@phdthesis{Arand2010,
  author    = {Arand, Katja},
  title     = {Charakterisierung hydrophiler Permeationswege in der pflanzlichen Kutikula anhand der Permeationseigenschaften ionischer Aminos{\"a}uren},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-49954},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2010},
  abstract  = {Um sich vor dem Austrocknen zu sch{\"u}tzen, haben Pflanzen eine Transpirationsbarriere entwickelt, die als Membran alle prim{\"a}ren, oberirdischen Pflanzenteile {\"u}berzieht. Diese so genannte Kutikula besteht haupts{\"a}chlich aus den lipophilen Komponenten Kutin und Wachs und reduziert so effektiv den Verlust von Wasser und wasserl{\"o}slichen N{\"a}hrstoffen aus dem Blattinneren. Trotzdem ist sie nicht vollst{\"a}ndig undurchl{\"a}ssig, und so k{\"o}nnen Wasser und gel{\"o}ste Substanzen wie organische und anorganische N{\"a}hrstoffe, Pestizide oder Umweltchemikalien die Kutikula in beiden Richtungen permeieren. Dabei ist offensichtlich, dass die zu Grunde liegenden Transportmechanismen den Ern{\"a}hrungszustand der Pflanzen, die Effizienz von Pestiziden und die Wirkung von Umweltchemikalien beeinflussen. Ein genaues Verst{\"a}ndnis der Transportprozesse auf denen die kutikul{\"a}re Permeation basiert, kann helfen die Wirkweise von blattapplizierten D{\"u}nge- und Pflanzenschutzmitteln zu optimieren, indem gezielt Wirk- oder Zusatzstoffe modelliert werden k{\"o}nnen, welche die Aufnahme steigern. In der vorliegenden Arbeit sollte deshalb der Einfluss physiko-chemischer Eigenschaften von hydrophilen Verbindungen auf die kutikul{\"a}re Permeation untersucht werden. Nicht zuletzt wegen ihrer strukturellen {\"A}hnlichkeit mit den blattapplizierten Herbiziden Glufosinat und Glyphosat wurden Aminos{\"a}uren als Modellsubstenzen ausgew{\"a}hlt. Die verwendeten Aminos{\"a}uren sind gut wasserl{\"o}slich, wobei alle Oktanol/Wasser Verteilungskoeffizienten kleiner als 1 sind. Zus{\"a}tzlich liegen alle Aminos{\"a}uren in gel{\"o}ster Form als Ionen vor, was zu einer Hydratisierung der Molek{\"u}le f{\"u}hrt. Es wird spekuliert, dass hydratisierte Molek{\"u}le keinen Zugang zur lipophilen Phase der Kutikula haben. Welche Rolle die Hydrath{\"u}lle bei der Permeation tats{\"a}chlich spielt, ist allerdings noch unklar. Viele Aktivwirkstoffe liegen nur unter ganz bestimmten Bedingungen in geladener Form vor, w{\"a}hrend die Richtung der kontinuierlichen Nettoladung der Aminos{\"a}uren durch den pH Wert modifiziert wird. Damit kann der Einfluss verschiedener Ladungszust{\"a}nde auf die kutikul{\"a}re Permeation unter Verwendung eines einheitlichen Sets von Modellsubstanzen untersucht werden. Unter nat{\"u}rlichen Bedingungen sind Aminos{\"a}uren unter anderem auf Blattoberfl{\"a}chen zu finden, wo sie blattassoziierten Mikroorganismen eine profitable Nahrungsquelle bieten. Ob {\"a}ußere Faktoren f{\"u}r die Deposition dieser Recourcen verantwortlich sind, oder ob der Ursprung innerhalb des Blattgewebes liegt, wird kontrovers diskutiert. Die Sorption von Aminos{\"a}uren in isolierte Kutikularmembranen ist sehr gering, und korreliert - anders als bei lipophilen Substanzen - nicht mit dem Oktanol/Wasser Verteilungskoeffizienten. Das zeigt, dass der Verteilung von lipophilen und hydrophilen Substanzen innerhalb der Kutikula verschiedene Mechanismen zu Grunde liegen. Unter einer gegebenen Bedingung werden die kutikul{\"a}ren Leitwerte der Aminos{\"a}uren negativ vom Molvolumen beeinflusst. Zudem {\"u}bersteigt die L{\"a}nge des Permeationswegs die eigentliche Dicke der Membran um ein Vielfaches. Diese Zusammenh{\"a}nge kennzeichnen eine gehinderte Diffusion innerhalb einer engporigen und weit verzweigten Umgebung. Eine {\"A}nderung des pH Wertes wirkt sich in unterschiedlicher Form auf die Leitwerte von Wasser und Aminos{\"a}uren aus. Mit steigendem pH Wert erh{\"o}ht sich die Wasserpermeabilit{\"a}t isolierter Kutikularmembranen, was durch eine zunehmende, messbare Wassersorption in die Kutikula erkl{\"a}rt werden kann. Eine pH abh{\"a}ngige Dissoziation funktioneller Gruppen bewirkt eine Schwellung des polaren Weges, weshalb auch f{\"u}r die anionischen Aminos{\"a}uren bei pH 11 die h{\"o}chsten Leitwerte gemessen wurden. Die zwitterionischen Aminos{\"a}uren bei pH 6 wiesen hingegen die geringsten Leitwerte auf, was im Widerspruch zu der Beobachtung steht, dass bei pH 1 die geringste Wassersorption in die Kutikula stattfindet. Eine Erkl{\"a}rung hierf{\"u}r liefern die Hydrath{\"u}llen, die bei den zwitterionischen Aminos{\"a}uren am st{\"a}rksten und bei den anionischen Species am geringsten ausgepr{\"a}gt sind. Eine negative Korrelation aller gemessenen Aminos{\"a}ureleitwerte mit den entsprechenden hydratisierten Molvolumen zeigt eindeutig, dass die Hydrath{\"u}lle eine wichtige Gr{\"o}ße f{\"u}r die Permeation durch die Kutikula darstellt. Dabei nimmt der Leitwert einer hydrophilen Substanz mit definiertem Molvolumen mit kleiner werdender Hydrath{\"u}lle zu. Intakte Bl{\"a}tter wurden in fl{\"u}ssiges Wasser als Rezeptorl{\"o}sung getaucht, um steady-state Bedingungen aufrecht zu erhalten. Dabei konnte gezeigt werden, dass die Permeabilit{\"a}ten von intakten Kutikularmembranen, die anhand der nat{\"u}rlichen Aminos{\"a}urekonzentration innerhalb der Bl{\"a}tter bestimmt wurden, in derselben Gr{\"o}ßenordnung liegen, wie die f{\"u}r isolierte Membranen gemessenen. Außerdem konnte ein Vergleich der Flussraten auf der Ober- und Unterseite der Bl{\"a}tter zeigen, dass die stomat{\"a}ren Poren nicht direkt in den Leachingprozess involviert sind.},
  subject      = {Permeation},
  language  = {de}
}
@phdthesis{Asmus2016,
  author    = {Asmus, Elisabeth},
  title     = {Mode of Action of Adjuvants for Foliar Application},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-138159},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2016},
