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The development of PCR, which enables extremely small amounts of DNA to be amplified, led to the rapid development of a multiplicity of a- lytical procedures that permit use of this new resource for the analysis of genetic variation and for the detection of disease-causing mutations. The advent of capillary electrophoresis (CE), with its power to separate and a- lyze very small amounts of DNA, has also stimulated researchers to develop analytical procedures for the CE format. The advantages of CE in terms of speed and reproducibility of analyses are manifold. Furthermore, the high s- sitivity of detection, and the ability to increase sample throughput with par- lel analysis, has led to the creation of a full range of analysis of DNA molecules, from modified DNA adducts and single-strand oligonucleotides through PCR-amplified DNA fragments and whole chromosomes. Capillary Elect- phoresis of Nucleic Acids focuses on analytical protocols that can be used for detection and analysis of mutations and modification, from precise DNA loci through entire genomes of organisms. Important practical considerations for CE, such as the choice of separation media, electrophoresis conditions, and the influence of buffer additives and dyes on DNA mobility, are discussed in several key chapters and within particular applications.
The development of PCR, which enables extremely small amounts of DNA to be amplified, led to the rapid development of a multiplicity of a- lytical procedures to utilize this new resource for analysis of genetic variation and for the detection of disease causing mutations. The advent of capillary electrophoresis (CE), with its power to separate and analyze very small amounts of DNA, has also stimulated researchers to develop analytical procedures for the CE format. The advantages of CE in terms of speed and reproducibility of analysis are manifold. Further, the high sensitivity of detection, and the ab- ity to increase sample throughput with parallel analysis, has led to the creation of a full range of analysis of DNA molecules, from modified DNA-adducts and single-strand oligonucleotides through to PCR-amplified DNA fragments and whole chromosomes. Capillary Electrophoresis of Nucleic Acids focuses on such analytical protocols, which can be used for detection and analysis of mutations and modification, from precise DNA loci through to entire genomes of organisms. Important practical considerations for CE, such as the choice of separation media, electrophoresis conditions, and the influence of buffer additives and dyes on DNA mobility, are discussed in several key chapters and within particular applications.
An outstanding panel of hands-on experts and developers of CE equipment describe in step-by-step fashion their best cutting-edge methods for the detection and analysis of DNA mutations and modifications, ranging from precise DNA loci to entire genomes of organisms. This first volume of the set, Introduction to the Capillary Electrophoresis of Nucleic Acids, covers the practical and theoretical considerations behind the use of capillary electrophoresis for the analysis of small oligonucleotides and modified nucleotides. Along with detailed instructions ensuring ready reproducibility, these protocols offer time-tested advice on instrumentation, signal detection, the capillary environment, and the integration of mass spectrometry with CE. Several chapters are devoted to the analysis of small therapeutic oligonucleotides, nucleosides, and ribonucleotides by CE. The companion volume, Practical Applications of Capillary Electrophoresis, addresses techniques for high-throughput analysis of DNA fragments using SNP detection, mutation detection, DNA sequencing methods, and DNA-ligand interactions. Comprehensive and up-to-date, the paired volumes of Capillary Electrophoresis of Nucleic Acids offer an authoritative guide with easy access to fast, versatile, reliable, and powerful technologies for all those basic and clinical investigators analyzing DNA variation today.
Since the independent invention of DNA sequencing by Sanger and by
Gilbert 30 years ago, it has grown from a small scale technique
capable of reading several kilobase-pair of sequence per day into
today's multibillion dollar industry. This growth has spurred the
development of new sequencing technologies that do not involve
either electrophoresis or Sanger sequencing chemistries. Sequencing
by Synthesis (SBS) involves multiple parallel micro-sequencing
addition events occurring on a surface, where data from each round
is detected by imaging.
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