Liquid Culture Systems for in vitro Plant Propagation

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210 Elio Jiménez González Escalant J-V, Teisson C & Cote F (1994) Amplified somatic embryogenesis from male flowers of triploid banana and plantain cultivars (Musa spp.) In Vitro Cell. Dev. Biol. 30: 181-186 Escalona M, Lorenzo B, González B, Daquinta M, González JL, Desjardins Y & Borroto C (1999) Pineapple (Ananas comosus L. Merr) micropropagation in temporary immersion. Plant Cell Rep. 18: 743-748 Etienne H & Berthouly M (2002) Temporary immersion systems in plant micropropagation. Plant Cell Tiss. Org. Cult 69: 215–231 Etienne H, Lartaud M, Michaux-Ferriere N, Carron MP, Berthouly M & Teisson C (1997) Improvement of somatic embryogenesis in Hevea brasiliensis (Müll. Arg) using the temporary immersion technique. In Vitro Cell. Dev. Biol.-Plant. 33: 81-87 Freire M (2001) Nueva metodología de embriogénesis somática en caña de azúcar (Saccharum spp híbrido) empleando medios de cultivo líquidos. Tesis de Doctorado (p. 107). Instituto de Biotecnología de las Plantas. Universidad Central de Las Villas, Santa Clara, Cuba Gómez R, de Feria M, Posada L, Gilliard T, Bernal F, Reyes M, Chávez M & Quiala E (2002) Somatic embryogenesis of the banana hybrid cultivar FHIA-18 (AAAB) in liquid medium and scaled-up in a bioreactor. Plant Cell Tiss. Org. Cult. 68: 21–26 Hempfling T & Preil W (2002) Application of a temporary immersion system in propagation of Phalaenopsis. First International Symposium on “Liquid Systems for in vitro Mass Propagation of Plants” (pp. 47-48). Agricultural University of Norway. 29 May-2 June Hohe A, Gerth A, Jiménez E, Jordan M, Gómez R, Schmeda G & Wilken D (2002) Production of active substances applying temporary immersion systems. First International Symposium on “Liquid Systems for in vitro Mass Propagation of Plants” (pp. 49-50). Agricultural University of Norway. 29 May-2 June Jiménez E (1995) Propagacion in vitro de la caña de azúcar (Saccharum spp híbrido). Tesis de Doctorado. Instituto de Biotecnología de las Plantas. Universidad Central de Las Villas, Santa Clara, Cuba. p. 95 Jiménez E, Pérez N, de Feria M, Barbón R, Capote A, Chávez M & Quiala E (1999) Improved production of potato microtubers in a temporary immersion system. Plant Cell Tiss. Org. Cult. 59: 19-23 Jiménez E, de Feria M, Freire M, Quiala E, Chávez M, Herrera I & Capote A (2002) Sugarcane somatic embryo production in bioreactors: Effect of partial oxygen pressure, germination in temporary immersion systems and field studies of regenerated plants. First International Symposium on “Liquid Systems for in vitro Mass Propagation of Plants” (p. 143) Agricultural University of Norway, 29 May-2 June Lorenzo JC, González BL, Escalona M, Teisson C, Espinosa P & Borroto C (1998) Sugarcane shoot formation in an improved temporary immersion system. Plant Cell Tiss. Org. Cult. 54: 197-200 Mc Alister B, Finnie J, Watt MP & Blakeway F (2002) Use of temporary immersion system (RITA ®) for the production of commercial Eucalyptus clones at Mondi Forests (SA). First International Symposium on “Liquid Systems for in vitro Mass Propagation of Plants” (p. 79). Agricultural University of Norway. 29 May-2 June Medero V, Rodríguez S, Borroto C, Gómez R, Lóèz J, de Feria M, García M, Ventura J & Cabrera M (2001) Sistema de inmersión temporal para producción intensiva de material de siembra de yuca. Continente Yuquero 3: 10-11 Pérez J, Jiménez E & Agramonte D (1998) Aumento de la eficiencia en la propagación masiva. In: Pérez et al. (eds) Propagación y mejora genética de plantas por biotecnología (pp. 179-192). Instituto de Biotecnología de las Plantas, Santa Clara, Cuba
Mass propagation of tropical crops 211 Perez N, Jiménez E, de Feria M, Capote A, Chávez M & Quiala E (2000) Escalado productivo de microtuberculos de papa (Solanum tuberosum L var Atlantic) en sistemas de inmersión temporal y su evaluación en condiciones de campo. XIX Congreso de la Asociación Latinoamericana de la Papa, ALAP (p. 227). 28 de Febrero al 3 de Marzo. La Habana, Cuba Preil W (1991) Application of bioreactors in plant propagation. In: Debergh PC & Zimmerman RH (eds) Micropropagation: Technology and Application (pp. 426-445). Kluwer Academic Publishers, Dordrecht Teisson C, Alvard D, Berthouly B, Cote F, Escalant JV, Etienne H & Lartaud M (1996) Simple apparatus to perform plant tissue culture by temporary immersion. Acta Horticulturae 440: 521-526 Teisson C & Alvard D (1995) A new concept of plant in vitro cultivation in liquid medium: Temporary immersion. In: Terzi M et al. (eds) Current Issues in Plant Molecular and Cellular Biology (pp. 105–110). Kluwer Academic Publishers, Dordrecht Teisson C & Alvard D (1999) In vitro production of potato microtubers in liquid medium using temporary immersion. Potato Research 42: 499-504 Vilches J, Albany N & Gómez R (2002) Somatic embryogenesis induction in guava (Psidium guajava L.). Plant Cell Tiss. Org. Cult. (in press) Ziv M (1992) The use of growth retardants for the regulation and acclimatization of in vitro plants. In: Karssen CM, Van Loon LC & Vreugdenhil D (eds) Progress in Plant Growth Regulation (pp. 809-817). Kluwer Academic Publishers, Dordrecht Ziv M, Ronen G & Raviv M (1998) Proliferation of meristematic clusters in disposable presterilized plastic bioreactors for the large-scale micropropagation of plants. In Vitro Cell. Dev. Biol.-Plant. 34: 152-158
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LIQUID CULTURE SYSTEMS FOR IN VITRO
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A C.I.P. Catalogue record for this
