A method is provided for analyzing a sample including a population of biological entities using at least one microfabricated device. A plurality of the microwells on the microfabricated device are each uniquely indexed, and loaded with a sample such that at least some microwells each include more than one cell of a biological entity. The microfabricated device was incubated at predetermined conditions, and a selected genetic material of the cells of the biological entities obtained from the incubation is amplified to obtaining amplicons. An aggregate of the amplicons are sequenced obtain sequencing data, based on which and the indexing of the microwells, an identification of the biological entities present in each of the plurality of microwells is obtained. Such identification can then be used to determine a relationship between different types of biological entities in the sample.

A method is provided for analyzing a sample including a population of biological entities using at least one microfabricated device. A plurality of the microwells on the microfabricated device are each uniquely indexed, and loaded with a sample such that at least some microwells each include more than one cell of a biological entity. The microfabricated device was incubated at predetermined conditions, and a selected genetic material of the cells of the biological entities obtained from the incubation is amplified to obtaining amplicons. An aggregate of the amplicons are sequenced obtain sequencing data, based on which and the indexing of the microwells, an identification of the biological entities present in each of the plurality of microwells is obtained. Such identification can then be used to determine a relationship between different types of biological entities in the sample.

A picking instrument for picking biological samples, such as microbial samples, includes a picking pin having a distal tip and three degrees-of-freedom and configured to move in x, y, and z directions. The picking instrument also includes a loading platform comprising a first area and a second area, the first area configured to accommodate and secure a microfabricated chip including a plurality of microwells. The picking pin is programmatically controlled to pick a sample contained in one or more selected microwells of the microfabricated chip and then transfer the sample to a predetermined location at the destination sample holder. Methods of operating the picking instrument, including calibrating the coordinates of the selected microwell(s) relative to a location of the picking pin, are also provided.

A picking instrument for picking biological samples, such as microbial samples, includes a picking pin having a distal tip and three degrees-of-freedom and configured to move in x, y, and z directions. The picking instrument also includes a loading platform comprising a first area and a second area, the first area configured to accommodate and secure a microfabricated chip including a plurality of microwells. The picking pin is programmatically controlled to pick a sample contained in one or more selected microwells of the microfabricated chip and then transfer the sample to a predetermined location at the destination sample holder. Methods of operating the picking instrument, including calibrating the coordinates of the selected microwell(s) relative to a location of the picking pin, are also provided.

A method of transferring material from a first microfabricated device to a second microfabricated device. At least one magnetic bead is loaded into at least one microwell of the first microfabricated device, where a plurality of cells are cultivated. The second microfabricated device is positioned such that the at least one microwell of the first array of microwells is aligned with at least one microwell of the second array of microwells. A magnetic field is applied so as to move the at least one magnetic bead contained in the at least one microwell of the first microfabricated device into the at least one microwell of the second microfabricated device. In this manner, at least one cell from the plurality of cells in the at least one microwell of the first microfabricated device is transferred to the at least one microwell of the second microfabricated device.

A method of transferring material from a first microfabricated device to a second microfabricated device. At least one magnetic bead is loaded into at least one microwell of the first microfabricated device, where a plurality of cells are cultivated. The second microfabricated device is positioned such that the at least one microwell of the first array of microwells is aligned with at least one microwell of the second array of microwells. A magnetic field is applied so as to move the at least one magnetic bead contained in the at least one microwell of the first microfabricated device into the at least one microwell of the second microfabricated device. In this manner, at least one cell from the plurality of cells in the at least one microwell of the first microfabricated device is transferred to the at least one microwell of the second microfabricated device.

A picking instrument for picking biological samples, such as microbial samples, includes a picking pin having a distal tip and three degrees-of-freedom and configured to move in x, y, and z directions. The picking instrument also includes a loading platform comprising a first area and a second area, the first area configured to accommodate and secure a microfabricated chip including a plurality of microwells. The picking pin is programmatically controlled to pick a sample contained in one or more selected microwells of the microfabricated chip and then transfer the sample to a predetermined location at the destination sample holder. Methods of operating the picking instrument, including calibrating the coordinates of the selected microwell(s) relative to a location of the picking pin, are also provided.

A picking instrument for picking biological samples, such as microbial samples, includes a picking pin having a distal tip and three degrees-of-freedom and configured to move in x, y, and z directions. The picking instrument also includes a loading platform comprising a first area and a second area, the first area configured to accommodate and secure a microfabricated chip including a plurality of microwells. The picking pin is programmatically controlled to pick a sample contained in one or more selected microwells of the microfabricated chip and then transfer the sample to a predetermined location at the destination sample holder. Methods of operating the picking instrument, including calibrating the coordinates of the selected microwell(s) relative to a location of the picking pin, are also provided.

Methods and systems for ordering assays which detect SNPs or gene expression are provided. The methods use PCR and RT-PCR procedures. Collections of stock assays are assembled using pre- and post-manufacturing quality control procedures and made available to consumers via the Internet. In addition, custom assays are prepared upon order from the consumer and these assays are also prepared using pre- and post-manufacturing quality control procedures. The assays are then delivered to the consumer.

Methods and systems for ordering assays which detect SNPs or gene expression are provided. The methods use PCR and RT-PCR procedures. Collections of stock assays are assembled using pre- and post-manufacturing quality control procedures and made available to consumers via the Internet. In addition, custom assays are prepared upon order from the consumer and these assays are also prepared using pre- and post-manufacturing quality control procedures. The assays are then delivered to the consumer.