  abstract  = {Adjuvants are compounds added to an agrochemical spray formulation to improve or modify the action of an active ingredient (AI) or the physico-chemical characteristics of the spray liquid. Adjuvants can have more than only one distinct mode of action (MoA) during the foliar spray application process and they are generally known to be the best tools to improve agrochemical formulations. The main objective for this work was to elucidate the basic MoA of adjuvants by uncoupling different aspects of the spray application. Laboratory experiments, beginning from retention and spreading characteristics, followed by humectant effects concerning the spray deposit on the leaf surface and ultimately the cuticular penetration of an AI, were figured out to evaluate overall in vivo effects of adjuvants which were also obtained in a greenhouse spray test. For this comprehensive study, the surfactant classes of non-ionic sorbitan esters (Span), polysorbates (Tween) and oleyl alcohol polyglycol ether (Genapol O) were generally considered because of their common promoting potential in agrochemical formulations and their structural diversity. The reduction of interfacial tension is one of the most crucial physico-chemical properties of surfactants. The dynamic surface tension (DST) was monitored to characterise the surface tension lowering behaviour which is known to influence the droplet formation and retention characteristics. The DST is a function of time and the critical time frame of droplet impact might be at about 100 ms. None of the selected surfactants were found to lower the surface tension sufficiently during this short timeframe (chapter I). At ca. 100 ms, Tween 20 resulted in the lowest DST value. When surfactant monomers are fully saturated at the droplet-air-interface, an equilibrium surface tension (STeq) value can be determined which may be used to predict spreading or run-off effects. The majority of selected surfactants resulted in a narrow distribution of STeq values, ranging between 30 and 45 mN m- 1. Nevertheless, all surfactants were able to decrease the surface tension considerably compared to pure water (72 mN m- 1). The influence of different surfactants on the wetting process was evaluated by studying time-dependent static contact angles on different surfaces and the droplet spread area on Triticum aestivum leaves after water evaporation. The spreading potential was observed to be better for Spans than for Tweens. Especially Span 20 showed maximum spreading results. To transfer laboratory findings to spray application, related to field conditions, retention and leaf coverage was measured quantitatively on wheat leaves by using a variable track sprayer. Since the retention process involves short time dynamics, it is well-known that the spray retention on a plant surface is not correlated to STeq but to DST values. The relationship between DST at ca. 100 ms and results from the track sprayer showed increasing retention results with decreasing DST, whereas at DST values below ca. 60 mN m- 1 no further retention improvement could be observed. Under field conditions, water evaporates from the droplet within a few seconds to minutes after droplet deposition on the leaf surface. Since precipitation of the AI must essentially being avoided by holding the AI in solution, so-called humectants are used as tank-mix adjuvants. The ability of pure surfactants to absorb water from the surrounding atmosphere was investigated comprehensively by analysing water sorption isotherms (chapter II). These isotherms showed an exponential shape with a steep water sorption increase starting at 60\% to 70\% RH. Water sorption was low for Spans and much more distinct for the polyethoxylated surfactants (Tweens and Genapol O series). The relationship between the water sorption behaviour and the molecular structure of surfactants was considered as the so-called humectant activity. With an increasing ethylene oxide (EO) content, the humectant activity increased concerning the particular class of Genapol O. However, it could be shown that the moisture absorption across all classes of selected surfactants correlates rather better with their hydrophilic-lipophilic balance values with the EO content. All aboveground organs of plants are covered by the cuticular membrane which is therefore the first rate limiting barrier for AI uptake. In vitro penetration experiments through an astomatous model cuticle were performed to study the effects of adjuvants on the penetration of the lipophilic herbicide Pinoxaden (PXD) (chapter III). In order to understand the influence of different adjuvant MoA like humectancy, experiments were performed under three different humidity levels. No explicit relationship could be found between humidity levels and the PXD penetration which might be explained by the fact that humidity effects would rather affect hydrophilic AIs than lipophilic ones. Especially for Tween 20, it became obvious that a complex balance between multiple MoA like spreading, humectancy and plasticising effects have to be considered. Greenhouse trials, focussing the adjuvant impact on in vivo action of PXD, were evaluated on five different grass-weed species (chapter III). Since agrochemical spray application and its following action on living plants also includes translocation processes in planta and species dependent physiological effects, this investigation may help to simulate the situation on the field. Even though the absolute weed damage was different, depending both on plant species and also on PXD rates, adjuvant effects in greenhouse experiments displayed the same ranking as in cuticular penetration studies: Tween 20 > Tween 80 > Span 20 ≥ Span 80. Thus, the present work shows for the first time that findings obtained in laboratory experiments can be successfully transferred to spray application studies on living plants concerning adjuvant MoA. A comparative analysis, using radar charts, could demonstrate systematic derivations from structural similarities of adjuvants to their MoA (summarising discussion and outlook). Exemplarily, Tween 20 and Tween 80 cover a wide range of selected variables by having no outstanding MoA improving one distinct process during foliar application, compared to non-ethoxylated Span 20 and Span 80 which primarily revealed a surface active action. Most adjuvants used in this study represent polydisperse mixtures bearing a complex distribution of EO and aliphatic chains. From this study it seems alike that adjuvants having a wide EO distribution offer broader potential than adjuvants with a small EO distribution. It might be a speculation that due to this broad distribution of single molecules, all bearing their individual specific physico-chemical nature, a wide range of properties concerning their MoA is covered.},
  subject      = {Adjuvans},
  language  = {en}
}
@phdthesis{Brandstaetter2010,
  author    = {Brandstaetter, Andreas Simon},
