Solid-phase synthesis purification

In conclusion, compared with solution-phase synthesis, solid-phase enzymatic synthesis, generally, needs higher concentrations of enzyme, longer reaction times, and a large excess of donors. Although there is still room for improvement in terms of yields and scale-up of syntheses, in solid-phase synthesis purification procedures are straightforward so it is expected that this approach will open the route to automated oligosaccharide synthesis in the near future. 

The major disadvantage of solid-phase peptide synthesis is the fact that ail the by-products attached to the resin can only be removed at the final stages of synthesis. Another problem is the relatively low local concentration of peptide which can be obtained on the polymer, and this limits the turnover of all other educts. Preparation of large quantities (> 1 g) is therefore difficult. Thirdly, the racemization-safe methods for acid activation, e.g. with azides, are too mild (= slow) for solid-phase synthesis. For these reasons the convenient Menifield procedures are quite generally used for syntheses of small peptides, whereas for larger polypeptides many research groups adhere to classic solution methods and purification after each condensation step (F.M. Finn, 1976). 

Rapid purification Stir over CaH2 (5% w/v) overnight, filter, then distil at 20mmHg. Store the distd DMF over 3A or 4A molecular sieves. For solid phase synthesis, the DMF used must be of high quality and free from amines. 

Soluble support-based synthetic approaches offer the advantages of both homogeneous solution-phase chemistry (high reactivity, ease of analysis) and solid-phase synthesis (large excess of reagents, simple product isolation and purification) [98,99]. As a representative example, PEG, one of the most widely used soluble polymers, has good solubility in most organic solvents (i.e., dichloromethane, acetonitrile, dimethylformamide, and toluene), but it... 

One of the cornerstones of combinatorial synthesis has been the development of solid-phase organic synthesis (SPOS) based on the original Merrifield method for peptide preparation [19]. Because transformations on insoluble polymer supports should enable chemical reactions to be driven to completion and enable simple product purification by filtration, combinatorial chemistry has been primarily performed by SPOS [19-23], Nonetheless, solid-phase synthesis has several shortcomings, because of the nature of heterogeneous reaction conditions. Nonlinear kinetic behavior, slow reaction, solvation problems, and degradation of the polymer support, because of the long reactions, are some of the problems typically experienced in SPOS. It is, therefore, not surprising that the first applications of microwave-assisted solid-phase synthesis were reported as early 1992 [24],... 

Keywords. Short monolithic columns, Monoliths, Chromatography, Separation, Purification, Proteins, DNA, Bioconversion, Solid-phase synthesis... 

The solid-phase synthesis of dendritic polyamides was explored by Frechet et al. [49]. Inspired by the technique used by Merrifield for peptide synthesis, the same strategy was used to build hyperbranched polyamides onto a polymeric support. The idea was to ensure the preservation of the focal point and to ease the purification between successive steps. The resulting polymers were cleaved from the solid support, allowing ordinary polymer characterization. The reaction was found to be extremely sluggish beyond the fourth generation. 

Frechet et al. reported on the solid-phase synthesis of dendritic polyamides in 1991 [49]. The intention was to grow dendritic segments from a sohd support and thereby enhance the ease of purification between successive steps (Sect. 2.2). 

Particularly noteworthy examples are Entries 8 and 9 in Table 3.19 these represent a diastereoselective RCM in which the stereoselectivity is controlled by the catalyst [886]. Entries 17, 23 and 24 (Table 3.19) illustrate the use of RCM for the solid-phase synthesis of lactams [894]. RCM induces both ring closure to the lactam and cleavage from the support. Although elegant at first glance, the usefulness of this methodology will be limited if the products must be used without further purification (as is usually the case for compound libraries prepared by parallel synthesis). Because relatively large amounts of catalyst are required, the crude products will only be acceptable for assays in which transition metal complexes do not interfere. 

Supported reagents have found application in many areas of synthesis including the construction of small peptides, the traditional foundation stone of solid phase synthesis. For example a recent paper describes the preparation of dipeptide p-nitroanilide and phosphonate libraries by supported carbodiimide coupling and scavenger purification (Scheme 2.52) [79]. 

Solid-phase synthesis has unique advantages in accommodating purification at each individual reaction step without losing compound mass. However, to ensure reaction completion is a challenging task. Our capability to monitor reactions on... 

In general, solid-phase synthesis, rather than solution-phase synthesis, can be the preferred method for the generation of combinatorial libraries because of the greater abihty to automate a solid-phase protocol, primarily due to the use of excess reagents in solution to effect cleaner reactions and to the ease of workup by simple filtration. The solid-phase method of peptide synthesis has had many notable successes. However, the preparation of peptides containing more than 20 amino acids in length using the solid-phase technique often causes major problems in that very extensive purification of the final product is needed. 

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