Essential BioinformaticsCambridge University Press, 13 mars 2006 Essential Bioinformatics is a concise yet comprehensive textbook of bioinformatics, which provides a broad introduction to the entire field. Written specifically for a life science audience, the basics of bioinformatics are explained, followed by discussions of the state-of-the-art computational tools available to solve biological research problems. All key areas of bioinformatics are covered including biological databases, sequence alignment, genes and promoter prediction, molecular phylogenetics, structural bioinformatics, genomics and proteomics. The book emphasizes how computational methods work and compares the strengths and weaknesses of different methods. This balanced yet easily accessible text will be invaluable to students who do not have sophisticated computational backgrounds. Technical details of computational algorithms are explained with a minimum use of mathematical formulae; graphical illustrations are used in their place to aid understanding. The effective synthesis of existing literature as well as in-depth and up-to-date coverage of all key topics in bioinformatics make this an ideal textbook for all bioinformatics courses taken by life science students and for researchers wishing to develop their knowledge of bioinformatics to facilitate their own research. |
Table des matières
LXXIII | 154 |
LXXIV | 155 |
LXXV | 163 |
LXXVI | 176 |
LXXVII | 180 |
LXXVIII | 181 |
LXXIX | 182 |
LXXX | 184 |
XIII | 31 |
XIV | 40 |
XV | 44 |
XVIII | 45 |
XIX | 46 |
XX | 47 |
XXI | 54 |
XXII | 60 |
XXIII | 61 |
XXIV | 62 |
XXV | 64 |
XXVII | 65 |
XXIX | 73 |
XXX | 74 |
XXXII | 75 |
XXXIII | 76 |
XXXIV | 77 |
XXXV | 78 |
XXXVI | 84 |
XXXVII | 86 |
XXXVIII | 87 |
XXXIX | 88 |
XL | 90 |
XLI | 92 |
XLII | 97 |
XLIV | 98 |
XLV | 99 |
XLVII | 100 |
XLVIII | 103 |
XLIX | 104 |
L | 105 |
LI | 106 |
LII | 107 |
LIII | 108 |
LIV | 110 |
LV | 111 |
LVI | 116 |
LVII | 124 |
LIX | 127 |
LX | 128 |
LXI | 136 |
LXII | 137 |
LXIII | 138 |
LXV | 140 |
LXVII | 141 |
LXVIII | 143 |
LXIX | 144 |
LXX | 145 |
LXXI | 146 |
LXXII | 153 |
LXXXI | 186 |
LXXXIV | 187 |
LXXXV | 188 |
LXXXVI | 189 |
LXXXVII | 191 |
LXXXVIII | 193 |
LXXXIX | 194 |
XC | 195 |
XCI | 198 |
XCII | 199 |
XCIII | 200 |
XCIV | 203 |
XCV | 208 |
XCVI | 212 |
XCVII | 213 |
XCVIII | 214 |
XCIX | 221 |
C | 224 |
CI | 225 |
CII | 226 |
CIII | 227 |
CIV | 228 |
CV | 236 |
CVI | 240 |
CVII | 241 |
CVIII | 243 |
CIX | 244 |
CX | 246 |
CXI | 247 |
CXII | 250 |
CXIII | 252 |
CXIV | 253 |
CXV | 254 |
CXVI | 256 |
CXVII | 258 |
CXVIII | 259 |
CXIX | 263 |
CXX | 268 |
CXXI | 272 |
CXXII | 274 |
CXXV | 280 |
CXXVI | 291 |
CXXVII | 292 |
CXXVIII | 293 |
CXXIX | 294 |
CXXX | 302 |
CXXXI | 304 |
CXXXII | 309 |
CXXXIV | 312 |
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Expressions et termes fréquents
algorithms amino acid analysis annotation approach atoms bioinformatics biological databases BLAST BLOSUM branch lengths calculated cDNA Chapter Click Clustal clustering coding codon coiled coil compared comparison computational consensus conserved construction database searching datasets derived detect DNA microarray DNA sequences dynamic programming eukaryotic evaluation example exons FASTA Figure fold format functions GenBank gene expression gene prediction genetic genomic sequence helices heuristic homologous homology modeling hydrophobic identify initio interactions iterative loop Markov model matching matrix method microarray molecular motifs and domains multiple alignment multiple sequence alignment mutations neural network nodes nucleotide optimal pairwise alignment patterns peptide phylogenetic tree positions probability prokaryotic promoter protein sequences protein structures proteomics PSI-BLAST PSSM query sequence regions related sequences residues secondary structure prediction sequence database sequence similarity server statistical substitution substitution matrix taxa transcription tree topologies values web-based program window
Fréquemment cités
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