  title     = {Neuronal correlates of nestmate recognition in the carpenter ant, Camponotus floridanus},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-55963},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2010},
  abstract  = {Cooperation is beneficial for social groups and is exemplified in its most sophisticated form in social insects. In particular, eusocial Hymenoptera, like ants and honey bees, exhibit a level of cooperation only rarely matched by other animals. To assure effective defense of group members, foes need to be recognized reliably. Ants use low-volatile, colony-specific profiles of cuticular hydrocarbons (colony odor) to discriminate colony members (nestmates) from foreign workers (non-nestmates). For colony recognition, it is assumed that multi-component colony odors are compared to a neuronal template, located in a so far unidentified part of the nervous system, where a mismatch results in aggression. Alternatively, a sensory filter in the periphery of the nervous system has been suggested to act as a template, causing specific anosmia to nestmate colony odor due to sensory adaptation and effectively blocking perception of nestmates. Colony odors are not stable, but change over time due to environmental influences. To adjust for this, the recognition system has to be constantly updated (template reformation). In this thesis, I provide evidence that template reformation can be induced artificially, by modifying the sensory experience of carpenter ants (Camponotus floridanus; Chapter 1). The results of the experiments showed that template reformation is a relatively slow process taking several hours and this contradicts the adaptation-based sensory filter hypothesis. This finding is supported by first in-vivo measurements describing the neuronal processes underlying template reformation (Chapter 5). Neurophysiological measurements were impeded at the beginning of this study by the lack of adequate technical means to present colony odors. In a behavioral assay, I showed that tactile interaction is not necessary for colony recognition, although colony odors are of very low volatility (Chapter 2). I developed a novel stimulation technique (dummy-delivered stimulation) and tested its suitability for neurophysiological experiments (Chapter 3). My experiments showed that dummy-delivered stimulation is especially advantageous for presentation of low-volatile odors. Colony odor concentration in headspace was further increased by moderately heating the dummies, and this allowed me to measure neuronal correlates of colony odors in the peripheral and the central nervous system using electroantennography and calcium imaging, respectively (Chapter 4). Nestmate and non-nestmate colony odor elicited strong neuronal responses in olfactory receptor neurons of the antenna and in the functional units of the first olfactory neuropile of the ant brain, the glomeruli of the antennal lobe (AL). My results show that ants are not anosmic to nestmate colony odor and this clearly invalidates the previously suggested sensory filter hypothesis. Advanced two-photon microscopy allowed me to investigate the neuronal representation of colony odors in different neuroanatomical compartments of the AL (Chapter 5). Although neuronal activity was distributed inhomogeneously, I did not find exclusive representation restricted to a single AL compartment. This result indicates that information about colony odors is processed in parallel, using the computational power of the whole AL network. In the AL, the patterns of glomerular activity (spatial activity patterns) were variable, even in response to repeated stimulation with the same colony odor (Chapter 4\&5). This finding is surprising, as earlier studies indicated that spatial activity patterns in the AL reflect how an odor is perceived by an animal (odor quality). Under natural conditions, multi-component odors constitute varying and fluctuating stimuli, and most probably animals are generally faced with the problem that these elicit variable neuronal responses. Two-photon microscopy revealed that variability was higher in response to nestmate than to non-nestmate colony odor (Chapter 5), possibly reflecting plasticity of the AL network, which allows template reformation. Due to their high variability, spatial activity patterns in response to different colony odors were not sufficiently distinct to allow attribution of odor qualities like 'friend' or 'foe'. This finding challenges our current notion of how odor quality of complex, multi-component odors is coded. Additional neuronal parameters, e.g. precise timing of neuronal activity, are most likely necessary to allow discrimination. The lower variability of activity patterns elicited by non-nestmate compared to nestmate colony odor might facilitate recognition of non-nestmates at the next level of the olfactory pathway. My research efforts made the colony recognition system accessible for direct neurophysiological investigations. My results show that ants can perceive their own nestmates. The neuronal representation of colony odors is distributed across AL compartments, indicating parallel processing. Surprisingly, the spatial activity patterns in response to colony are highly variable, raising the question how odor quality is coded in this system. The experimental advance presented in this thesis will be useful to gain further insights into how social insects discriminate friends and foes. Furthermore, my work will be beneficial for the research field of insect olfaction as colony recognition in social insects is an excellent model system to study the coding of odor quality and long-term memory mechanisms underlying recognition of complex, multi-component odors.},
  subject      = {Neuroethologie},
  language  = {en}
}
@phdthesis{Forster2006,
  author    = {Forster, Wilhelmina Alison},
  title     = {Mechanisms of cuticular uptake of xenobiotics into living plants},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-21240},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2006},
