Abstract: Described herein are devices, systems, and methods for trapping single-cell lysates in sealed, microwells capable of printing RNA on glass or capturing RNA on beads. These provide efficient, inexpensive manipulation of RNA from individual cells suitable for single-cell transcriptomics on a large scale. Also described are dual barcode capture beads and merged barcode capture beads.

Abstract: Many important biological questions demand single-cell transcriptions on a large scale. Hence, new tools are urgently needed for efficient, inexpensive manipulation of RNA from individual cells. Described herein are devices, systems and methods for trapping single-cell lysates in sealed, microwells capable of priming RNA on glass or capturing RNA on beads.

Abstract: Compositions and methods useful for treating and/or preventing a Zika virus infection are provided.

Abstract: Described herein are devices, systems, and methods for trapping single-cell lysates in sealed, microwells capable of printing RNA on glass or capturing RNA on beads. These provide efficient, inexpensive manipulation of RNA from individual cells suitable for single-cell transcriptomics on a large scale. Also described are dual barcode capture beads and merged barcode capture beads.

Abstract: Compositions and methods useful for treating and/or preventing a Zika virus infection are provided.

Abstract: An RFID antenna or tag is designed to be integrated with artwork such as a logo, brand name, trademark, graphic element, and/or letters. The RFID tag comprises a substrate, which may include or be integrated with a product package. An antenna is formed on the substrate. The antenna includes first and second conductive traces that are integrated with artwork. An integrated circuit is connected across the first and second conductive traces. The conductive traces are integrated with the artwork that is printed on or otherwise integrated with the substrate. At least one of a size, location, and/or gaps between said conductive traces are tuned based on at least on of impedance and radiation pattern thereof.

Abstract: An RFID antenna or tag is designed to be integrated with artwork such as a logo, brand name, trademark, graphic element, and/or letters. The RFID tag comprises a substrate, which may include or be integrated with a product package. An antenna is formed on the substrate. Non-conductive artwork is printed on the substrate. The antenna includes first and second conductive traces that are integrated with artwork. An integrated circuit is connected across the first and second conductive traces. The conductive traces are integrated with the artwork that is printed on or otherwise integrated with the substrate. At least one of a size, location, and/or gaps between said conductive traces are tuned based on at least on of impedance and radiation pattern thereof.