A sample carrier for assaying can include a plurality of pins having a surface that is capable of picking up at least one substance on the surface. The pins can be arranged such that one or more of the plurality of pins are introduced into a corresponding reaction vessel of a microplate. The sample carrier can be divided into a plurality of modules, with each of the plurality of modules comprising one or more pins of the plurality of pins. Methods of use include placing the sample carrier onto a microplate so that at least the one or more of the plurality of pins extend into the corresponding reaction vessel of the microplate.

Technology for a pillar structure for a biochip is disclosed. The pillar structure for a biochip includes: a substrate portion having a plate structure; an insertion pillar portion formed in one piece with the substrate portion and protruding downward from a lower surface of the substrate portion so as to be inserted into a well; and a compensation pillar portion formed in one piece with the substrate portion, the compensation pillar portion corresponding to the insertion pillar portion and protruding upward from an upper surface of the substrate portion. Therefore, when the pillar structure is cooled during an injection molding process, the substrate portion is prevented from being partially recessed, and when samples are analyzed using microscopic images, accuracy and reliability may be improved.

Technology for a biochip pillar structure is disclosed. According to an embodiment of the present disclosure, the biochip pillar structure includes: a pillar structure including a plate-shaped first substrate portion, and pillar portions protruding from a surface of the first substrate portion; and a well structure including a plate-shaped second substrate portion, and well portions formed in a surface of the second substrate portion and having a predetermined depth to respectively receive the pillar portions of the pillar structure, wherein the well portions have a diameter within a range of 800 m to 1500 m, and the pillar portions configured to be inserted into the well portions have a diameter of which the ratio to the diameter of the well portions ranges from 0.3 to 0.58, thereby providing a high-density biochip and preventing bubbling in an aqueous liquid contained in the well portions when the pillar portions are inserted.

A sample carrier for assaying can include a plurality of pins having a surface that is capable of picking up at least one substance on the surface. The pins can be arranged such that one or more of the plurality of pins are introduced into a corresponding reaction vessel of a microplate. The sample carrier can be divided into a plurality of modules, with each of the plurality of modules comprising one or more pins of the plurality of pins. Methods of use include placing the sample carrier onto a microplate so that at least the one or more of the plurality of pins extend into the corresponding reaction vessel of the microplate.

The present disclosure provides methods, device, and system for wafer processing. The wafer processing apparatus uses a nozzle in a lid to disperse a solution to the surface of a wafer. Further, the wafer is positioned on top of a vacuum chuck and does not spin while the solution is dispensed over the surface of the wafer via surface tension, thereby permitting the first solution to react with a reagent on the surface. Further, when dispensing the first solution, a separation gap between the lid and the wafer is at a predetermined distance, for example, from about 20 ?m to about 2 mm.

Technology for a pillar structure for a biochip is disclosed. The pillar structure for a biochip includes: a substrate portion having a plate structure; an insertion pillar portion formed in one piece with the substrate portion and protruding downward from a lower surface of the substrate portion so as to be inserted into a well; and a compensation pillar portion formed in one piece with the substrate portion, the compensation pillar portion corresponding to the insertion pillar portion and protruding upward from an upper surface of the substrate portion. Therefore, when the pillar structure is cooled during an injection molding process, the substrate portion is prevented from being partially recessed, and when samples are analyzed using microscopic images, accuracy and reliability may be improved.

Technology for a biochip pillar structure is disclosed. According to an embodiment of the present disclosure, the biochip pillar structure includes: a pillar structure including a plate-shaped first substrate portion, and pillar portions protruding from a surface of the first substrate portion; and a well structure including a plate-shaped second substrate portion, and well portions formed in a surface of the second substrate portion and having a predetermined depth to respectively receive the pillar portions of the pillar structure, wherein the well portions have a diameter within a range of 800 m to 1500 m, and the pillar portions configured to be inserted into the well portions have a diameter of which the ratio to the diameter of the well portions ranges from 0.3 to 0.58, thereby providing a high-density biochip and preventing bubbling in an aqueous liquid contained in the well portions when the pillar portions are inserted.