  abstract  = {The objective of this Thesis was to progress the understanding of the mechanisms of cuticular uptake into living plant foliage, thereby enabling uptake of important compounds such as pesticides and pollutants to be modelled. The uptake of three model compounds, applied in the presence and absence of surfactants, into the leaves of three plant species (Chenopodium album L., Hedera helix L. and Stephanotis floribunda Brongn) was determined. The results with 2-deoxy-D-glucose (DOG), 2,4-dichlorophenoxy-acetic acid (2,4-D) and epoxiconazole in the presence of surfactants (the polyethylene glycol monododecyl ethers C12EO3, C12EO6, C12EO10, and a trisiloxane ethoxylate with mean ethylene oxide (EO) content of 7.5, all used at one equimolar concentration) illustrated that the initial dose (nmol mm-2) of xenobiotic applied to plant foliage was a strong positive determinant of uptake. Using this new approach for whole plant uptake, uptake on a per unit area basis was found to be related to initial dose of xenobiotic applied, by an equation of the form: Uptake(nmol mm-2) = a [ID]b at time t = 24 hours, where ID is the initial dose or the mass of xenobiotic applied per unit area (M(nmol xenobiotic applied)/A(droplet spread area)). Total mass uptake can then be calculated from an equation of the form: Total Uptake(nmol) = a [ID]b.A. In order to verify this relationship, further studies determined the uptake of three pesticides, applied as commercial and model formulations in the presence of a wide range of surfactants, into the leaves of three plant species (bentazone into Chenopodium album L. and Sinapis alba L., epoxiconazole and pyraclostrobin into Triticum aestivum L.). The results confirmed that the initial dose (nmol mm-2) of xenobiotic applied to plant foliage is a strong, positive determinant of uptake. In a novel approach, further studies used this relationship (nmol mm-2 uptake versus ID; termed the uptake ratio) to establish the relative importance of species, active ingredient (AI), AI concentration (g L-1) and surfactant to uptake. Species, AI, its concentration, and surfactant all significantly affected the uptake ratio. Overall, 88\% of the deviance could be explained. More useful was the analysis of the individual xenobiotics, where the models explained 83\%, 85\%, and 94\% of the variance in uptake ratio for DOG, 2,4-D, and epoxiconazole, respectively. In all cases, species, surfactant, and AI concentration significantly affected the uptake ratio. However, there were differences in the relative importance of these factors among the xenobiotics studied. Concentration of AI increased in importance with increasing lipophilicity of AI, while species was much less important for the most lipophilic compound. Surfactant became less important with increasing AI lipophilicity, although it was always important. The preceding studies considered uptake at only one time interval (24 hours). Total uptake after 24 hours can be the same for a compound formulated with different surfactants, but rates of uptake (and therefore rain-fastness and subsequent translocation to target sites) can be quite different. Therefore, there was a requirement to be able to model uptake over time into whole plants. Hence, the objective of further studies was to determine whether a logistic-kinetic penetration model, developed using isolated plant cuticles, could be applied to whole plant uptake. Uptake over 24 hours was determined for three model compounds, applied in the presence and absence of surfactants, into the leaves of two plant species. Overall, the model fitted the whole plant uptake data well. Using the equations developed, based on initial dose, to calculate uptake at 24 hours, in conjunction with the logistic-kinetic model, has significantly progressed our understanding and ability to model uptake. The advantages of the models and equations described are that few variables are required, and they are simple to measure.},
  subject      = {Kutikula},
  language  = {en}
}
@phdthesis{Kunz2023,
  author    = {Kunz, Marcel},
  title     = {Diffusion kinetics of organic compounds and water in plant cuticular model wax under the influence of diffusing barrier-modifying adjuvants},
  doi       = {10.25972/OPUS-27487},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-274874},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2023},
  abstract  = {To reach their target site, systemic pesticides must enter the plant from a spray droplet applied in the field. The uptake of an active ingredient (AI) takes place via the barrier-forming cuticular membrane, which is the outermost layer of the plant, separating it from the surrounding environment. Formulations are usually used which, in addition to the AI, also contain stabilizers and adjuvants. Adjuvants can either have surface-active properties or they act directly as barrier-modifying agents. The latter are grouped in the class of accelerating adjuvants, whereby individual variants may also have surface-active properties. The uptake of a pesticide from a spray droplet depends essentially on its permeability through the cuticular barrier. Permeability defines a combined parameter, which is the product of AI mobility and AI solubility within the cuticle. In recent decades, several tools have been developed that allowed the determination of individual parameters of organic compound penetration across the cuticular membrane. Nevertheless, earlier studies showed that mainly cuticular waxes are the barrier-determining component of the cuticular membrane and additionally, it was shown that mainly the very-long-chain aliphatic compounds (VLCAs) are responsible for establishing an effective barrier. However, the barrier-determining role of the individual VLCAs, being classified according to their respective functional groups, is still unknown. Therefore, the following objectives were pursued and achieved in this work: (1) A new ATR-FTIR-based approach was developed to measure the temperature-dependent real-time diffusion kinetics of organic models for active ingredients (AIs) in paraffin wax, exclusively consisting of very-long chain alkanes. (2) The developed ATR-FTIR approach was applied to determine the diffusion kinetics of self-accelerating adjuvants in cuticular model waxes of different VLCA composition. At the same time, wax-specific changes were recorded in the respective IR spectra, which provided information about the respective wax modification. (3) The ATR-FTIR method was used to characterize the diffusion kinetics, as well as to determine the wax-specific sorption capacities for an AI-modeling organic compound and water in cuticular model waxes after adjuvant treatment. Regarding the individual chemical compositions and