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Contents Contributing Authors xiii
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Liquid culture systems for in vitro
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Contributing Authors Adelberg, J. 4
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Preface Plant cell, tissue and orga
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Chapter 1 General introduction: a p
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General introduction 3 2. Cell susp
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General introduction 5 rooted in gr
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General introduction 7 (Winkelmann
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General introduction 9 the bioreact
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General introduction 11 (TIS), resu
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General introduction 13 Barz W, Rei
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General introduction 15 Hohe A, Win
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General introduction 17 Shimazu T &
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I. Bioreactors
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22 Wayne R. Curtis 1. Introduction
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24 Wayne R. Curtis headspace double
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26 Wayne R. Curtis that is required
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28 Wayne R. Curtis C L y � P O2
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30 Wayne R. Curtis since there is a
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32 Wayne R. Curtis 5 cm 30 cm 30 o
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34 Wayne R. Curtis Pˆ N � � me
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36 Wayne R. Curtis Radial Flow Impe
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38 Wayne R. Curtis CS = Medium diss
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40 Wayne R. Curtis Murashige T & Sk
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42 Anne Kathrine Hvoslef-Eide et al
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Chapter 4 Practical aspects of bior
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Practical aspects of bioreactor app
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Chapter 5 Simple bioreactors for ma
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Simple bioreactors for mass propaga
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96 K. Y. Paek et al. opportunity fo
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98 K. Y. Paek et al. disadvantages
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100 K. Y. Paek et al. 3.1 Dissolved
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102 K. Y. Paek et al. optimizing bi
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104 K. Y. Paek et al. cosmetics, wh
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106 K. Y. Paek et al. protocol, mor
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108 K. Y. Paek et al. use. In order
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110 K. Y. Paek et al. a b c d e f F
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112 K. Y. Paek et al. a b c d e f F
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114 K. Y. Paek et al. Escalona M, L
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116 K. Y. Paek et al. Son SH & Paek
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118 Seppo Sorvari et al. economical
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120 Seppo Sorvari et al. membrane w
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122 Seppo Sorvari et al. 3. Results
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124 Seppo Sorvari et al. D.O. 160 1
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Chapter 8 Cost-effective mass cloni
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Cost-effective mass cloning of plan
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144 Eun-Joo Hahn & Kee-Yoeup Paek 1
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146 Eun-Joo Hahn & Kee-Yoeup Paek F
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148 Eun-Joo Hahn & Kee-Yoeup Paek T
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150 Eun-Joo Hahn & Kee-Yoeup Paek 3
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152 Eun-Joo Hahn & Kee-Yoeup Paek E
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Chapter 10 Control of growth and di
Page 168 and 169: Control of growth and differentiati
Page 174 and 175: Chapter 11 Temporary immersion syst
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Page 206 and 207: 198 Elio Jiménez González 1. Intr
Page 208 and 209: 200 Elio Jiménez González Several
Page 210 and 211: 202 Elio Jiménez González Figure
Page 212 and 213: 204 Elio Jiménez González exploit
Page 214 and 215: 206 Elio Jiménez González weeks i
Page 216 and 217: 208 Elio Jiménez González germina
Page 220 and 221: Chapter 13 Use of growth retardants
Page 222 and 223: Use of growth retardants for banana
Page 232 and 233: Chapter 14 Somatic embryo germinati
Page 234 and 235: Somatic embryo germination of Psidi
Page 236 and 237: Somatic embryo germination of Psidi
Page 238 and 239: 232 Tino Hempfling & Walter Preil N
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Page 250 and 251: 244 C. Damiano et al. Over the last
Page 252 and 253: 246 C. Damiano et al. 2.2 Temporary
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Page 258 and 259: Chapter 17 Optimisation of growing
