Search results for: 'azido'

HMPO (5-(hydroxymethyl)pyrogallol orthoester), a plasma-stable, pH-sensitive, 1,6-self-immolative crosslinker derived from the natural product gallic acid. Discover its properties!

Use the possibilities of Linkerology® to boost the efficacy of your drug! We illustrate how the drug Gepirone (Exxua TM ), a medication to treat major depressive disorders, can be conjugated.

Have an additional ace up your sleeve for selective and efficient peptide modification, cyclization, and/or bioconjugation. Explore 2-cyanopyridines for click-like reactions. Get more information!

The targeted delivery and traceless release of drugs is an important concept in pharmacology. Discover the possibilities of payload conjugation to carrier proteins shown for the example drug Elacestrant.

Discover our new building block 4-(azido-propyl-tetrazine)phenylalanine (pTAF) and make use of the orthogonality of the 2 nd and 3 rd generation Click reaction to build multiconjugates via double-Click.

Bioengineering in combination with Linkerology® . Check out the unique options for membrane proteins, recombinant immunotoxins (RITs) and novel antibody-drug conjugates.

You missed our workshop featuring Prof. Rob Liskamp (Cristal Therapeutics, University of Maastricht, University of Glasgow)? Any further questions? Please get in contact via info@iris-biotech.de.

(Bi)functional dioxoborolane and disulfide-based self-immolative linkers – mode of action and application examples for the detection of H 2 O 2 , for prodrug design, and reversible peptide cyclization.

The 2022 Chemistry Nobel prize is awarded to B. Sharpless, M. Meldal and C. Bertozzi for their work in the field of Click Chemistry. At Iris, we are providing clickable building blocks for nobel chemistry. Read on for more information!

The para -azido benzyloxycarbonyl protected lysine building block Fmoc-L-Lys(4-N3-Z)-OH (FAA8830) is useful for a wide range of applications. Read on to find out more!

Discover our selection of propargyl-substituted amino acids and find the best position for subsequent Click chemistry within your peptide/protein. Just click here for further information on our products.

Iris Biotech offers various (protected) azide- and alkyne-modified fatty acid derivatives suitable for Click Chemistry. Interested? Read on to find out more!

The highly lipophilic, bulky adamantyl motif is a promising and validated building block to increase the drug-qualities of lead compounds without increasing their toxicity.

Methionine is particularly prone to oxidation by atmospheric oxygen in vitro but also by reactive oxygen species in vivo, resulting in the corresponding sulfoxide and sulfone. Read on to find out more.

Learn, how His-Tag can be used for specific linker attachment. Another example in our LINKEROLOGY series of sophisticated linker technologies.

Alkyne amino acids allow for Click conjugations and other types of chemistry. Read more about alkyne-functionalized amino acids and our related products.

DTT is a powerful yet mild reducing agent. Based on your demand we can offer different quality grades to suit your needs.

Betulin and its derivatives are pentacyclic triterpenoids of the lupane-type. They are natural products that occur as secondary metabolites in over 200 different plants. Betulinic acid (BA) is a derivative of betulin that is oxidized at C-28.

This alkyne-functionalized cysteine building block can be incorporated into peptides via the Fmoc strategy.

Azido and alkyne functions can cyclise by an intramolecular CuI or Cu0 catalyzed azide-alkyne 1,3-dipolar cycloaddition (CuAAC). This so-called Click Reaction, developed by K. Barry Sharpless and Morton Meldal, has meanwhile grown to a widely used type of reaction orthogonal to many other types of reactions in different kinds of applications.

Mutant or modified aminoacyl tRNA synthetases (aaRS) have been used to charge non-natural amino acids to the corresponding tRNA, which incorporates them into polypeptides or proteins during recombinant synthesis.

As Boc and Fmoc protected derivatives of both azido and alkyne amino acids are available, they can be introduced into peptide sequences through standard SPPS protocols, for example. In an α-helical secondary structure amino acids at positions i and i+4 are above each other.

The azido group can be reduced to an amino function and hereby serve as masked amino group. It is of particular use if additional orthogonalities are needed. Azido is stable towards treatment with piperidine (Fmoc deprotection), Pd(0) (Alloc removal) and acidic treatmet (cleavage of Mtt, Trt or other acid sensitive groups). However, as it is a pseudohalogenide, care has to be taken during coupling steps, as HATU will cause high racemization. This can be avoided using collidine or other non-nucleophilic bas...

Click Chemistry in DNA Synthesis - Applications and Procedures in DNA Synthesis

Click chemistry is a convenient method to chemoselectively functionalize peptides at specific positions. We offer a variety of different propargyl amino acids for both Fmoc and Boc strategies, for enzymatic synthesis, as well as preloaded resins for SPPS.

Alkylating the Nitrogen of an amide bond results in peptoid structures, leading to conformational restrains, like N-methylation and allows backbone derivatisation. Applications already have been published with Cilengitide, Piscidin 1, and MC4 receptor agonist.

Fatty Acids for Click Conjugation Fatty acid residues and alkyl chains in general can improve solubility and anchoring in membranes and other Lipophilie environments. Find a selection of promptly available short and long chain clickable acids in our web store. Any other – including functional groups for copper-free Click conjugation can be made on custom synthesis basis.

1,4-substituted 1,2,3-triazole are isosteric to peptide bonds and result in peptide mimetics which even retain activity e.g. in case of certain tyrosinease inhibitors. We offer custom synthesis of Alkyne Amino Acid Analogues as building blocks for triazol formation via Click conjugation. Side chains can represent all natural amino acids or unusual residues. In combination with our alpha-azido acids we can offer the whole range of building blocks to design Click-peptide bond analogues for every proteinoge...

Aryl azides are well-known precursors of nitrenes and have been introduced by Fleet  et al . as versatile photoaffinity labeling agents to probe biological receptors.

The azido function can be used for different applications

Building Blocks for the synthesis of 2,3-diaminobutanoic acid containing peptides or for Click reactions.

Spermines and other Biogenic Polyamines interact due to their multi cationic structure with DNA!

H-L-Aha-OH*HCl H-L-Dab(N3)-OH 4-Azido-L-homoalanine (S)-2-Amino-4-azidobutanoic acid hydrochloride Formula:                    C 4 H 8 N 4 O 2 *HCl Molecular Weight:     144,13*35,45 g/mole CAS:  942518-29-8 CODE:  HAA5730 1g:       EUR    200,-    US$    300,-  5g:   ...

Dendrimers offer a new possibility to derivatize small molecules, surfaces or biopharmaceuticals with a monodisperse macromolecule and alter in this way properties like solubility and hydrophilicity. Immunogenicity and pharmacokinetics of pharmaceuticals will be improved. The synthetic approach for designing these dendrons of different generations is based on 2,2-bis(hydroxymethyl) propionic acid, which is a non-toxic and biocompatible building block. The size can be designed from 250 g/mole for 1st gene...