Micro-fluidic mixer and method of determining pathogen inactivation via antimicrobial solutions

What is claimed is: 1. A micro-fluidic sanitizer analysis system comprising: a pathogen inactivation channel comprising: (a) a first Y-injection mixer comprising a first and second inlets; and, (b) at least first and second S-shaped serpentine pathogen inactivation channels having chaotic mixer elements and being connected in series, a first end of the first S-shaped serpentine channel being connected to the first Y-injection mixer; and, a sanitizer deactivation channel operatively connected to the pathogen inactivation channel, the sanitizer deactivation channel comprising: (c) a second Y-injection mixer comprising third and fourth inlets, a second end of the pathogen inactivation serpentine channels comprising the third inlet: and, (d) at least third and fourth sanitizer deactivation S-shaped serpentine channels having chaotic mixer elements and being connected in series, a first end of the sanitizer deactivation S-shaped serpentine channels being connected to the second Y-injection mixer, and a second end of the sanitizer deactivation S-shaped serpentine channels comprising a sanitizer deactivation channel outlet; wherein the micro-fluidic system is configured so that after a produce wash sample is injected into the first or second inlet, the produce wash sample is mixed with a reference bacterial solution component in the first Y-injection mixer, and then directed to the third inlet, and then mixed with a sanitizer deactivating solution component in the second Y-injection mixer, and then the resulting deactivated sanitizer solution is directed out of the sanitizer deactivation channel outlet, the resulting deactivated sanitizer solution then being analyzed. 2. The micro-fluidic system of claim 1 wherein the system is structured so that: the first injection mixer, the first and second S-shaped serpentine pathogen inactivation channels, second Y-injection mixer, and third and fourth sanitizer deactivation S-shaped serpentine channels are all in fluid communication and are connected in series. 3. The micro-fluidic system of claim 1 wherein the system is structured so that the pathogen inactivation channel comprises at least one Dean's mixer. 4. The micro-fluidic system of claim 1 wherein the produce wash sample comprises a chlorine produce wash solution. 5. The micro-fluidic system of claim 1 wherein the reference bacterial solution component comprises E. coli. 6. The micro-fluidic system of claim 1 wherein the system comprises a continuous fluid channel, the pathogen inactivation channel having the same structure as the structure of the sanitizer deactivation channel. 7. The micro-fluidic system of claim 1 wherein the system is structured so that the pathogen inactivation channel comprises at least one Dean's mixer.