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 present invention relates to a process for providing a first reaction product by a first fermentation process conducted in a first Loop reactor, the method comprising the steps of: (i) adding an inoculum comprising one or more methanogenic microorganism to the first Loop reactor providing a first inoculated fermentation medium; (ii) adding a gaseous hydrogen (H.sub.2) to the first inoculated fermentation medium; (iii) adding a first carbon source to the first inoculated fermentation medium; (iv) allowing the first fermentation medium to ferment, providing the first reaction product; and (v) isolating the first reaction product provided in step (iv).

Methods and systems for control of solid phase peptide synthesis are generally described. Control of solid phase peptide synthesis involves the use of feedback from one or more reactions and/or processes (e.g., reagent removal) taking place in the solid phase peptide synthesis system. In some embodiments, a detector may detect one or more fluids flowing across a detection zone of a solid phase peptide synthesis system and one or more signals may be generated corresponding to the fluid(s). For instance, an electromagnetic radiation detector positioned downstream of a reactor may detect a fluid exiting the reactor after a deprotection reactor and produce a signal(s). In some embodiments, based at least in part on information derived from the signal(s), a parameter of the system may be modulated prior to and/or during one or more subsequent reactions and/or processes taking place in the solid phase peptide synthesis system. In some embodiments, the methods and systems, described herein, can be used to conduct quality control to determine and correct problems (e.g., aggregation, truncation, deletion) in reactions (e.g., coupling reactions) taking place in the solid phase peptide synthesis system.

Selectively controllable cleavable linkers include electrochemically-cleavable linkers, photolabile linkers, thermolabile linkers, chemically-labile linkers, and enzymatically-cleavable linkers. Selective cleavage of individual linkers may be controlled by changing local conditions. Local conditions may be changed by activating electrodes in proximity to the linkers, exposing the linkers to light, heating the linkers, or applying chemicals. Selective cleaving of enzymatically-cleavable linkers may be controlled by designing the sequences of different sets of the individual linkers to respond to different enzymes. Cleavable linkers may be used to attach polymers to a solid substrate. Selective cleavage of the linkers enables release of specific polymers from the solid substrate. Cleavable linkers may also be used to attach protecting groups to the ends of growing polymers. The protecting groups may be selectively removed by cleavage of the linkers to enable growth of specific polymers.

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.

Systems and processes for performing solid phase peptide synthesis are generally described. Solid phase peptide synthesis is a known process in which amino acid residues are added to peptides that have been immobilized on a solid support. In certain embodiments, the inventive systems and methods can be used to perform solid phase peptide synthesis quickly while maintaining high yields. Certain embodiments relate to processes and systems that may be used to heat, transport, and/or mix reagents in ways that reduce the amount of time required to perform solid phase peptide synthesis.

The present invention provides for a one-pot enzymatic approach which does not require removal of the enzyme and purification of the intermediate after deglycosylation step, and the Endo-S treatment is able to do both deglycosylation and transglycosylation. The one-pot strategy of the present invention enables chemoenzymatic synthesis of an azido-tagged N-glycoform of monocloncal antibodies which could be further modified through orthogonal chemical ligation for various applications.

The present disclosure provides coupling methods and systems for producing peptides or proteins using semi-continuous or continuous manufacturing techniques to enable rapid production of peptides and proteins using solid phase peptide synthesis (SPPS). The disclosure provides a higher degree of process control for peptide and protein product manufacturing using semi-continuous or continuous manufacturing techniques with inline analytics and automation.

Structured substrate including (a) a plurality of nanoparticles distributed on a solid support, (b) a gel material forming a layer in association with the plurality of nanoparticles, and (c) a library of target nucleic acids in the gel material.