Abstract: A method of manipulating droplet in a programmable EWOD microelectrode array comprising multiple microelectrodes, comprising: constructing a bottom plate with multiple microelectrodes on a top surface of a substrate covered by a dielectric layer; the microelectrode coupled to at least one grounding elements of a grounding mechanism, a hydrophobic layer on the top of the dielectric layer and the grounding elements; manipulating the multiple microelectrodes to configure a group of configured-electrodes to generate microfluidic components and layouts with selected shapes and sizes, comprising: a first configured-electrode with multiple microelectrodes arranged in array, and at least one second adjacent configured-electrode adjacent to the first configured-electrode, the droplet disposed on the top of the first configured-electrode and overlapped with a portion of the second adjacent-configured-electrode; and manipulating one or more droplets among multiple configured-electrodes by sequentially activating and de-

Abstract: Disclosed herein is a device A device of the microelectrode array architecture, comprising: (a) a bottom plate comprising an array of multiple microelectrodes disposed on a top surface of a substrate covered by a dielectric layer; wherein each of the microelectrode is coupled to at least one grounding elements of a grounding mechanism, wherein a hydrophobic layer is disposed on the top of the dielectric layer and the grounding elements to make hydrophobic surfaces with the droplets; (b) a field programmability mechanism for programming a group of configured-electrodes to generate microfluidic components and layouts with selected shapes and sizes; and, (c) a system management unit, comprising: (i) a droplet manipulation unit; and (ii) a system control unit.

Abstract: A surgical kit comprising a suture retriever comprising a handle element coupling with an extending element, wherein the extending element is coupled with a hook portion; wherein the hook portion comprises a spiral structure and a suture collector comprising suture collecting elements forming one or more slits configured to receive a suture from the suture retriever and a base coupling both sides of the suture collecting elements.

Abstract: The system relates to filed-programmable lab-on-chip (FPLOC) microfluidic operations, fabrications, and programming based on Microelectrode Array Architecture are disclosed herein. The FPLOC device by employing the microelectrode array architecture may include the following: (a) a bottom plate comprising an array of multiple microelectrodes disposed on a top surface of a substrate covered by a dielectric layer; wherein each of the microelectrode is coupled to at least one grounding elements of a grounding mechanism, wherein a hydrophobic layer is disposed on the top of the dielectric layer and the grounding elements to make hydrophobic surfaces with the droplets; (b) a field programmability mechanism for programming a group of configured-electrodes to generate microfluidic components and layouts with selected shapes and sizes; and, (c) a FPLOC functional block, comprising: (i) I/O ports; (ii) a sample preparation unit; (iii) a droplet manipulation unit; (iv) a detection unit; and (iv) a system control unit.

Abstract: The system relates to filed-programmable lab-on-chip (FPLOC) microfluidic operations, fabrications, and programming based on Microelectrode Array Architecture are disclosed herein. The FPLOC device by employing the microelectrode array architecture may include the following: (a) a bottom plate comprising an array of multiple microelectrodes disposed on a top surface of a substrate covered by a dielectric layer; wherein each of the microelectrode is coupled to at least one grounding elements of a grounding mechanism, wherein a hydrophobic layer is disposed on the top of the dielectric layer and the grounding elements to make hydrophobic surfaces with the droplets; (b) a field programmability mechanism for programming a group of configured-electrodes to generate microfluidic components and layouts with selected shapes and sizes; and, (c) a FPLOC functional block, comprising: (i) I/O ports; (ii) a sample preparation unit; (iii) a droplet manipulation unit; (iv) a detection unit; and (iv) a system control unit.

Abstract: Disclosed herein is a device A device of the microelectrode array architecture, comprising: (a) a bottom plate comprising an array of multiple microelectrodes disposed on a top surface of a substrate covered by a dielectric layer; wherein each of the microelectrode is coupled to at least one grounding elements of a grounding mechanism, wherein a hydrophobic layer is disposed on the top of the dielectric layer and the grounding elements to make hydrophobic surfaces with the droplets; (b) a field programmability mechanism for programming a group of configured-electrodes to generate microfluidic components and layouts with selected shapes and sizes; and, (c) a system management unit, comprising: (i) a droplet manipulation unit; and (ii) a system control unit.

Abstract: A method of manipulating droplet in a programmable EWOD microelectrode array comprising multiple microelectrodes, comprising: constructing a bottom plate with multiple microelectrodes on a top surface of a substrate covered by a dielectric layer; the microelectrode coupled to at least one grounding elements of a grounding mechanism, a hydrophobic layer on the top of the dielectric layer and the grounding elements; manipulating the multiple microelectrodes to configure a group of configured-electrodes to generate microfluidic components and layouts with selected shapes and sizes, comprising: a first configured-electrode with multiple microelectrodes arranged in array, and at least one second adjacent configured-electrode adjacent to the first configured-electrode, the droplet disposed on the top of the first configured-electrode and overlapped with a portion of the second adjacent-configured-electrode; and manipulating one or more droplets among multiple configured-electrodes by sequentially activating and de-