Optical detection based on non-linear magnetophoretic transport of magnetic particle for particle and biological sensing and separation

The invention claimed is: 1. An integrated bio-separation and optical detection system for detection of analytes in a sample based on non-linear magnetophoretic separation, the sample being prepared with functionalized superparamagnetic (SPM) particles provided for binding with selected target analytes, the system comprising: a separation chip comprising at least one micro-magnet array comprising a plurality of spaced apart micro-magnets, the at least one micro-magnet array being disposed on a substrate and comprising a capture region, a focusing region, and a detection region; the capture region comprising a plurality of micro-magnets in a rectilinear arrangement; the focusing region comprising a converging micro-magnet array comprising (i) micro-magnets arranged in lines at an angle of 5 to 30 degrees to a major axis and the lines of micro-magnets of the focusing region being substantially parallel while converging to the detection region, or, (ii) micro-magnets arranged in lines in a tree-like structure converging in consecutive steps to the detection region; and the detection region comprising a single row of reflective micro-magnets including a reflective metal defining micro-sized mirrors on the substrate with the substrate having a lower reflectivity compared to the reflectivity of the micro-magnets of the detection region, wherein the micro-magnets comprise one or more of (i) Chromium, and (ii) Cobalt with a layer of Chromium on the Cobalt; a non-linear magnetic (NLM) separator, the NLM separator having external magnets controllable and configured to apply a rotating magnetic field to a surface of the chip to effect separation of the sample provided thereto by non-linear magnetophoresis, wherein the superparamagnetic particles and aggregates thereof are translated over surfaces of the chip, including surfaces of the substrate and the reflective micro-magnets, under an influence of the rotating magnetic field and the field of the fixed micro-magnets of the at least one micro-magnet array, wherein a rotation frequency of the rotating magnetic field applied by the external magnets of the NLM separator is varied during the course of the separation to effect movement, capture, and separation of the SPM particles on the substrate; and characterized in that the system further comprises an integrated optical detector comprising a light source and a detector having a field of view, the light source configured to illuminate a surface of the substrate, and the detector configured to detect light reflected from the substrate at the field of view and configured to generate output signals including an initial light output signal of light reflected from the substrate before the sample is introduced, and to generate separation light output signals of light reflected from the surface of the substrate during the course of the separation, as modulated by SPM particles, aggregates, clusters and target analytes of the sample being translated over the surface of the substrate, such that separation light output signals are representative of the particles, aggregates, clusters and target analytes that are transported through the field of view during the course of the separation, and a data acquisition and processing computer configured to receive as input (i) parameters of the separation including dimensions, number, and optical properties of the SPM particles, and dimensions and optical properties of the aggregates, clusters and target analytes; (ii) the initial light output signal from the detector indicative of properties of the substrate surface, and (iii) the separation light output signals from the detector, the inputs being analyzed by the data acquisition and processing computer to detect a difference between the initial light output signal and the separation light output signals to obtain information about the SPM particles, aggregates, clusters and target analytes of the sample, and to identify presence, number, and concentration of SPM particles, aggregates, clusters and target analytes of the sample. 2. The system of claim 1 wherein the data acquisition and processing computer receives as input the frequency of rotation of the applied magnetic field during the course of the separation. 3. The system of claim 1 wherein the data acquisition and processing computer receives as input details of the at least one micro-magnet array. 4. The system of claim 1 wherein the data acquisition and processing computer receives as an input, an initial output signal of the optical detector based on light interaction with the substrate prior to the sample being introduced to the substrate, and, separation output signals based on light interaction with the substrate during a runtime of the separation. 5. The system of claim 1 wherein the data acquisition and processing computer is configured to analyze a frequency and intensity spectrum of the output signal of the optical detector to differentiate target biological materials attached to the SPM particles in suspension in the sample. 6. The system of claim 1 wherein the light source comprises a monochromatic laser configured to illuminate the at least one micro-magnet array. 7. The system of claim 1 wherein a frequency response of the output signal of the optical detector changes as dimensions of the SPM particles change and optical properties of particles change. 8. The system of claim 1 wherein a frequency response of output signal of the optical detector can also be changed due to different immobility of samples with different proportion of aggregates. 9. The system of claim 1 wherein an intensity of light detected by the optical detector is dependent on micro-magnet array surface properties, fluid, and number of micro-particles P, dimension of particles, and optical properties of the particles. 10. The system of claim 1 , wherein light detected from the micro-magnet array is periodically modulated during the separation by motion of the SPM particles on the at least one micro-magnet array such that output signal of the detector is modulated by motion of the SPM particles on the at least one micro-magnet array by controlling the rotation frequency of rotating magnetic field. 11. The system of claim 1 , wherein the inputs include magnetic properties of the SPM particles and hydrodynamic drag factors and rotation frequency. 12. The system of claim 1 wherein the data acquisition and processing computer is configured to analyze SPM particle differences in dimensions, optical properties, and non-linear magnetophoresis (NLM) transport, wherein mixture of different SPM particles can be detected by opto-non-linear magnetophoresis (ONLM) because frequency response of ONLM is different between different SPM particles. 13. The system of claim 1 wherein the optical detector comprises an optical detector located above the at least one micro-magnet array to detect light reflected from the substrate or from the at least one micro-magnet array. 14. The system of claim 1 wherein the optical detector comprises a photodetector located below the at least one micro-magnet array to detect light transmitted through the substrate or through the at least one micro-magnet array. 15. The system of claim 1 wherein the micro-magnets of the detection region comprise a transparent cover layer comprising a Silicon dioxide or polymer material. 16. The system of claim 1 wherein the at least one micro-magnet array comprises micro-magnets separated by gaps. 17. The system of claim 1 , configured such that when SPM particles move during separation to gaps between adjacent micro-m