Certain embodiments are directed to an ultrasensitive poly(methyl methacrylate) (PMMA) ELISA microfluidic microplate, where the protein is covalently bound to a poly-lysine modified or carboxylated PMMA surface.

An optofluidic diagnostic system and methods for rapid analyte detections. The system comprises an optofluidic sensor array, a test plate and an optical detection cartridge. The sensor array supports one or more distinct sensor units, each having a reactor section designed to temporarily enter a series of different kinds of wells in the test plate. One kind of well is a sample reservoir that holds reagent solution to be transferred into the reactor section. Another kind of well is a drainage chamber that removes reagent solution from the reactor section. A third kind of well is a colorant reservoir that holds a colorant reagent transferable into a reactor section. Finally, the sensor unit is transferred to the optical detection cartridge where it is placed into an isolation booth during the optical detection process so that its flat observation face is stationed in a viewing window opposite an optical detector lens.

The invention relates to a multi-well plate comprising a support, the upper surface of which is at least partially covered with a continuous layer of a hydrogel in contact with the lower surface of a bottomless multi-well plate, the support, the continuous layer, and the bottomless multi-well plate being adhered by means of an adhesive which extends from at least certain portions of the lower surface of the bottomless multi-well plate up to certain portions of the upper surface of the support by passing through the continuous layer of hydrogel, each well of the bottomless multi-well plate being entirely surrounded by the at least certain portions of the lower surface. The application also relates to a method for preparing the multi-well plate and the use thereof for in vitro cell culture.

A substrate is described having a treated contact surface comprising a carbon or silicon compound comprising from 1 to 30 atomic percent oxygen, from 0.1 to 30 atomic percent nitrogen, or both, each as measured by XPS. The treated contact surface has a biomolecule recovery percentage greater than the biomolecule recovery percentage of the surface before treatment according to the method.

The present disclosure provides methods, systems, and compositions for parallel processing of nucleic acid samples. Methods and systems of the present disclosure comprise the use of sample-specific barcode sequences, which facilitate the multiplexing of samples, detection of discrete cell populations within a pooled population, and detection of partitions comprising more than one cell.

The present disclosure relates to compositions and methods for combinatorial assessment of nanoscale droplets, as specifically exemplified by massively parallel assessment of spatially-directed (while agnostic as to precise droplet content) combinations of droplets harboring distinct and independently identifiable microbial types and/or chemical compounds or mixtures. More particularly, the disclosure relates to a platform and methodologies for identifying advantageous (including synergistic, additive, etc.) microbial interactions and/or chemical compound or mixture interactions with microbes in a manner that allows for binary, trinary, etc. combinatorial assessments to be performed across a range of many discrete input types of microbes (e.g., 6-16 or more discrete input microbial types), to an extent capable of approaching comprehensive sampling and measurement of microbial community combinations from a selected panel of microbial inputs, optionally also in the presence of chemical compounds or mixtures (e.g., test compounds or mixtures for antimicrobial effect).

Provided are microfluidic systems and methods for detecting, sorting, and dispensing of low abundance events such as single cells and particles, including a variety of eukaryotic and bacterial cells, for a variety of bioassay applications. The systems and methods described herein, when implemented in whole or in part, will make relevant microfluidic based tools available for a variety of applications in biotechnology including antibody discovery, immuno-therapeutic discovery, high-throughput single cell analysis, target-specific compound screening, and synthetic biology screening.

The present disclosure provides a HTP microbial genomic engineering platform that is computationally driven and integrates molecular biology, automation, and advanced machine learning protocols. This integrative platform utilizes a suite of HTP molecular tool sets to create HTP genetic design libraries, which are derived from, inter alia, scientific insight and iterative pattern recognition. The HTP genomic engineering platform described herein is microbial strain host agnostic and therefore can be implemented across taxa. Furthermore, the disclosed platform can be implemented to modulate or improve any microbial host parameter of interest.

An automated analysis instrument operates to detect inadequate dispensation of a fluidic substance on a tray. The instrument includes an image capturing device to capture an image of at least a portion of the tray including a receptacle portion and a surrounding portion around the receptacle portion. The instrument then identifies the surrounding portion of the at least the portion of the tray in the image, evaluates color components of the image corresponding to the surrounding portion of the at least the portion of the tray, and determines whether the fluidic substance is present on the surrounding portion of the at least the portion of the tray based on at least one of the color components.

A method for treating a solution including nucleic acid, comprising the steps of: arranging the solution on a first surface of a first base material having the first surface, which has a well defined by an electrode and a resist; and after arranging the solution on the first surface of the first base material, pressing the first base material and a second base material, which has a hydrophobic second surface, together so that the second surface of the second base material and the first surface of the first base material face each other.