Reflectance based pulse oximetry systems and methods

The invention claimed is: 1. A pulse oximeter device, comprising: an array of first light emitting elements configured to emit red light, wherein each first light emitting element in the array of first light emitting elements comprises a first printed organic light emitting diode (OLED); an array of second light emitting elements configured to emit green light or infrared light, wherein each second light emitting element in the array of second light emitting elements comprises a second printed OLED; an array of sensor elements configured to detect red and green light or red and infrared light and output signals representing detected red and green light or detected red and infrared light, wherein each sensor element in the array of sensor elements comprises a printed organic photodiode; and a flexible substrate, wherein the array of first light emitting elements, the array of second light emitting elements and the array of sensor elements are printed on the flexible substrate. 2. The pulse oximeter device of claim 1 , wherein the flexible substrate comprises polyethylene napthalate (PEN). 3. The pulse oximeter device of claim 1 , wherein each sensor element is configured to detect the emitted red and green light or the emitted red and infrared light transmitted through tissue containing blood. 4. The pulse oximeter device of claim 1 , wherein each sensor element is configured to detect the emitted red and green light or the emitted red and infrared light reflected by tissue containing blood. 5. The pulse oximeter device of claim 1 , further comprising a signal processing element configured to receive and process the signals representing detected red and green light or detected red and infrared light output by the array of sensor elements to produce signals that represent blood oxygenation content. 6. A pulse oximeter device, comprising: a plurality of first light emitting elements configured to emit red light, wherein each first light emitting element of the plurality of first light emitting elements comprises a first printed organic light emitting diode (OLED); a plurality of second light emitting elements configured to emit green light or infrared light, wherein each second light emitting element of the plurality of second light emitting elements comprises a second printed OLED; a plurality of sensor elements configured to detect red and green light or red and infrared light and output signals representing detected red and green light or detected red and infrared light, wherein each sensor element in the plurality of sensor elements comprises a printed organic photodiode; and a flexible substrate, wherein the first light emitting elements, the second light emitting elements and the sensor elements are printed on the flexible substrate. 7. The pulse oximeter device of claim 6 , wherein the flexible substrate comprises polyethylene napthalate (PEN). 8. The pulse oximeter device of claim 6 , wherein the sensor elements are configured to detect the emitted red and green light or the emitted red and infrared light transmitted through tissue containing blood. 9. The pulse oximeter device of claim 6 , wherein the sensor elements are configured to detect the emitted red and green light or the emitted red and infrared light reflected by tissue containing blood. 10. The pulse oximeter device of claim 6 , further comprising a signal processing element configured to receive and process the signals representing detected red and green light or detected red and infrared light output by the sensor elements to produce signals representing blood oxygenation content. 11. A method of measuring blood oxygenation content of a tissue sample, the method comprising: applying a flexible pulse oximeter device proximal the tissue sample, the flexible pulse oximeter device including: a flexible substrate; at least one first printed light emitting element formed on the flexible substrate and configured to emit red light; at least one second printed light emitting element formed on the flexible substrate and configured to emit green light or infrared light; and at least one printed sensor element formed on the flexible substrate and configured to detect red and green light or red and infrared light and output signals representing detected red and green light or detected red and infrared light; activating the at least one first printed light emitting element and the at least one second printed light emitting element; detecting red and green light or red and infrared light reflected by the tissue sample by the at least one printed sensor element; and outputting signals representing the detected reflected red and green light or the detected red and infrared light to a signal processing device. 12. The method of claim 11 , wherein each of the at least one first printed light emitting element and the at least one second printed light emitting element comprises an organic LED, and wherein the at least one printed sensor element comprises an organic photodiode. 13. A method of mapping blood oxygenation content of a region of a tissue sample, the method comprising: a) applying a flexible pulse oximeter device proximal the tissue sample, the flexible pulse oximeter device including: a flexible substrate; an array of first light emitting elements formed on the flexible substrate configured to emit red light; an array of second light emitting elements formed on the flexible substrate configured to emit green light or infrared light; and an array of sensor elements formed on the flexible substrate that detects red and green light or that detects red and infrared light and that outputs signals representing detected red and green light or detected red and infrared light; b) activating a first portion of the array of first light emitting elements and a first portion of the array of second light emitting elements; c) detecting red and green light or red and infrared light reflected by the tissue sample by a first sensor element; and d) outputting, by the first sensor element, signals representing the detected reflected red and green light or the detected reflected red and infrared light to a signal processing device; e) activating a second portion of the array of first light emitting elements, and a second portion of the array of second light emitting elements; f) detecting red and green light or red and infrared light reflected by the tissue sample by a second sensor element; and g) outputting, by the second sensor element, signals representing the detected reflected red and green light or the detected reflected red and infrared light to a signal processing device; and h) processing the signals output by the first sensor element and the second sensor element to determine blood circulation and oxygenation content for different areas of the region of the tissue sample. 14. The method of claim 13 , wherein the steps e)-g) are performed after steps b)-d). 15. The method of claim 13 , wherein the steps e)-g) are performed simultaneously with steps b)-d). 16. The method of claim 13 , wherein each first light emitting element of the array of the first light emitting elements and each second light emitting the array of second light emitting elements comprises an organic LED, and wherein each sensor element of the array of sensor elements comprises an organic photodiode. 17. The method of claim 13 , wherein each first light emitting element of the array of the first light emitting elements and each second light emitting element of the array of second light emitting elements comprises a printed organic