structures, conclusions were drawn about the adjuvant-specific modes of action (MoA). In the first chapter, the ATR-FTIR based approach to determine organic compound diffusion kinetics in paraffin wax was successfully established. The diffusion kinetics of the AI modelling organic compounds heptyl parabene (HPB) and 4-cyanophenol (CNP) were recorded, comprising different lipophilicities and molecular volumes typical for AIs used in pesticide formulations. Derived diffusion coefficients ranged within 10-15 m2 s-1, thus being thoroughly higher than those obtained from previous experiments using an approach solely investigating desorption kinetics in reconstituted cuticular waxes. An ln-linear dependence between the diffusion coefficients and the applied diffusion temperature was demonstrated for the first time in cuticular model wax, from which activation energies were derived. The determined activation energies were 66.2 ± 7.4 kJ mol-1 and 56.4 ± 9.8 kJ mol-1, being in the expected range of already well-founded activation energies required for organic compound diffusion across cuticular membranes, which again confirmed the significant contribution of waxes to the cuticular barrier. Deviations from the assumed Fickian diffusion were attributed to co-occurring water diffusion and apparatus-specific properties. In the second and third chapter, mainly the diffusion kinetics of accelerating adjuvants in the cuticular model waxes candelilla wax and carnauba wax were investigated, and simultaneously recorded changes in the wax-specific portion of the IR spectrum were interpreted as indications of plasticization. For this purpose, the oil derivative methyl oleate, as well as the organophosphate ester TEHP and three non-ionic monodisperse alcohol ethoxylates (AEs) C12E2, C12E4 and C12E6 were selected. Strong dependence of diffusion on the respective principal components of the mainly aliphatic waxes was demonstrated. The diffusion kinetics of the investigated adjuvants were faster in the n-alkane dominated candelilla wax than in the alkyl ester dominated carnauba wax. Furthermore, the equilibrium absorptions, indicating equilibrium concentrations, were also higher in candelilla wax than in carnauba wax. It was concluded that alkyl ester dominated waxes feature higher resistance to diffusion of accelerating adjuvants than alkane dominated waxes with shorter average chain lengths due to their structural integrity. This was also found either concerning candelilla/policosanol (n-alcohol) or candelilla/rice bran wax (alkyl-esters) blends: with increasing alcohol concentration, the barrier function was decreased, whereas it was increased with increasing alkyl ester concentration. However, due to the high variability of the individual diffusion curves, only a trend could be assumed here, but significant differences were not shown. The variability itself was described in terms of fluctuating crystalline arrangements and partial phase separation of the respective wax mixtures, which had inevitable effects on the adjuvant diffusion. However, diffusion kinetics also strongly depended on the studied adjuvants. Significantly slower methyl oleate diffusion accompanied by a less pronounced reduction in orthorhombic crystallinity was found in carnauba wax than in candelilla wax, whereas TEHP diffusion was significantly less dependent on the respective wax structure and therefore induced considerable plasticization in both waxes. Of particular interest was the AE diffusion into both waxes. Differences in diffusion kinetics were also found here between candelilla blends and carnauba wax. However, these depended equally on the degree of ethoxylation of the respective AEs. The lipophilic C12E2 showed approximately Fickian diffusion kinetics in both waxes, accompanied by a drastic reduction in orthorhombic crystallinity, especially in candelilla wax, whereas the more hydrophilic C12E6 showed significantly retarded diffusion kinetics associated with a smaller effect on orthorhombic crystallinity. The individual diffusion kinetics of the investigated adjuvants sometimes showed drastic deviations from the Fickian diffusion model, indicating a self-accelerating effect. Hence, adjuvant diffusion kinetics were accompanied by a distinct initial lag phase, indicating a critical concentration in the wax necessary for effective penetration, leading to sigmoidal rather than to exponential diffusion kinetics. The last chapter dealt with the adjuvant-affected diffusion of the AI modelling CNP in candelilla and carnauba wax. Using ATR-FTIR, diffusion kinetics were recorded after adjuvant treatment, all of which were fully explicable based on the Fickian model, with high diffusion coefficients ranging from 10-14 to 10-13 m2 s-1. It is obvious that the diffusion coefficients presented in this work consistently demonstrated plasticization induced accelerated CNP mobilities. Furthermore, CNP equilibrium concentrations were derived, from which partition- and permeability coefficients could be determined. Significant differences between diffusion coefficients (mobility) and partition coefficients (solubility) were found on the one hand depending on the respective waxes, and on the other hand depending on treatment with respective adjuvants. Mobility was higher in candelilla wax than in carnauba wax only after methyl oleate treatment. Treatment with TEHP and AEs resulted in higher CNP mobility in the more polar alkyl ester dominated carnauba wax. The partition coefficients, on the other hand, were significantly lower after methyl oleate treatment in both candelilla and carnauba wax as followed by TEHP or AE treatment. Models were designed for the CNP penetration mode considering the respective adjuvants in both investigated waxes. Co-penetrating water, which is the main ingredient of spray formulations applied in the field, was likely the reason for the drastic differences in adjuvant efficacy. Especially the investigated AEs favored an enormous water uptake in both waxes with increasing ethoxylation level. Surprisingly, this effect was also found for the lipophilic TEHP in both waxes. This led to the assumption that the AI permeability is not exclusively determined by adjuvant induced plasticization, but also depends on a "secondary plasticization", induced by adjuvant-attracted co-penetrating water, consequently leading to swelling and drastic destabilization of the crystalline wax structure. The successful establishment of the presented ATR-FTIR method represents a milestone for the study of adjuvant and AI diffusion kinetics in cuticular waxes. In particular, the simultaneously detectable wax modification and, moreover, the determinable water uptake form a perfect basis to establish the ATR-FTIR system as a universal screening tool for wax-adjuvants-AI-water interaction in crop protection science.},
