Palm-size μNMR relaxometer using a digital microfluidic (DMF) device and a semiconductor transceiver for chemical/biological diagnosis

What is claimed is: 1. A portable μNMR relaxometer system for performing multi-step multi-sample chemical/biological assays, comprising: a printed circuit board (PCB) having a CMOS μNMR transceiver, a Butterfly coil, and a Digital Microfluidic (DMF) device integrated thereon; and a portable magnet generating a static magnetic field, wherein the portable magnet comprises a housing that surrounds the portable magnet, wherein the housing of the portable magnet within a body of the portable magnet comprises an inner gap from one side of the housing to an opposite side of the housing that is configured to at least partially receive the DMF device such that sensing would be performed within the housing of the portable magnet, wherein the DMF device comprises a platform of electrodes using electro-wetting-on-dielectric (EWOD) effects, the platform including a sensing site and having top and bottom planes for squeezing a sample, wherein the DMF device is configured to receive one or more samples for analysis at an electrode on the platform and automatically transport the one or more samples on individual paths sequentially to the sensing site, for performing sensing on each sample sequentially, wherein the CMOS μNMR transceiver comprises an μNMR circuit that interfaces with the Butterfly coil, the Butterfly coil being disposed on the PCB and directly underneath the DMF device and being at least partially received in the inner gap of the portable magnet, the Butterfly coil generating a surface-parallel RF magnetic field that is parallel to a surface of the PCB and is orthogonal to the static magnetic field generated by the portable magnet for exciting the sample at the μNMR sensing site by transducing a magnetic field produced at the sensing site to an electrical signal which is processed by the CMOS μNMR transceiver to produce an analytical signal. 2. The system of claim 1 , wherein the DMF device further comprises a capacitance-to-digital module having a memory and processor configured to automatically determine whether a droplet is located on an electrode of the platform by: counting a number of pulses on each electrode; comparing the number of pulses counted on each electrode; and determining that an electrode having a low number of pulses relative to a high number of pulses at another electrode has a droplet located thereon. 3. The system of claim 1 , wherein the platform of the DMF device comprises: the top plane, composed of glass and being coated with the electrodes, the electrodes being comprised of Chromium; a Ta 2 O 5 layer underneath the electrodes; a Parylene-C layer underneath the Ta 2 O 5 layer; a first Teflon layer under the Parylene-C layer; a space for holding the samples which are surrounded on each end by Silicone oil; a second Teflon layer underneath the space for holding the samples; an ITO layer underneath the second Teflon layer; and the bottom plane, composed of glass and disposed underneath the ITO layer. 4. The system of claim 1 , further comprising: a DMF circuit, configured to control the platform of electrodes of the DMF device; a field-programmable gate array (FPGA), configured to transmit commands to the CMOS μNMR transceiver and control the DMF circuit; and a signal generator, configured to provide an LO ref signal for input to the CMOS μNMR transceiver. 5. The system of claim 4 , wherein the DMF device further comprises a samples actuator comprising: an input for receiving input power from the FGPA; a boost converter for generating a sufficiently high voltage signal for electrode actuation; an oscillator for generating a square wave; a switch pair for amplifying the square wave; a high pass filter (HPF) to high-pass filter the amplified square wave to remove the DC level for actuating the electrodes of the platform; and a switch array controlled by the FGPA to control an on-off pattern of the electrodes by modulating a driving voltage on an occupied electrode with an on-off duty cycle to actuate movement of the sample. 6. The system of claim 1 , wherein the DMF device is configured to transport the sample from one electrode on the platform to a neighboring electrode by applying a square wave to the neighboring electrode. 7. The system of claim 1 , wherein a Silicone oil shell is applied on the platform of the DMF device to surround the received sample on the platform of electrodes. 8. The system of claim 1 , wherein the samples comprise probe-decorated NP droplets and each sample is mixed with a target prior to being transported sequentially and individually to the sensing site. 9. The system of claim 1 , wherein the DMF device is configured by a software module such that a first sample is screened at the sensing site while a second sample stays on its electrode, and then after the first sample is guided away from the sensing site the second sample is transported to the sensing site for screening. 10. The system of claim 1 , wherein the DMF device is configured by a software module to move a sample onto the sensing site for screening and then away from the sensing site for mixing with a target, and then back to the sensing site for further screening. 11. The system of claim 4 , wherein the signal generator comprises: a temperature sensor to sense an ambient temperature and produce an analog signal relating thereto; an analog-to-digital converter (ADC) for converting the analog signal to a digital signal; a processor for reading the digital signal and calculating a working frequency for the LO ref signal; a digital-to-analog converter for altering the working frequency; and a voltage-controller oscillator to produce the LO ref signal from the working frequency and output the LO ref signal. 12. The system of claim 4 , wherein the CMOS μNMR transceiver further comprises: a transmitter adapted to power the Butterfly coil, comprising: a state control and pulse sequence synthesizer to receive the LO ref signal from the signal generator and read the commands transmitted from the FGPA, and a power amplifier configured to generate CPMG pulse sequences and excite the nuclei of the sample at the sensing site with the CPMG pulses via the Butterfly coil; and a receiver adapted to extract the μNMR signal induced by the Butterfly coil from the protons, comprising: a multi-stage low-noise amplifier (LNA) at a front of the receiver to boost the gain and enhance the signal-to-noise ratio (SNR) of the RF signal, a pair of quadrature mixers configured to downconvert the RF signal to an intermediate frequency (IF) signal for filtering and digitalization, and a dynamic-bandwidth lowpass filter (LPF) configured to process the IF signal to suppress out-of-band noise and high frequencies generated by the mixers. 13. The system of claim 12 , wherein the LPF is a 6 th -order Butterworth filter using source-follower-based topology. 14. The system of claim 5 , further comprising a portable computer, configured to: set μNMR parameters, sample routing, and positioning, display μNMR results, read ambient temperature, control the switch array of the DMF device, display vacancy of the electrodes on the platform, and display results of the micro-NMR sensing in real time. 15. The system of claim 1 , further comprising a pipette configured to receive a sample for analysis and deliver the sample to the DMF device. 16. The system of claim 1 , wherein the transceiver comprises multiple receivers which interface with multiple Butterfly coils, each receiver interfacing with a respective Butterfly coil disposed inside the opening gap of the