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Each chapter identifies a problem in neurobiology, showing how the solution of that problem will advance knowledge in the field. The approaches taken to solve the problem are clearly explained, providing sufficient detail for users to readily reproduce the technique and its results. In keeping with the goal of the series, each technique is designed to work, even the first time it is used.
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Separation of Large DNA Molecules by Pulsed-Field Gel Electrophoresis Duncan J. Shaw 1. Introduction Conventional agarose gel electrophoresis is a widely used technique for the analysis of many kinds of biological molecules, including fragments of DNA. It has one major limitation, namely its inability to resolve DNA fragments of greater than approx 30 kb in length. In human genetics, the enormous length of the genome (3 million kb) makes it necessary to have techniques capable of analyzing much larger DNA molecules, and it was in response to this that the methods of pulsed field-gel electrophoresis (PFGE) were developed. The procedure was first described by Schwartz and Cantor (I), and since then numerous variations and modifications have been published (2-4). These methods all have in common the use of two alternately switched (pulsed) electric fields, arranged at an angle of between 90 and 180 degrees. Conventional gel electrophoresis uses a single, continuous electric field. In PFGE, the molecules are forced to change direction each time the field is switched, and the time taken for a large DNA molecule to reorient itself in response to the change in field is a direct function of its size. Hence, at each pulse, longer molecules become retarded relative to shorter ones because of their longer reorientation time, and over the course of the electrophoretic run, a separation is achieved. The theory of the method was described in detail by Southern et al. (5)