and wherein the fluid spilled from the fractioning compartments passes through the respective mixing compartments before reaching the respective analysis areas. 6. The cartridge of claim 5 , wherein each of the mixing compartments stores a quantity of a reagent positioned to mix with the fluid spilled from the respective fractioning compartment before the fluid flows to the respective analysis area. 7. The cartridge of claim 1 , wherein: the fluid is a first fluid; the cartridge body further defines a second set of compartments and flow channels for manipulating a second fluid in sequence through the second set of compartments in reaction to the rotations of the cartridge about the rotation axis and the holding of the cartridge in the first and second vertical orientations; the cartridge body further defines a second set of outlet channels respectively connecting the last of the second set of compartments with the analysis areas; and the second set of compartments and flow channels and the outlet channels are shaped, sized, and positioned such that the second fluid reaches the analysis areas later than the first fluid when the cartridge is rotated in such a way as to deliver the first fluid to the analysis areas. 8. The cartridge of claim 7 , wherein the lengths of the outlet channels are selected to ensure that the second fluid will reach the analysis areas later than the first fluid. 9. A cartridge for fluid manipulation, the cartridge comprising a cartridge body and a separate reservoir, wherein: the cartridge body defines a first set of compartments and flow channels for manipulating a first fluid, the compartments and channels in the first set sized, shaped, and positioned such that a sequence of rotations of the cartridge body about a predefined rotation axis to a number of vertical orientations in which the cartridge body is held will cause a quantity of the first fluid to sequentially pass through all of the compartments in the first set via the first set of flow channels to reach an outlet of the first set of compartments and flow channels; the cartridge body defines a second set of compartments and flow channels for manipulating a second fluid, the compartments and channels in the second set sized, shaped, and positioned such that the same sequence of rotations of the cartridge body about the predefined rotation axis causes a quantity of the second fluid to sequentially pass through all of the compartments in the second set via the second set of flow channels to reach an outlet of the second set of compartments and flow channels; the outlets of the first and second sets of compartments and flow channels are joined at a junction; the first and second sets of compartments and flow channels are shaped, sized, and positioned such that the second fluid reaches the junction at a different time than the first fluid in response to the sequence of rotations; the cartridge comprises an analysis area at the junction, the analysis area including an absorbent medium, and wherein the analysis area is positioned such that fluid output from the junction is delivered to the absorbent medium, to transport across the absorbent medium by capillary wicking action; and the reservoir comprises two reservoir compartments, and the reservoir is mateable to the cartridge body to supply fluids to the cartridge body. 10. The cartridge of claim 9 , wherein the reservoir holds a sample fluid and a washing buffer fluid in respective compartments of the reservoir, the reservoir including two openings sealed by puncturable sealing covers; and two hollow piercing elements positioned on the cartridge body such that the two piercing elements pierce the punctura