MEMS-based calorimeter, fabrication, and use thereof

The invention claimed is: 1. A microdevice for calorimetric measurement comprising: a reference channel comprising a first passive mixer; a sample channel comprising a second passive mixer; and a thermoelectric sensor located under each of the first and second passive mixers and configured to measure a temperature differential therebetween, wherein each of the first and second passive mixers comprises a micromixer and is configured for three dimensional mixing of a solution, wherein each of the first and second passive mixers comprises a first set of channels in a first horizontal plane and a second set of channels in a second horizontal plane, wherein each of the first and second passive mixers are formed by a top layer and a bottom layer, and further wherein each of the first and second passive mixers comprise a first set of channels in the top layer and a second set of channels in the bottom layer. 2. The microdevice of claim 1 , wherein the thermoelectric sensor comprises a thermopile. 3. The microdevice of claim 1 , further comprising a substrate layer beneath the thermopile. 4. The microdevice of claim 3 , wherein the substrate layer comprises Kapton film. 5. A microdevice for calorimetric measurement comprising: a first layer comprising: a reference channel comprising a first passive mixer; and a sample channel comprising a second passive mixer; and a second layer, coupled to the first layer, comprising a thermoelectric sensor located under each of the first and second passive mixers and configured to measure a temperature differential therebetween, wherein each of the first and second passive mixers comprises a micromixer and is configured for three dimensional mixing of a solution, wherein each of the first and second passive mixers comprises a first set of channels in a first horizontal plane and a second set of channels in a second horizontal plane, wherein each of the first and second passive mixers are formed by a top layer and a bottom layer, and further wherein each of the first and second passive mixers comprise a first set of channels in the top layer and a second set of channels in the bottom layer. 6. The microdevice of claim 5 , wherein the reference channel comprises a first reference channel inlet and a second reference channel inlet, and the sample channel comprises a first sample channel inlet and a second sample channel inlet. 7. The microdevice of claim 5 , wherein the thermoelectric sensor comprises a thermopile. 8. The microdevice of claim 5 , wherein the second layer further comprises a polymeric substrate. 9. The microdevice of claim 8 , wherein the polymeric substrate comprises Kapton film. 10. A microdevice for calorimetric measurement comprising: a first layer consisting essentially of: a reference channel comprising a first passive mixer, a first reference channel inlet, a second reference channel inlet, and a reference channel outlet; and a sample channel comprising a second passive mixer, a first sample channel inlet, and second sample channel inlet, and a sample channel outlet; and a second layer, coupled to the first layer, the second layer comprising a thermoelectric sensor located under each of the first and second passive mixers and configured to measure a temperature differential therebetween, wherein each of the first and second passive mixers comprises a micromixer and is configured for three dimensional mixing of a solution, or/and a splitting-and-recombination mixer, wherein each of the first and second passive mixers comprises a first set of channels in a first horizontal plane and a second set of channels in a second horizontal plane. 11. The microdevice of claim 10 , wherein the thermoelectric sensor comprises a thermopile. 12. The microdevice of claim 10 , further comprising a substrate layer coupled to the second layer. 13. The microdevice of claim 12 , wherein the substrate layer comprises Kapton film. 14. A method of determining a thermal property of an analyte, comprising: providing a microdevice comprising: a reference channel comprising a first passive mixer; a sample channel comprising a second passive mixer; and a thermoelectric sensor located under each of the first and second passive mixers and configured to measure a temperature differential between the first and second passive mixers, wherein each of the first and second passive mixers comprises a micromixer and is configured for three dimensional mixing of a solution, introducing a sample material and a second substance into the sample channel; introducing the sample material and a buffer into the reference channel; and determining a thermal property of the reaction between the sample material and the second substance based on the measured temperature differential between the sample channel and the reference channel. 15. The method of claim 14 , wherein providing the microdevice comprises providing a microdevice wherein the first and second passive mixers comprise splitting-and-recombination micromixers. 16. A method of determining a thermal property of an analyte, comprising: providing a microdevice comprising: a reference channel comprising a first passive mixer; a sample channel comprising a second passive mixer; and a thermoelectric sensor located under each of the first and second passive mixers and configured to measure a temperature differential between the first and second passive mixers, and further wherein each of the first and second passive mixers is configured for three dimensional mixing of a solution, introducing a sample material and a second substance into the sample channel; introducing the sample material and a buffer into the reference channel; and determining the heat involved in the reaction between the sample material and the second substance based on the measured temperature differential between the sample channel and the reference channel. 17. The method of claim 16 , wherein providing the microdevice comprises providing a microdevice wherein the first and second passive mixers comprise splitting-and-recombination micromixers. 18. A microdevice for calorimetric measurement comprising: a reference channel comprising a first passive mixer; a sample channel comprising a second passive mixer; and a thermoelectric sensor located under each of the first and second passive mixers and configured to measure a temperature differential therebetween, wherein the reference channel comprises a 3D diffusive titration channel, wherein the sample channel comprises a 3D diffusive titration channel, wherein each of the first and second passive mixers comprises a micromixer and is configured for three dimensional mixing of a solution, wherein each of the first and second passive mixers comprises a first set of channels in a first horizontal plane and a second set of channels in a second horizontal plane, wherein each of the first and second passive mixers are formed by a top layer and a bottom layer, and further wherein each of the first and second passive mixers comprise a first set of channels in the top layer and a second set of channels in the bottom layer. 19. The microdevice of claim 18 , wherein the thermoelectric sensor comprises a thermopile. 20. The microdevice of claim 18 , further comprising a substrate layer beneath the thermopile. 21. The microdevice of claim 20 , wherein the substrate layer comprises Kapton film. 22. The microdevice of claim 18 , wherein the microdevice comprises a pol