Multiplexed sweat extraction and sensing wearable device for normalized and time-sequential sweat analysis

What is claimed is: 1 . A wearable device for sweat analysis, comprising: a sensing module including multiple compartments, including: a first compartment configured to induce sweat and sense a first level of a target analyte in the sweat induced by the first compartment; and a second compartment configured to induce sweat and sense a second level of the target analyte in the sweat induced by the second compartment; a current source respectively coupled to provide current to the first and second compartments; a signal conditioner coupled between the current source and the first and second compartments, wherein the signal conditioner is configured to condition the current from the current source so as to provide first and second respective different currents to the first and second compartments in accordance with first and second respective different sweat secretion rates; and a processor configured to derive a measurement of a blood level of the target analyte from multiple sweat measurements comprising multiple ones of the sensed first and second levels of the target analyte obtained from the first and second compartments, wherein the processor is configured to derive the blood level of the target analyte from the multiple sweat measurements of the target analyte using a model of a relationship between the blood level of the target analyte and a sweat level of the target analyte under a plurality of sweat induction conditions. 2 . The wearable device of claim 1 , wherein: the first compartment includes: a first pair of iontophoresis electrodes and a first secretory agonist-containing hydrogel layer adjacent to the first pair of iontophoresis electrodes; and a first sensor configured to sense the target analyte. 3 . The wearable device of claim 2 , wherein the first compartment further includes a first calibration sensor. 4 . The wearable device of claim 3 , wherein: the second compartment includes: a second pair of iontophoresis electrodes and a second secretory agonist-containing hydrogel layer adjacent to the second pair of iontophoresis electrodes; and a second sensor configured to sense the target analyte. 5 . The wearable device of claim 4 , wherein the second compartment further includes a second calibration sensor. 6 . The wearable device of claim 5 , further comprising: the processor connected to the compartments to direct multiplexed operation of the compartments. 7 . The wearable device of claim 6 , wherein the processor is configured to concurrently activate multiple ones of the compartments under respective and different sweat induction conditions. 8 . The wearable device of claim 7 , wherein the processor is configured to derive the multiple measurements of a sweat level of the target analyte from sensing signals of the concurrently activated compartments under the different conditions, and to derive a normalized measurement of the blood level of the target analyte from the multiple measurements of the sweat level of the target analyte. 9 . The wearable device of claim 6 , wherein the processor is configured to sequentially activate the compartments over time. 10 . The wearable device of claim 9 , wherein the processor is configured to derive a time profile of the target analyte. 11 . A wearable device for sweat analysis, comprising: a first sensing region including a first pair of iontophoresis electrodes and a first secretory agonist-containing hydrogel layer adjacent to the first pair of iontophoresis electrodes; and a first sensor configured to sense a first level of a target analyte in sweat induced in the first sensing region; a second sensing region including a second pair of iontophoresis electrodes and a second secretory agonist-containing hydrogel layer adjacent to the second pair of iontophoresis electrodes; and a second sensor configured to sense a second level of the target analyte in sweat induced in the second sensing region; a current source respectively coupled to provide current to the first and second sensing regions; a signal conditioner coupled between the current source and the first and second sensing regions, wherein the signal conditioner is configured to condition the current from the current source so as to provide first and second different currents to the first and second sensing regions in accordance with respective first and second different sweat secretion rates; and a processor connected to the first sensing region and the second sensing region, wherein the processor is configured to derive a measurement of a blood level of the target analyte from multiple sweat measurements comprising multiple ones of the sensed first and second levels of the target analyte obtained from the first and second sensing regions, wherein the processor is configured to derive the blood level of the target analyte from the multiple sweat measurements of the target analyte using a model of a relationship between the blood level of the target analyte and a sweat level of the target analyte under a plurality of sweat induction conditions. 12 . The wearable device of claim 11 , wherein the processor is configured to activate the first sensing region and the second sensing region under respective and different sweat induction conditions. 13 . The wearable device of claim 12 , wherein the processor is configured to derive the multiple measurements of a sweat level of the target analyte from sensing signals of the first sensing region and the second sensing region under the different conditions, and to derive a normalized measurement of the blood level of the target analyte from the multiple measurements of the sweat level of the target analyte. 14 . The wearable device of claim 11 , wherein the processor is configured to sequentially activate the first sensing region and the second sensing region over time. 15 . The wearable device of claim 14 , wherein the processor is configured to derive a time profile of the target analyte. 16 . The wearable device of claim 1 , wherein the current source and signal conditioner are configured to cause the first and second respective different currents to be concurrently provided to the first and second compartments. 17 . The wearable device of claim 11 , wherein the current source and signal conditioner are configured to cause the first and second respective different currents to be concurrently provided to the first and second sensing regions. 18 . The wearable device of claim 16 , wherein the first and second different currents are adjusted to normalize sweat secretion for the first and second compartments according to first and second different sweat induction conditions concurrently associated with the first and second compartments. 19 . The wearable device of claim 1 , wherein the model is a linear model.