  subject      = {Pflanzen},
  language  = {en}
}
@phdthesis{Leide2008,
  author    = {Leide, Jana},
  title     = {Cuticular Wax Biosynthesis of Lycopersicon esculentum and Its Impact on Transpiration Barrier Properties during Fruit Development},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-34526},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2008},
  abstract  = {Cuticular waxes cover all above-ground growing parts of plants. They provide the outermost contact zone between plants and their environment and play a pivotal role in limiting transpirational water loss across the plant surface. The complex mechanisms in cuticular wax biosynthesis conferring proper barrier function still remain to be elucidated. The present study focuses on biosynthetic pathways in wax formation, cuticular wax accumulation and composition and its impact on the epidermal barrier property of the intact system of the astomatous tomato fruit (Lycopersicon esculentum Mill.). Fruits of all developmental stages of the wild type cultivar MicroTom and its lecer6 mutant defective in a \&\#946;-ketoacyl-CoA synthase involved in very-long-chain fatty acid elongation were analyzed. This 'reverse genetic' approach clarified the importance of the \&\#946;-ketoacyl-CoA synthase LeCER6 for epidermal barrier property in vivo on the biochemical-analytical level, on the transcriptional level and, furthermore, on the physiological level comparatively between MicroTom wild type and MicroTom lecer6. Surfaces of MicroTom wild type and MicroTom lecer6 fruits showed similar patterns of quantitative wax accumulation, but differed considerably in the permeance for water. Qualitative analyses of the chemical composition of fruit cuticular waxes in the course of fruit development revealed the meaning of the \&\#946;-ketoacyl-CoA synthase deficiency in the lecer6 mutant. Fruits of this mutant exhibited a distinct decrease in the proportion of n-alkanes of chain lengths > C28. Moreover, a concomitant increase in pentacyclic triterpenoids became discernible in the mature green fruit stage of the mutant. Since quantitative changes of the cutin matrix were not sufficient to affect transpiration barrier properties of the lecer6 mutant presumably the shift in cuticular wax biosynthesis of the lecer6 mutant is responsible for the observed increase of water permeance. In order to investigate the molecular basis of wax formation, a microarray experiment was established that allows the simultaneous and comprehensive analysis of the timing and abundance of transcriptional changes in MicroTom wild type and MicroTom lecer6. This microarray consists of 167 oligonucleotides corresponding to EST and gene sequences of tomato potentially participating in wax biosynthesis, wax modification, transport processes and stress responsiveness. These parameters were correlated with the course of fruit development. This comparison of gene expression patterns showed a variety of differential expressed transcripts encoding for example lipid transfer proteins and the dehydrin TAS14. On the basis of these findings, it can be proposed that diverse regulatory mechanisms like lipid transfer processes or osmotic stress response are affected by the LeCER6 deficiency, which is primarily accompanied by an impaired water barrier property of the fruit cuticle. This present study correlates the continuous increase of LeCer6 gene expression and the accumulation of very-long-chain n-alkanes within the cuticular waxes during the transition from the immature green to the early breaker fruit phase displaying a developmental regulation of the cuticular wax biosynthesis. Organ-specific wax biosynthesis resulted in different cuticular wax pattern in tomato fruits and leaves. Moreover, in contrast to the fruits, LeCER6-deficient leaves showed a significantly reduced wax accumulation, mainly due to a decrease of n-alkanes with chain lengths > C30, while the proportion of pentacyclic triterpenoids were not affected. Deduced from these biochemical-analytical data on tomato fruits and leaves LeCER6 was characterized as a key enzyme in VLCFA biosynthetic pathway responsible for cuticular wax accumulation. In silico analysis of the LeCER6 sequence revealed the presence of two putative transmembrane domains in the N-terminal position. In addition, highly conserved configurations of catalytic residues in the active site of the enzyme were observed, which are probably essential to its overall structure and function in the fatty acid elongation process. High sequence homology of LeCER6 to the very-long-chain condensing enzymes GhCER6 of Gossypium hirsutum L. and AtCER6 of Arabidopsis thaliana (L.) Heynh. was found, which might be a good evidence for similar biochemical functions. Apart from developmental regulation of the cuticular wax biosynthesis, environmental factors influenced the cuticular wax coverage of tomato fruits. Mechanical removal of epicuticular fruit wax evoked large-scale modifications of the quantitative and qualitative wax composition, such as a reduction of aliphatic wax components, and therewith affected the cuticular water permeability. A subsequent regeneration event was included in the regular wax biosynthesis process and led to the compensation of the detached wax amounts and increased the water barrier properties of the cuticular membrane again. In contrast, water-limited conditions had only minor impact on alterations in cuticular wax biosynthesis and, consequently, on the permeance for water of tomato fruits. Floral organ fusion and conditional sterility, as observed in this study, are caused as pleiotropic effects in cell-cell signaling by the loss-of-function mutation in LeCER6. These findings corroborated the functional impact of LeCER6 on the epidermal integrity and are consistent with the current knowledge on eceriferum mutants of Arabidopsis. Investigations of phenotypic and biochemical characteristics of tomato fruits allowed a broader system-orientated