Part No: PPS347Issued year: 2014File size: 0.49mbFile type: pdf
Trends on chemical synthesis have changed over recent years, with a more targeted approach to molecular design becoming more prevalent. As a result, the speed with which a new compound can be synthesized is key to an efficient laboratory.
Part No: TN522Issued year: 2004File size: 0.03mbFile type: pdf
Microwave assisted organic synthesis has become an important tool to medicinal chemists for rapid organic synthesis. Thousands of research papers have appeared over the last decades on the application of microwave technology in organic synthesis.1 Some of the major advantages include a spectacular decrease in reaction time, improved conversions, clean product formation and wide scope for the development of new reaction conditions.
Part No: Issued year: 2002File size: 0.36mbFile type: pdf
The first decision that needs to be made is what the final analysis will be for the analyte. This will have an impact on the sample and cartridge size, as well as the final elution solvent. Gas chromatography offers higher sensitivity than HPLC, while HPLC is better suited for ionisable species and very high molecular weights. If LC-MS is available, minimal sample clean-up may be required.
Part No: P167Issued year: 2017File size: 0.42mbFile type: pdf
For most organic and natural product chemists flash
chromatography is a necessary part of their research. As such, many chemists need quick isolation of at least one desired component from a crude mixture in relatively high yield and purity. This need for speed, purity, and yield pits these desires against each other as you can typically optimize on only two of the three goals.
In this poster, we will describe some techniques that help chemists optimize flash purification and maximize speed, yield, and purity.
Part No: P021Issued year: 2008File size: 1.87mbFile type: pdf
It is well known that traditional liquid-liquid extraction (LLE) provides very clean extracts prior to LC/MS analysis. Supported liquid extraction is analogous to traditional LLE, however, analyte partitioning takes place using an inert support material, rather than two immiscible liquids. This provides excellent extraction efficiencies while alleviating
many of the tedious liquid handling issues associated with LLE.
1) Remember to add stir bar for efficient mixing. Catalysts, salts, or visible precipitate should be washed clear of head space and into solution. Particles adhering to glass head space could cause excessive heating increasing possibility of failure of vial. Stay within specified vial volume range (see diagram for proper filling).
Part No: P080Issued year: 2014File size: 0.88mbFile type: pdf
This poster describes the benefits of supported liquid extraction and highlights its use in removal of endogenous matrix components that cause ion suppression/enhancement (matrix effects) in LC-MS/MS analyses.
Part No: P118Issued year: 2015File size: 0.48mbFile type: pdf
This poster examines the use of ISOLUTE SLE+ columns as an alternative to SPE for the extraction and clean up of hair samples containing drugs of abuse. SLE was found to be a simple, faster alternative to SPE for this type of analysis.
Part No: P089Issued year: 2014File size: 0.79mbFile type: pdf
This poster presents a novel method for the simultaneous extraction, derivatization and subsequent detection of both the traditional 25-hydroxy and the biologically active 1α,25-dihydroxy vitamin D metabolites in serum.
Part No: Issued year: 2013File size: 0.35mbFile type: pdf
Leu-Enkephalin-amide (YGGFLNH2, Ca. MW = 554.65) was synthesized on the Rink amide ChemMatrix® resin at a scale of 0.5 mmol. Crude peptide (100 mg) was purified in duplicate using the Isolera Dalton equipped with a Biotage® SNAP KP-C18-HS 12g cartridge.
Part No: AN097Issued year: 2014File size: 0.73mbFile type: pdf
A branched peptidoglycan mimic and a tetra-branched antimicrobial peptide analogue were synthesized on a lysine scaffold using Biotage® Initiator+ Alstra™ microwave peptide synthesizer. These peptide modifications are challenging to synthesize and automate, however, the procedure was operationally simplified using Branches™.
Part No: AN053Issued year: 2010File size: 0.92mbFile type: pdf
It has recently been demonstrated that specific recognition of rhizobial bacteria by the signaling molecule Nod-factor receptor 5 (NFR5) relies on LysM domains. The LysM (lysine motif) domain is believed to be involved in the regulation of the interaction between plants and rhizobial bacteria to promote plant growth. The LysM domain is predicted to consist of two-α
helices and a two-stranded anti-parallel β-sheet in a β-α-α-β structure and has been identified in NFR5 by sequence alignment of the crystal structure with the LysM domain of Bacillus subtilis ykuD.2 The synthesis of the C-terminal and the N-terminal regions of LysM domains provide significant challenges, this is presumably due to the formation of β-sheet like structures, which are known to pose problems for peptide chain assembly.