Water and Solute Permeability of Plant Cuticles: Measurement and ...

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References 289 Kolattukudy P (2004) Cutin from Plants. In: Y Doi, A Steinbüchel (eds) Polyesters I: biological systems and biotechnological production, Wiley-VCH, Weinheim, pp 1–40 Kolthoff IM, Sandell EB, Bruckenstein S (1969) Quantitative chemical analysis. MacMillan, London Korenman YI, Nefedova TA, Taldykina SN (1977) Extraction of nitrophenols from aqueous solutions at different temperatures. Russ J Phys Chem 51:730–732 Kunst L, Samuels AL (2003) Biosynthesis and secretion of plant cuticular wax. Prog Lipid Res 42 (1):51–80 Lakshminarayanaiah N (1969) Transport phenomena in membranes. Academic Press, New York LaMer VK, Healy TW, Aylsmore LAG (1964) The transport of water through monolayers of longchain paraffinic alcohols. J Colloid Sci 19:673–684 Larcher W (1995) Physiological plant ecology, 3rd edn. Springer, Berlin Le Roux JH, Loubser NH (1980) Nuclear magnetic resonance investigation of the mobile phase in paraffinic Fischer-Tropsch waxes. SA J Sci 76:157–161 Lendzian KJ, Kerstiens G (1991) Sorption and transport of gases and vapors in plant cuticles. Rev Environ Contamin Toxicol 121:65–128 Lendzian KJ, Schönherr J (1983) In-vivo study of cutin synthesis in leaves of Clivia miniata Reg. Planta 158:70–75 Leo A, Hansch C, Elkins D (1971) Partition coefficients and their uses. Chem Rev 71:525–616 Longsworth LG (1953) Diffusion measurements, at 25 ◦ C, of aqueous solutions of amino acids, peptides and sugars. J Am Chem Soc 75:5705–5709 Marga F, Pesacreta TC, Hasenstein KH (2001) Biochemical analysis of elastic and rigid cuticles of Cirsium horridulum. Planta 213:841–848 Marzouk H, Baur P, Schönherr J (1998) Relative solubilities of bifenox and naphthylacetic acid (NAA) in plant cuticles and in selected pure or aqueous glycol adjuvants. Pestic Sci 53: 278–284 McFairlane JC, Berry WL (1974) Cation penetration through isolated cuticles. Plant Physiol 53:723–727 McGowan JC, Mellors A (1986) Molecular volumes in Chemistry and biology: applications including partitioning and toxicity. Ellis Horwood, Chichester Mérida T, Schönherr J, Schmidt HW (1981) Fine structure of plant cuticles in relation to water permeability: the fine structure of the cuticle of Clivia miniata Reg. leaves. Planta 152: 259–267 Meier-Maercker U (1979) Peristomatal transpiration and stomatal movement: III. Visible effects of peristomatal transpiration on the epidermis. Zeitschr Pflanzenphysiol 91:225–238 Meyer M (1938) Die submikroskopische Struktur der kutinisierten Zellmembranen. Protoplasma 29:552–586 Nawrath C (2006) Unraveling the complex network of cuticular structure and function. Curr Opin Biol 9:1–7 Nevis AH (1958) Water transport in invertebrate peripheral nerve fibre. J Gen Physiol 41:927–958 Niederl S, Kirsch T, Riederer M, Schreiber L (1998) Co-permeability of 3 H-labelled water and 14 C-labelled organic acids across isolated plant cuticles: investigating cuticular paths of diffusion and predicting cuticular transpiration. Plant Physiol 116:117–123 Nobel PS (1983) Biophysical plant physiology. Freeman, San Francisco, USA Orgell WH (1955) Isolation of plant cuticle with pectic enzymes. Plant Physiol 30:78–80 Park GS (1968) The glassy state and slow process anomalies. In: Crank J, Park GS (eds) Diffusion in polymers, Academic Press, London Popp C, Burghardt M, Friedmann A, Riederer M (2005) Characterization of hydrophilic and lipophilic pathways of Hedera helix L. cuticular membranes: permeation of water and uncharged organic compounds. J Exp Bot 56:2797–2806 Potts RO, Francoeur ML (1991) The influence of Stratum Corneum morphology on water permeability. J Investig Dermatol 96:495–499 Potts RO, Guy RH (1992) Predicting skin permeability. Pharma Res 9:663–669
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Water and Solute Permeability of Pl
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Professor Dr. Lukas Schreiber Ecoph
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vi Preface This is not a review abo
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Contents 1 Chemistry and Structure
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Contents xi 4.6.3 Diffusion Coeffic
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Contents xiii 7.4.2 Effects of Plas
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2 1 Chemistry and Structure of Cuti
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10 1 Chemistry and Structure of Cut
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Chapter 2 Quantitative Description
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2.1 Models for Analysing Mass Trans
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2.3 Steady State Diffusion Across a
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2.4 Steady State Diffusion of a Sol
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2.4 Steady State Diffusion of a Sol
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2.5 Diffusion Across a Membrane wit
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2.5 Diffusion Across a Membrane wit
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2.6 Determination of the Diffusion
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Solutions 51 2.7 Summary In this ch
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Chapter 3 Permeance, Diffusion and
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3.1 Units of Permeability 55 3.1.1
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3.1 Units of Permeability 57 identi
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3.3 Partition Coefficients 59 The d
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Chapter 4 Water Permeability All te
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4.1 Water Permeability of Synthetic
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4.2 Isoelectric Points of Polymer M
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4.2 Isoelectric Points of Polymer M
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4.3 Ion Exchange Capacity 69 The hi
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4.3 Ion Exchange Capacity 71 has an
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4.3 Ion Exchange Capacity 73 Counte
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4.4 Water Vapour Sorption and Perme
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4.4 Water Vapour Sorption and Perme
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4.5 Diffusion and Viscous Transport
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4.6 Water Permeability of Isolated
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Problems 121 Our present knowledge
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Solutions 123 5. Ca 2+ , because se
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126 5 Penetration of Ionic Solutes
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146 6 Diffusion of Non-Electrolytes
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206 7 Accelerators Increase Solute
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Chapter 8 Effects of Temperature on
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8.1 Sorption from Aqueous Solutions
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Page 266 and 267: Problems 257 E D (kJ/mol) DH S (kJ/
Page 268 and 269: Chapter 9 General Methods, Sources
Page 270 and 271: 9.2 Testing Integrity of Isolated C
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Page 274 and 275: 9.6 Cutin and Wax Analysis and Prep
Page 276 and 277: 9.7 Measuring Water Permeability 26
Page 278 and 279: 9.8 Measuring Solute Permeability 2
Page 284 and 285: 276 Appendix A Abbreviations (conti
Page 286 and 287: 278 Appendix A Symbols (continued)
Page 288 and 289: 280 Appendix B Physico-chemical pro
Page 290 and 291: Appendix C Index of Plants Botanica
Page 292 and 293: References Abraham MH, McGowan JC (
Page 294 and 295: References 287 Doty PM, Aiken WH, M
Page 298 and 299: References 291 Sabljic A, Güsten H
Page 300 and 301: References 293 Schreiber L, Schönh
Page 302 and 303: Index 2,4-D, 46 2,4-Dichlorophenoxy
Page 304 and 305: Index 297 leaf disks, 130 leaf surf
Page 306: Index 299 water molar volume, 110 p
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