perspective of the fruit development of MicroTom wild type and its lecer6 mutant. These analyses highlight more precisely alterations in the fruit surface area, fresh and dry weight, epidermal cell density, photosynthetic activity or glucose content in the course of fruit development. The differences between MicroTom wild type and MicroTom lecer6 characterize very well the large-scale consequences of the LeCER6 deficiency on the physiological status of tomato fruits. Moreover, the results clearly show a part of the genetic controlled network that governs tomato fruit metabolism and mediates extensive changes of the tomato fruit life cycle. The analyses of the stem scar tissue of the tomato fruit revealed a complex set of responses caused by the harvesting process in detail. Throughout storage of the tomato fruits barrier properties were attributed to the suberized stem scar tissue in regard to water loss limitation and reduction of the fungal infection rate. Thereby the endogenous level of abscisic acid was found to be involved in the molecular signaling pathway that regulates the de novo formation of this tissue. For the first time, the chemical composition and physiological importance could be correlated with molecular changes at the transcriptional level during suberization of the stem scar of tomato fruits. In conclusion, this work indicates a novel intact model system for an integrative functional approach for plant barrier properties that was successfully established and carefully studied. The results highlight correlations between wax biosynthesis, distribution of cuticular waxes, and its relevance on the transpirational water loss across the plant surface and, thus, promote the global understanding of plant cuticle biology.},
  subject      = {Wachs},
  language  = {en}
}
@phdthesis{Popp2005,
  author    = {Popp, Christian},
  title     = {Cuticular transport of hydrophilic molecules with special focus on primary metabolites and active ingredients},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-15174},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2005},
  abstract  = {The plant cuticle as an interface between the plant interior and the adjoining atmosphere plays an important role in any interaction between the plant and its environment. Transport processes across the cuticles were the object of countless research since many decades. However, bulk of the work done was focused on transport of lipophilic molecules. It is highly plausible to examine the penetration of lipophilic compounds, since the cuticle is dominated by lipophilic compartments itself, and the most crop protection agents have lipophilic character. As a result of this research, cuticular transport of lipophilic compounds is relatively well understood. Since several years, examinations were expanded on transport of hydrophilic molecules. In the present study, a direct comparison was made between transport properties of lipophilic and hydrophilic compounds, which allows an objective assessment of the mechanism governing their penetration. The results of this present study debunked the existence of two different pathways across isolated cuticles of Hedera helix (English ivy), a lipophilic and a hydrophilic pathway. This finding was supported by examinations regarding to accelerator and temperature effects on the mobility of both pathways, because the hydrophilic path is insensitive to them - in contrary to the lipophilic one. The lipophilic pathway is rigorously restricted to lipophilic molecules and the hydrophilic pathway is only accessible for hydrophilic molecules. Uncharged hydrophilic compounds can cross the cuticle even the molecules are of relatively large dimensions. In contrast to that, dissociable compounds with a molar volume higher than 110 cm³ mol-1 are excluded from cuticular penetration. Differences in the mobility of uncharged and dissociable molecules might be a hint towards the chemical nature of the polar pathways. It is assumed, that both, cellulose and pectin fibrils, traverse the cuticle which are originated from the epidermal cell wall. While uncharged carbohydrates might be able to penetrate across a pathway made up of cellulose and pectin, dissociated amino acids might be restricted to the cellulose path. This could be a plausible explanation for the higher mobility and the higher cuticle/water partition coefficients of the carbohydrates compared with the amino acids. A hydrophilic pathway was found with isolated grapevine cuticles, too. The apparent size selectivity of the hydrophilic pathway implies transport via narrow pores. From the present data, a mean pore radius of 0.31 nm (H. helix) or rather 0.34 nm (V. vinifera) was calculated. The absolute number of pores per cm² is 1.1 x 109 for H. helix and 3.3 x 109 for V. vinifera cuticles. This finding and the enlarged pore size distribution of grapevine cuticles might be an explanation for the transport of uncharged and dissociable hydrophilic compounds of higher molar volume like paraquat dichloride - in contrast to ivy membranes Wax extraction of ivy membranes uncovers additional pores, which explains the increased mobilities of the hydrophilic compounds across dewaxed membranes. From these extensive measurements it is very conspicuous, that the bulk of cuticular water transpiration occurs via the polar pathway. Since the work was focused on cuticular penetration of primary metabolites like amino acids and carbohydrates, a mechanistic explanation of leaching processes is obtained, simultaneously. In cuticular research, an inconsistent terminology regarding the transport path of the hydrophilic compounds was used. The term 'hydrophilic pathway' is definitely correct, since it makes no statement with regard to the shape of this path. In contrast to that, the terms 'polar pore' or 'aqueous pore' could imply that there is a tube or rather a water-filled tube traversing the cuticle. However - at this point of time - the imagination about the shape of this path is a pathway across interfibrilar gaps within polysaccharide strains. The proposed diameter of these interfibrilar gaps fits very well to the diameter determined in this study. Therefore, the imagination of a pore is not unfounded, but it is a very narrow pore, definitely. Additionally, this pathway is a very straight pathway which corresponds to this simplified imagination. An expanded study was done with paraquat dichloride, which was applied as aqueous droplets on grapevine cuticles. It is assumed that these model membranes reflect transport properties which are very close to that of relevant crops and weeds. The predominating parameter for paraquat penetration is the moisture, either originated from a relative humidity of at least 75\% or provided by added chemicals. There is a tendency for good suitability of hygroscopic additives. Increased paraquat penetration was also obtained by raised concentrations and removal of the cuticular waxes.},
