A target particle transferring device is disclosed, which comprises: (a) a substrate with a thickness of T and a width of W, having top and bottom portions, the top portion having a top surface and the bottom portion having a bottom surface; (b) a notch structure formed in the bottom portion of the substrate, comprising: a groove with a width of W1, located at a distance oft below the top surface of the substrate, wherein the groove is formed in the bottom portion from the bottom surface extending toward the top portion; and (c) a target substrate portion with a width of W2 and a thickness of T, located in the top and bottom portions of the substrate and being surrounded by the groove. Methods of transferring a target particle from one device to another is also disclosed.

A target particle transferring device is disclosed, which comprises: (a) a substrate with a thickness of T and a width of W, having top and bottom portions, the top portion having a top surface and the bottom portion having a bottom surface; (b) a notch structure formed in the bottom portion of the substrate, comprising: a groove with a width of W1, located at a distance oft below the top surface of the substrate, wherein the groove is formed in the bottom portion from the bottom surface extending toward the top portion; and (c) a target substrate portion with a width of W2 and a thickness of T, located in the top and bottom portions of the substrate and being surrounded by the groove. Methods of transferring a target particle from one device to another is also disclosed.

A microfluidic dual-well device is disclosed. The device comprises: (a) a first substrate having a first end, a second end, and a culture microwell forming portion; (b) a plurality of culture microwells; (c) a second substrate having a first end, a second end, and a capture microwell forming portion, the two ends of the second substrate being respectively bounded to the two ends of the first substrate; (d) a plurality of capture microwells; (e) a microfluidic channel; (f) a microfluidic inlet port; and (g) a microfluidic outlet port; wherein the microfluidic channel is in fluidic connections with the culture microwells, the capture microwells, and the inlet and outlet ports. Methods of capturing and transferring a single cell or a single cell colony for culture, and method of transferring a target cell from a polydimethylsiloxane (PDMS) structure of culture microwells to a culture plate for culture are also disclosed.

A microfluidic dual-well device is disclosed. The device comprises: (a) a first substrate having a first end, a second end, and a culture microwell forming portion; (b) a plurality of culture microwells; (c) a second substrate having a first end, a second end, and a capture microwell forming portion, the two ends of the second substrate being respectively bounded to the two ends of the first substrate; (d) a plurality of capture microwells; (e) a microfluidic channel; (f) a microfluidic inlet port; and (g) a microfluidic outlet port; wherein the microfluidic channel is in fluidic connections with the culture microwells, the capture microwells, and the inlet and outlet ports. Methods of capturing and transferring a single cell or a single cell colony for culture, and method of transferring a target cell from a polydimethylsiloxane (PDMS) structure of culture microwells to a culture plate for culture are also disclosed.