Separation molecule-conformation-based

The above simple model of a steric exclusion mechanism was considered by several authors attempting to describe quantitatively the gel chromatographic separation process. Distribution coefficients were expressed on the basis of the model considerations of the dimensions of both the separated molecules and the pores of gel, as well as of the stochastic model approaches (for reviews see e.g.. Refs. 1, 3-6), and also of the thermodynamic reasoning on the changes of conformational entropy of macromolecules due to their transfer from the interstitial volume into the pores in the course of separation [7]. However, besides the steric exclusion from the pores, at least two other size-based mechanisms are operative in the ideal gel chromatography ... 

Nanopatterned surfaces for DNA separation was first introduced several years ago by Young-soo Seo. In earlier works, it has been shown that it is possible to separate DNA on a flat-attractive surface without any topological boundaries or any sieving matrix. The separation mechanism is based on the differences in conformational associated with DNA molecules of different length adsorbed on the surface. This surface-directed separation has opened a new vistas for nonsieving polymer-based DNA separation. 

In the post-World War II years, synthesis attained a different level of sophistication partly as a result of the confluence of five stimuli (1) the formulation of detailed electronic mechanisms for the fundamental organic reactions, (2) the introduction of conformational analysis of organic structures and transition states based on stereochemical principles, (3) the development of spectroscopic and other physical methods for structural analysis, (4) the use of chromatographic methods of analysis and separation, and (5) the discovery and application of new selective chemical reagents. As a result, the period 1945 to 1960 encompassed the synthesis of such complex molecules as vitamin A (O. Isler, 1949), cortisone (R. Woodward, R. Robinson, 1951), strychnine (R. Woodward, 1954), cedrol (G. Stork, 1955), morphine (M. Gates, 1956), reserpine (R. Woodward, 1956), penicillin V (J. Sheehan, 1957), colchicine (A. Eschenmoser, 1959), and chlorophyll (R. Woodward, 1960) (page 5). ... 

C13HuC1N307 2,2 -Anhydro-[5-chloro-l-(3,5-di-0-acetyl-/ -D-arabino-furanosyl)-6-oxocytosine] (ACAFCC)166 I4t Z — 8 D = 1.56 R = 0.066 for 818 intensities. The glycosyl disposition of the anhydronucleoside is constrained to the syn (— 68.8°) orientation. The conformation of the D-arabinofuranosyl group is a flattened 4E (232.6°, 18.0°), and the exocyclic, C-4 -C-5 bond torsion-angle is g auche+ (50.2°). The adjacent bases are connected by N-H O hydrogen-bonds between the N-4 atom of one molecule and the carbonyl oxygen atom (0-4) of another. The twofold-symmetry-related bases are stacked, with an interbase separation of 329 pm. 

We note that the calculation of At/ will depend primarily on local information about solute-solvent interactions i.c., the magnitude of A U is of molecular order. An accurate determination of this partition function is therefore possible based on the molecular details of the solution in the vicinity of the solute. The success of the test-particle method can be attributed to this property. A second feature of these relations, apparent in Eq. (4), is the evaluation of solute conformational stability in solution by separately calculating the equilibrium distribution of solute conformations for an isolated molecule and the solvent response to this distribution. This evaluation will likewise depend on primarily local interactions between the solute and solvent. For macromolecular solutes, simple physical approximations involving only partially hydrated solutes might be sufficient. 

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