Flow cell using peltier module as prime mover for polymerase chain reaction

I claim: 1 . A flow cell for DNA amplification, comprising: a substrate having a proximal end, a distal end opposite the proximal end, a first side intermediate the proximal end and the distal end, a second side opposite the first side and intermediate the proximal end and the distal end, and opposite upper and lower faces each bound by the proximal end, the distal end, the first side, and the second side; and a continuous fluid flow channel disposed on the upper surface, the fluid flow channel comprising a loading port, a first heat portion in fluidic communication with the loading port, proximate the distal end and the first side, and configured for being heated to a first temperature, a second heat portion in fluidic communication with the first heat portion, proximate the distal end and the second side, and configured for being heated to a second temperature, and a third heat portion in fluidic communication with the second heat portion, intermediate the first side and the second side, and configured for being heated to one of a plurality of temperatures. 2 . The flow cell of claim 1 , wherein the substrate is rectangular. 3 . The flow cell of claim 1 , wherein the fluid flow channel further comprises a fourth unheated portion in communication with the first heat portion and proximate the proximal end of the substrate. 4 . The flow cell of claim 1 , further comprising a first thermal barrier intermediate the first heat portion and the third heat portion and intermediate the second heat portion and the third heat portion. 5 . The flow cell of claim 4 , wherein the first thermal barrier comprises a first barrier portion intermediate the first heat portion and the third heat portion and a second barrier portion intermediate the second heat portion and the third heat portion. 6 . The flow cell of claim 4 , wherein the first thermal barrier is disposed on the substrate. 7 . The flow cell of claim 1 , further comprising a second thermal barrier intermediate the first heat portion and the second heat portion. 8 . The flow cell of claim 7 , wherein the second thermal barrier is a discontinuity in the distal end of the substrate. 9 . The flow cell of claim 1 , further comprising a lid over the upper face, the loading port forming an orifice through the lid and into the fluid flow channel. 10 . The flow cell of claim 1 , wherein the second temperature is greater than the first temperature. 11 . The flow cell of claim 1 , wherein the loading port is intermediate the proximal end and third heat portion. 12 . The flow cell of claim 1 , wherein the fluid flow channel in the third heat portion is substantially serpentine. 13 . The flow cell of claim 1 , wherein the fluid flow channel in each of the first and second heat portions is substantially serpentine. 14 . A system for DNA amplification, comprising: a flow cell comprising a rectangular substrate having a proximal end, a distal end opposite the proximal end, a first side intermediate the proximal end and the distal end, a second side opposite the first side and in the proximal end and the distal end, and opposite upper and lower faces each bound by the proximal end, the distal end, the first side, and the second side, a continuous fluid flow channel disposed on the upper face, the fluid flow channel comprising a loading port, a first heat portion in fluidic communication with the loading port, proximate the distal end and the first side, and configured for being heated to a first temperature, a second heat portion in fluidic communication with the first heat portion, proximate the distal end and the second side, and configured for being heated to a second temperature, a third heat portion in fluidic communication with the second heat portion, intermediate the first side and the second side, and configured for being heated to one of a plurality of temperatures, and a fourth unheated portion in communication with the first heat portion and proximate the proximal end of the substrate; a flow cell process heater for selectively receiving the distal end of the flow cell, for heating the first heat portion to the first temperature, and for heating the second heat portion to the second temperature; and a flow control heater proximate the flow cell process heater and configured to selectively heat the third heat portion of the fluid flow channel via the lower face of the flow cell when the distal end of the flow cell is installed within the flow cell process heater, whereby the selective heating of the third portion of the fluid flow channel causes the pressure in the third portion to increase or decrease relative to the pressure in the fourth unheated portion, based upon the degree of selective heating by the flow control heater, thereby selectively moving fluid within the fluid flow channel between the first heat portion and the second heat portion. 15 . The system of claim 14 , wherein the flow cell process heater further comprises optical detector windows, whereby the first heat portion and the second heat portion are each visible through a respective one of the optical detector windows when the distal end of the flow cell is received within the flow cell process heater. 16 . The system of claim 14 , wherein the flow cell process heater comprises a first heater for heating the first heat portion to the first temperature and a second heater for heating the second heat portion to the second temperature. 17 . The system of claim 16 , wherein each of the first heater and the second heater is an individually controlled Peltier heater. 18 . The system of claim 14 , wherein the flow cell process heater comprises resilient members for selectively engaging the flow cell when the flow cell distal end is inserted into the flow cell process heater. 19 . The system of claim 18 , wherein each of the resilient members extends laterally across a top of the flow cell process heater. 20 . The system of claim 18 , wherein each resilient member is attached to the flow cell process heater at a respective distal end thereof and has a proximal end that is deflected upwards upon insertion of the flow cell into the flow cell process heater, the deflection causing each of the resilient members to apply downward force on the flow cell. 21 . The system of claim 14 , wherein the flow control heater comprises a heater module and a heat distribution plate intermediate the heater module and the lower face of the flow cell when the distal end of the flow cell is received within the flow cell process heater. 22 . The system of claim 21 , wherein the heater module is a Peltier module. 23 . The system of claim 14 , further comprising a resilient flow cell retention clip proximate the flow control heater and deformable upwardly by the upper face of the flow cell when the flow cell is received within the flow cell process heater, the deformation of the resilient flow cell retention clip applying downward force on the flow cell. 24 . The system of claim 23 , wherein the resilient flow cell retention clip is adjacent the third heat portion of the continuous fluid flow channel when the flow cell is received within the flow cell process heater. 25 . The system of claim 23 , wherein the flow cell further comprises a lid over the upper face, the loading port forming an orifice through the lid and into the fluid flow channel, the resilient flow cell retentio