A reactor system for conducting multiple continuous reactions in parallel may include a preheating unit that includes an outer preheater shell and a plurality of heating tubes disposed within the preheating shell and arranged in parallel. The reactor system may include a reactor unit downstream of the preheating unit, the reactor unit comprising a plurality of reactor tubes disposed within a reactor shell and an outer heating element disposed about the reactor shell. An inlet end of at least one of the reactor tubes may be fluidly coupled to at least one of the heating tubes of the preheating unit. The reactor unit may include a multi-chamber separator downstream of the reactor unit, the multi-chamber separator having a plurality of separation chambers. At least one of the separation chambers may be fluidly coupled to at least one of the reactor tubes.

The invention refers to a modular continuous flow device for automated chemical multistep synthesis under continuous flow conditions. The device comprises a plurality of different types of continuous flow modules and a valve assembly for connecting the continuous flow modules to each other in a parallel or radial manner. This arrangement allows conducting chemical reaction sequences by pre-synthesizing and intermediately storing or simultaneously synthesizing at least one intermediate product which is needed in the main synthetic reaction sequence in order to obtain the final product.

A fluidic network for carrying out, in parallel, a plurality of analyses of biological samples is disclosed. The network has a flow cell array with a plurality of reaction chambers. The reaction chambers each have a first channel connection and a second channel connection. The first channel connections are connected to a first supply channel and the second channel connections are connected to a second supply channel. The first supply channel and the second channel connection are interconnected by a circulation line. At least one component is connected to the circulation line so that component test reagents can be introduced into the reaction chambers of the flow cell array.

Disclosed is a multi-channel peptide synthesizer, including a gas-bath thermotank, a plurality of reactor tubes, a motor, a rotating rack, a liquid-feeding tube, a feeding device, a vacuum tube and a nitrogen tube. The gas-bath thermotank body provides a desired constant temperature for reaction. The reactor tube provides a place for peptide synthesis and resin washing. The motor and the rotating rack are used to fully mix the reaction and cleaning solutions. Various liquid reagents required are fed to the reactor tube through the liquid-adding tube. Various materials required are prepared in advance in the feeding device and directly fed to the reactor tube. The reaction or washing solution in the reactor tube is pumped to a waste liquid tank through the vacuum tube. Nitrogen is introduced into each reactor tube through the nitrogen tube. This device can be applied in batch-wise peptide synthesis using solid-phase methods.

A peptide synthesis instrument can be used for small scale peptide synthesis. The instrument can include several unique features, including a compression style reaction vessel permitting quick setup of the reaction vessel, a double reaction vessel system permitting efficient mixing without loss of solvent or solvent-to-resin contact, gravity-fed heated reservoirs establishing a fixed volume for delivery to the reaction vessel, fume-free solvent addition permitting solvent addition to fixed bottles, and an improved amino acid manifold assembly which reduces the number of components and increases the ease of use of the instrument. Each of these features improve upon the current state of the art in solid phase automated peptide synthesizers.

The instant disclosure is related to fluidic distributors, fluidic systems, and associated methods and articles. Certain embodiments are related to fluidic distributors that comprise bays including fluidic connections with relative positions that substantially correspond to each other. In some embodiments, a fluidic distributor may comprise bays with electrical interfaces with relative positions that substantially correspond to each other.

Systems, computer program products, and methods for using a flow cell array are provided herein. A computer program product includes a computer readable storage medium having program instructions embodied therewith, the program instructions executable by a device to cause the device to deliver multiple items of chemical matter independently to multiple reaction sites of a flow cell array across multiple distinct instances of time; image multiple parallel chemical reactions at the multiple reaction sites of the flow cell array; and record an emission from each of the multiple chemical reactions site.

The invention generally relates to methods for quantifying an amount of enzyme molecules. Systems and methods of the invention are provided for measuring an amount of target by forming a plurality of fluid partitions, a subset of which include the target, performing an enzyme-catalyzed reaction in the subset, and detecting the number of partitions in the subset. The amount of target can be determined based on the detected number.

The invention generally relates to methods for quantifying an amount of enzyme molecules. Systems and methods of the invention are provided for measuring an amount of target by forming a plurality of fluid partitions, a subset of which include the target, performing an enzyme-catalyzed reaction in the subset, and detecting the number of partitions in the sunset. The amount of target can be determined based on the detected number.

A fluidic device (100) is described for locally coating an inner surface of a fluidic channel. The fluidic device (100) comprises a first (101), a second (102) and a third (103) fluidic channel intersecting at a common junction (105). The first fluidic channel is connectable to a coating fluid reservoir and the third fluidic channel is connectable to a sample fluid reservoir. The fluidic device (100) further comprises a fluid control means (111) configured for creating a fluidic flow path for a coating fluid at the common junction (105) such that, when coating, a coating fluid propagates from the first (101) to the second (102) fluidic channel via the common junction (105) without propagating into the third (103) fluidic channel. A corresponding method for coating and for sensing also has been disclosed.