Disclosed herein are methods for tracking solutions, (e.g., reaction conditions in solutions). In some embodiments, the method comprises: contacting a first lanthanide-chelator complex to a first solution to generate a first barcoded solution, wherein the first lanthanide-chelator complex comprises a first lanthanide chelated by a first chelator; contacting a second lanthanide-chelator complex to a second solution to generate a second barcoded solution, wherein the second lanthanide-chelator complex comprises a second lanthanide chelated by a second chelator; mixing the first barcoded solution and the second barcoded solution to form one or more mixtures; and identifying the first lanthanide ions in the mass spectrum and the second lanthanide ions in the mass spectrum to track the condition of each of the one or more mixtures.

The invention provides a method for immobilization of biological molecules such as nucleic acids, peptides and proteins onto the surface of a glass or plastic solid support.

Methods of making a supramolecular structure of lipids. The methods include providing an ink made of an aqueous solution of lipid micelles that are deposited onto a polymer pen or an array of polymer pens, such as by an electrospray technique to achieve a homogenous coverage of single and isolated micelles. The method further comprises transferring the ink to a substrate using polymer pen lithography (PPL). Nanoconfinement of the lipid micelles associated with the disclosed method, allow the lipid micelles to rearrange and ultimately lead to a highly ordered and homogenous supramolecular lipid structure. A supramolecular assembly made using the disclosed method and nanoscale delivery system comprising the supramolecular assembly of lipids are further disclosed.

Inventions covered include methods, systems, and compositions for sample processing, involving morphology-adjustable (e.g., tunable on-demand) functionalized particles. In some embodiments, a method can include distributing a set of functionalized particles, in a first morphological state, across a set of partitions; transitioning the set of functionalized particles, at the set of partitions, from the first morphological state to a second morphological state; transitioning the set of functionalized particles, at the set of partitions, from the second morphological state to a third morphological state, and inducing interactions between the set of functionalized particles and a set of targets, within the set of partitions and according to a set of operations with a set of process fluids.

Provided is a method of constructing a sequencing library. The method includes 1) providing a single-stranded DNA fragment from a biological sample; 2) subjecting the single-stranded DNA fragment to whole genomic amplification to obtain a whole genome amplification product; 3) fragmenting the whole genome amplification product using a transposase embedded with two adaptors to obtain a fragmented product with two adaptors respectively at two ends; and 4) amplifying the fragmented product with two adaptors respectively at two ends using a tag sequence and a pair of primers to obtain said sequencing library.

Three-dimensional cellular arrays, methods of making three-dimensional cellular arrays, and methods of identifying agents using the arrays are disclosed.

Analyte filter arrays and methods for making an analyte filter array are provided. The arrays are formed using a dispersion of filter particles having selected moieties attached to the surface of the particles and a microarray having complementary moieties formed in an array on a substrate, such that each filter particle is attached to a selected region of the microarray. The moiety on the substrate may be RNA or DNA or other molecule. The substrate may be a surface of a detector array, a membrane that may be placed in registration with the detector array or a stamp used to transfer the filter array to a detector array.

Compositions, systems, and methods for the display of analytes such as biomolecules are described. Display of analytes is achieved by coupling of the analytes to displaying molecules that are configured to associate with surfaces or interfaces. Arrays of analytes may be formed from the described systems for utilization in assays and other methods.

This disclosure provides methods and compositions for long fragment read sequencing. Technology is described for preparing long fragments of genomic DNA, for processing genomic DNA for long fragment read sequencing methods, as well as software and algorithms for processing and analyzing sequence data. Combinatorial oligonucleotide bar codes are used to label fragments from nearby portions of the genome, which facilitate computational assembly of sequence reads to obtain the genome sequence. This improves efficiency and accuracy of sequencing, whereby an entire sequence can be obtained from fragments that constitute a lower coverage amount of the genome.

Acid gas compounds are removed from a process gas such as, for example, syngas or natural gas, by flowing a feed gas into a desulfurization unit to remove a substantial fraction of sulfur compounds from the feed gas and flowing the resulting desulfurized gas into a CO.sub.2 removal unit to remove a substantial fraction of CO.sub.2 from the desulfurized gas.