A differentially coated device for conducting a plurality of nano-volume specified reactions, the device comprising a platen having at least one exterior surface modified to a specified physicochemical property, a plurality of nano-volume channels, each nanovolume channel having at least one interior surface in communication with the at least one exterior surface. Methods for preparing and using such devices are also provided, as well as a method of registering a location of a dispenser array in relation to a microfluidic array. Quantities related to a vector displacement from the alignment position to a fixed position on the one of the dispenser array and the microfluidic array is determined. The quantities thus determined are used to guide positioning of the dispenser array relative to the microfluidic array.

A kit includes a microfabricated device having a top surface defining an array of microwells for receiving a sample comprising at least one cell, and a membrane for applying on the top surface of the microfabricated device to retain the at least one cell in at least one microwell of the array of microwells after the sample is loaded on the microfabricated device.

A method of screening for at least one biological entity of interest using a microfabricated device which has a top surface defining an array of microwells. A sample is loaded onto the microfabricated device such that at least one microwell of the array of microwells includes at least one cell and an amount of a nutrient. A membrane is applied to the microfabricated device to retain the at least one cell and the nutrient. A plurality of cells are cultured from the at least one cell in the at least one microwell of the array of microwells. The plurality of cells is then analyzed to determine a presence or absence of a biological entity of interest.

A method of screening for at least one biological entity of interest using a microfabricated device which has a top surface defining an array of microwells. A sample is loaded onto the microfabricated device such that at least one microwell of the array of microwells includes at least one cell and an amount of a nutrient. A membrane is applied to the microfabricated device to retain the at least one cell and the nutrient. A plurality of cells is cultured from the at least one cell in the at least one microwell of the array of microwells. The plurality of cells in the at least one microwell of the array of microwells are split into a first portion of the plurality of cells and a second portion of the plurality of cells. The plurality of cells is analyzed to determine a presence or absence of a biological entity of interest.

Provided herein is generally tubular container, preferably including a plurality of reservoirs defined therein. The container can be adapted for acoustic ejection of a fluid disposed within at least one of the reservoirs of the plurality of reservoirs. Alternatively, the container can be adapted for extraction of a fluid disposed within at least one of the reservoirs of the plurality of reservoirs using a non-acoustic liquid handling method.

A method for manufacturing a three-dimensional object comprises the steps of (a) bringing at least one nozzle in a first position close to a surface of a substrate, (b) delivering through said at least one nozzle at least one reactant to said surface, (c) effecting a solid forming reaction of said at least one delivered reactant such that said at least one delivered reactant undergoes a transition to become a growing solid deposit on said surface under said at least one nozzle, and (d) detecting an interaction of said growing solid deposit with said at least one nozzle.

A microfabricated device defining a high density array of microwells is described for cultivating cells from a sample. The device may be incubated to grow a plurality of cells, which may be split into an analysis portion and a reserve portion. Methods are provided for screening a biological entity of interest using the microfabricated device, for example, for screening phosphate solubilizing bacteria or other bacteria producing acids.

An interface is provided for storing microfluidic samples in a nanoliter sample chip. A fluid access structure provides a fluid access region to a selected subset of sample wells from an array of sample wells. A fluid introduction mechanism introduces a sample fluid to the fluid access region so that the sample wells in the selected subset are populated with the sample fluid without the unselected sample wells being populated with the sample fluid.

Provided herein is generally tubular container, preferably including a plurality of reservoirs defined therein. The container can be adapted for acoustic ejection of a fluid disposed within at least one of the reservoirs of the plurality of reservoirs. Alternatively, the container can be adapted for extraction of a fluid disposed within at least one of the reservoirs of the plurality of reservoirs using a non-acoustic liquid handling method.

A microfabricated device defining a high density array of microwells is described for cultivating cells from a sample. A series of unique tags may be disposed in the microwells to identify one or more species of cells and locate the particular microwells in which each species was cultivated. A unique tag may be a nucleic acid molecule including a target-specific nucleotide sequence for annealing to a target nucleic acid fragment and a location-specific nucleotide sequence predetermined to identify one or more microwells. The device may be incubated to grow a plurality of cells, which may be split into an analysis portion and a reserve portion. High throughput methods are described for cultivating, screening, and determining a relative and/or absolute abundance of cells from a sample.