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264 Katerina Grigoriadou et al. cul
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266 Katerina Grigoriadou et al. 2.4
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268 Katerina Grigoriadou et al. mic
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270 Katerina Grigoriadou et al. of
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272 Katerina Grigoriadou et al. 4.
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274 Katerina Grigoriadou et al. Tei
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276 Ch. Wawrosch et al. possesses s
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278 Ch. Wawrosch et al. 3. Results
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280 Ch. Wawrosch et al. References
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Chapter 20 Propagation of Norway sp
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Propagation of Norway Spruce 285 2.
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Propagation of Norway Spruce 287 su
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Propagation of Norway Spruce 289 5.
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Propagation of Norway Spruce 291 bl
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Propagation of Norway Spruce 293 H
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296 M. Vágner et al. 1995). In liq
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298 M. Vágner et al. maturation pe
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300 M. Vágner et al. mature somati
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302 M. Vágner et al. Acknowledgeme
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304 Christopher Hunter & Lionel Lev
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314 Michel Petitprez et al. 1. Intr
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316 Michel Petitprez et al. 2.2 QTL
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318 Michel Petitprez et al. Figure
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320 Michel Petitprez et al. Table 1
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322 Michel Petitprez et al. Gentzbi
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324 F. Afreen et al. 1. Introductio
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326 F. Afreen et al. precotyledonar
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328 F. Afreen et al. Dry mass (mg/e
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330 F. Afreen et al. under photoaut
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332 F. Afreen et al. Figure 3: a) C
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334 F. Afreen et al. the plant qual
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Chapter 25 Potential of flow cytome
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Potential of flow cytometry 339 dis
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Potential of flow cytometry 341 Fig
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Potential of flow cytometry 343 tha
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Chapter 26 Somatic embryogenesis of
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Somatic embryogenesis of Gentiana 3
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Chapter 27 Induction and growth of
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Induction and growth of tulip 361 a
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Induction and growth of tulip 363 T
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Chapter 28 Micropropagation of Ixia
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Micropropagation of Ixia 367 for PA
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Micropropagation of Ixia 369 Biomas
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Micropropagation of Ixia 371 Figure
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Chapter 29 Micropropagation of Rosa
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Micropropagation of Rosa 375 The BA
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Micropropagation of Rosa 377 Platfo
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Micropropagation of Rosa 379 3. Res
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Micropropagation of Rosa 381 The ro
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Micropropagation of Rosa 383 4. Dis
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Micropropagation of Rosa 385 Murash
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Chapter 30 Mass propagation of coni
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Mass propagation of conifer trees 3
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Chapter 31 Potentials for cost redu
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Potentials for cost reduction 405 c
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Potentials for cost reduction 407 c
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Potentials for cost reduction 409 s
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Potentials for cost reduction 411 N
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Potentials for cost reduction 413 G
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Chapter 32 A new approach for autom
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A new approach for automation 417 (
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A new approach for automation 419 p
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A new approach for automation 421 T
