Integrated disposable component system for use in dialysis systems

The invention claimed is: 1. An apparatus adapted to filter blood, the apparatus comprising: a dialyzer configured to filter blood; a first flow path encompassed in a substrate, wherein the first flow path is configured to carry blood from and to a patient through the dialyzer; a dialysate regeneration system comprising a plurality of cartridges containing sorbents and configured to regenerate dialysate; a second flow path having first and second portions encompassed in the substrate and a third portion, wherein the first portion extends from a first output port of the dialyzer to a first port on the substrate and the second portion extends from a first input port of the dialyzer to a second port on the substrate, wherein the third portion is defined by a first tube extending from the first port to the dialysate regeneration system and a second tube extending from the second port to the dialysate regeneration system, and wherein the first flow path and second flow path are fluidically isolated from each other; at least one diaphragm positioned in the molded, substrate and over at least one of the first or second flow paths; a waste collection reservoir configured to receive waste fluid; a fluid reservoir configured to supply fluid, wherein each of the waste reservoir, fluid reservoir, dialysate regeneration system, and dialyzer is in fluid communication with the substrate; and a pump having first and second channels, wherein the first channel is configured to draw dialysate from the dialyzer through the first portion of the second flow path and force dialysate, via the third portion of the second flow path, into and out of the dialysate regeneration system and then back into the dialyzer via the second portion of the second flow path, wherein the second channel is configured to propel blood through the first flow path, and wherein the pump is in pressure communication with the dialysate regeneration system. 2. The apparatus of claim 1 , wherein the substrate comprises a third port, the apparatus further comprising a third tube having a first end fixedly attached to the third port and a second end fixedly attached to a second input port of the dialyzer. 3. The apparatus of claim 1 , wherein the substrate comprises a fourth port, the apparatus further comprising a fourth tube having a first end fixedly attached to the fourth port and a second end adapted to be removably attached to an input port of the waste collection reservoir. 4. The apparatus of claim 1 , further comprising a fifth tube having a first end fixedly attached to the first output port of the dialyzer and a second end fixedly attached to the first port. 5. The apparatus of claim 1 , wherein the substrate comprises a third port and a fifth port, the apparatus further comprising a third tube having a first end fixedly attached to the third port and a second end fixedly attached to a second input port of the dialyzer and a sixth tube having a first end fixedly attached to the fifth port and a second end fixedly attached to a second output port of the dialyzer. 6. The apparatus of claim 1 further comprising embedded data, wherein the embedded data uniquely identifies a disposable portion of the apparatus, and wherein the embedded data comprises data stored by at least one of a barcode, a Radio Frequency Identification (RFID) tag, an electrically erasable programmable read-only memory (EEPROM), and a microchip. 7. An apparatus adapted to filter blood comprising: a waste collection reservoir configured to receive waste fluid; a fluid reservoir configured to supply fluid; a dialysate regeneration system comprising a plurality of cartridges containing sorbents and configured to regenerate dialysate; a dialyzer configured to filter blood; a plastic substrate in fluid communication with the waste collection reservoir, fluid reservoir, dialysate regeneration system, and dialyzer, wherein the plastic substrate comprises: first and second inlet ports; first and second outlet ports; a first flow path comprising at least one sensor molded therein wherein the first flow path forms a pathway for transporting blood from the first inlet port to the dialyzer and from the dialyzer to the first outlet port; a second flow path comprising at least one sensor molded therein, first and second portions formed in the substrate and a third portion external to the substrate, wherein the first portion forms a pathway for transporting a first fluid from the dialyzer to the second outlet port and the second portion forms a pathway for transporting the first fluid from the second inlet port to the dialyzer, and wherein the third portion is defined by first and second tubes that respectively enable the dialysate regeneration system to be in fluid communication with the second outlet port and the second inlet port; and and a pump having first and second channels, wherein the first channel is configured to draw the first fluid from the dialyzer through the first portion of the second flow path and force the first fluid, via the third portion of the second flow path, into the dialysate regeneration system and then back into the dialyzer via the second portion of the second flow path, wherein the second channel is configured to move blood through the first flow path, and wherein the pump is in pressure communication with the dialysate regeneration system. 8. The apparatus of claim 7 further comprising a third tube that enables the first inlet port to be in fluid communication with the dialyzer. 9. The apparatus of claim 7 further comprising a fourth tube that enables a third outlet port to be in fluid communication with the waste collection reservoir. 10. The apparatus of claim 7 wherein the rigid substrate comprises embedded data and wherein the embedded data uniquely identifies a disposable portion of the apparatus, and wherein the embedded data comprises data stored by at least one of a barcode, a Radio Frequency Identification (RFID) tag, an electrically erasable programmable read-only memory (EEPROM), and a microchip. 11. The apparatus of claim 7 wherein the at least one sensor comprises a transducer diaphragm. 12. The apparatus of claim 11 wherein the transducer diaphragm comprises polyisoprene. 13. An apparatus adapted to filter blood, the apparatus comprising: a dialyzer configured to filter blood; a first flow path encompassed in a substrate, wherein the first flow path is configured to carry blood from and to a patient through the dialyzer; a dialysate regeneration system comprising a plurality of cartridges containing sorbents and configured to regenerate dialysate; a second flow path having first and second portions encompassed in the substrate and a third portion, wherein the first portion extends from the dialyzer to a first port on the substrate and the second portion extends from the dialyzer to a second port on the substrate, wherein the third portion is defined by a first tube extending from the first port to the dialysate regeneration system and a second tube extending from the second port to the dialysate regeneration system, and, wherein the first flow path and second flow path are fluidically isolated from each other; at least one sensor molded into at least one of the first or second flow paths using a multi-shot plastic injection molding process; a waste collection reservoir configured to receive waste fluid; a fluid reservoir configured to supply fluid, wherein each of the waste reservoir, fluid reservoir, dialysate regeneration system, and dialyzer is in fluid communication with the substrate; and a pump having first and second channels, wherein the first channel is configured t