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A new approach for automation 423 D
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426 B. McAlister et al. 1. Introduc
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428 B. McAlister et al. 2.2 Multipl
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430 B. McAlister et al. Table 2: Mu
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432 B. McAlister et al. rest time -
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434 B. McAlister et al. Figure 3: M
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436 B. McAlister et al. Average mul
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438 B. McAlister et al. Table 4: Co
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440 B. McAlister et al. Semi-solid
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442 B. McAlister et al. Escalona M,
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444 Jeffrey Adelberg including Host
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446 Jeffrey Adelberg BioSystems (Ho
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448 Jeffrey Adelberg more prolific
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450 Jeffrey Adelberg vessel of liqu
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452 Jeffrey Adelberg Figure 4: Labo
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454 Jeffrey Adelberg constituted a
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456 Jeffrey Adelberg Acknowledgemen
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Chapter 35 Aeration stress in plant
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Aeration stress in plant tissue cul
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476 Hans R. Gislerød et al. 1. Int
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478 Hans R. Gislerød et al. biorea
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480 Hans R. Gislerød et al. A low
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482 Hans R. Gislerød et al. Table
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484 Hans R. Gislerød et al. common
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486 Hans R. Gislerød et al. can be
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488 Hans R. Gislerød et al. 4.1 Li
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490 Hans R. Gislerød et al. 4.3 Ca
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492 Hans R. Gislerød et al. Morten
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494 Han Bouman & Annemiek Tiekstra
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V. Biomass for Secondary Metabolite
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510 E. Gontier et al. 1. Introducti
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512 E. Gontier et al. 2. Materials
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514 E. Gontier et al. developed dra
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516 E. Gontier et al. 3.3 Establish
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518 E. Gontier et al. Fresh weight
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520 E. Gontier et al. 3.5 Effect of
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522 E. Gontier et al. 3.6 Scale up
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524 E. Gontier et al. Lorenzo JC, G
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526 Dirk Wilken et al. 1. Introduct
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528 Dirk Wilken et al. running at 6
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530 Dirk Wilken et al. described a
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532 Dirk Wilken et al. packed cell
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534 Dirk Wilken et al. bioactive co
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536 Dirk Wilken et al. Fowler MW (1
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Chapter 40 Cultivation of root cult
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Cultivation of root cultures of Pan
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Chapter 41 Optimisation of Panax gi
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Optimisation of Panax ginseng liqui
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558 S. M. Nalawade et al. performan
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560 S. M. Nalawade et al. Plantlets
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562 S. M. Nalawade et al. leaves on
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564 S. M. Nalawade et al. roots (Fi
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Chapter 43 Production of taxanes in
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Production of taxanes 569 2. Materi
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Production of taxanes 571 Figure 2:
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Production of taxanes 573 various T
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Acknowledgments The editors thank t
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578 Contents 130, 131, 133, 134, 13
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580 Contents poplar, see Populus Po
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582 Contents bubble aerated 165 bub
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584 Contents ginsenoside content, p
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586 Contents plant growth regulator
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588 Contents -free microcorms 71 -f
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