  subject      = {Kutikula},
  language  = {en}
}
@phdthesis{Reisberg2013,
  author    = {Reisberg, Eva},
  title     = {Der Einfluss von Trichomen und kutikul{\"a}ren Lipiden auf die bakterielle Besiedelung von Arabidopsis thaliana-Bl{\"a}ttern},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-83971},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2013},
  abstract  = {Die oberirdischen Oberfl{\"a}chen von Pflanzen sind von komplexen mikrobiellen Konsortien besiedelt deren Zusammensetzung von verschiedenen Faktoren abh{\"a}ngig ist. In der vorliegenden Promotionsarbeit wurden zwei Eigenschaften pflanzlicher Oberfl{\"a}chen auf m{\"o}gliche Auswirkungen auf ihre bakterielle Besiedelung hin untersucht. Dazu wurden Wildtyplinien und Mutanten von Arabidopsis thaliana eingesetzt. Zun{\"a}chst wurde die bakterielle Besiedelung von A. thaliana Wildtyplinien in kultivierungsbasierten Experimenten untersucht. Es wurde hierbei ein {\"U}berblick {\"u}ber die kultivierbare Diversit{\"a}t auf Pflanzen, die unter kontrollierten Bedingungen im Klimaschrank gewachsen waren und Pflanzen, die einen Freilandaufenthalt durchlaufen hatten, gewonnen. Der Einfluss von nicht-dr{\"u}sigen Trichomen von A. thaliana auf die Quantit{\"a}t und Diversit{\"a}t der bakteriellen Besiedelung wurde am A. thaliana Col-0-Wildtyp mit normaler Behaarung und der trichomlosen gl1-Mutante untersucht. Mithilfe von DAPI-F{\"a}rbungen und nachfolgender Zellz{\"a}hlung wurden die bakteriellen Gemeinschaften der beiden Pflanzenlinien quantifiziert. Dabei zeigten sich keine pflanzenlinienspezifischen Unterschiede. Durch die Amplifizierung der bakteriellen 16S rRNA-Gene der Gemeinschaft und den nachfolgenden Einsatz der Denaturierenden Gradientengelelektrophorese (DGGE) wurde ein {\"U}berblick {\"u}ber die Diversit{\"a}t der vorherrschenden Bakteriengruppen gewonnen. Obwohl Trichome als bevorzugte Siedlungspl{\"a}tze von Bakterien gelten, wurden hier auch hinsichtlich der Diversit{\"a}t der bakteriellen Gemeinschaften keine Unterschiede zwischen den untersuchten Pflanzenlinien gefunden. Als weiteres artspezifisches Merkmal von Pflanzenoberfl{\"a}chen wurde die Zusammensetzung der kutikul{\"a}ren Wachse als Einflussfaktor untersucht. Daf{\"u}r wurden vier eceriferum-Mutanten (cer) von A. thaliana in Landsberg erecta (Ler) Wildtyp-Hintergrund eingesetzt, die sich hinsichtlich der kutikul{\"a}ren Wachszusammensetzung ihrer Bl{\"a}tter unterschieden. Zur Untersuchung der Diversit{\"a}t der bakteriellen Besiedelung wurde zun{\"a}chst ein DGGE-Screening durchgef{\"u}hrt. Hier zeigten sich deutliche pflanzenlinienspezifische Unterschiede, die vor allem die Gemeinschaften der cer9- und der cer16-Mutante betrafen. Zur genaueren Charakterisierung der bakteriellen Gemeinschaften der f{\"u}nf Pflanzenlinien wurde die Amplicon-Pyrosequenzierung eingesetzt. Hierbei stellte sich die bakterielle Diversit{\"a}t auf allen Pflanzenlinien entsprechend des Phyllosph{\"a}renhabitats moderat divers und ungleich verteilt dar. Die Identifizierung der sequenzierten Phylotypen ließ eine bakterielle Kerngemeinschaft erkennen. Weiterhin wurden 35 Phylotypen identifiziert, die differenziell auf einzelnen Pflanzenlinien auftraten. Hier handelte es sich um den pflanzenlinienspezifischen Teil der bakteriellen Gemeinschaften. Die statistische Analyse zeigte deutlich divergente Muster f{\"u}r die analysierten Bakteriengemeinschaften der f{\"u}nf Pflanzenlinien. Vor allem die Gemeinschaften der cer6-, cer9- und cer16-Linie konnten in einer UniFrac-basierten Clusteranalyse von den anderen Pflanzenlinien abgegrenzt werden. Diese Ergebnisse zeigen klar, dass die Mutationen in der Wachsbiosynthese zu divergenten bakteriellen Gemeinschaften f{\"u}hrten.},
  subject      = {Ackerschmalwand},
  language  = {de}
}
@phdthesis{Schuster2016,
  author    = {Schuster, Ann-Christin},
  title     = {Chemical and functional analyses of the plant cuticle as leaf transpiration barrier},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-133475},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2016},
  abstract  = {Cuticles cover all above-ground primary plant organs and are lipoid in nature consisting of a cutin matrix with cuticular waxes embedded within or deposited on its surface. The foremost function of the plant cuticle is the limitation of transpirational water loss into the surrounding atmosphere. Transpiration of water vapour from plants differs between stomatal and cuticular transpiration. Stomatal closure minimises the stomatal water loss and the remaining, much lower water transpiration occurs through the plant cuticle. Temperature influence on the transpiration barrier properties of intact leaves is not yet known, despite the importance of the cuticular transpiration especially under drought and heat conditions. The present study focuses on the temperature-dependent minimum water permeability of whole leaves, in comparison to the temperature effect on the cuticular permeance of isolated, astomatous cuticles (Chapter I - III). The minimum water permeability was determined gravimetrically from leaf drying curves and represents the cuticular water permeability of intact, stomatous leaves under conditions of complete stomatal closure. The temperature effect on the transpiration barrier of the desert plant Rhazya stricta and the Mediterranean sclerophyll Nerium oleander exposed a continuous increase of minimum water permeabilities with an increase in temperature. In contrast to other published studies, no abrupt and steep increase of the water permeability at high temperatures was detected. This steep increase indicates structural changes of the barrier properties of isolated cuticular membranes with a drastic decrease of efficiency. A stabilising impact of the cell wall on the plant cuticle of intact leaves was proposed. This steadying effect was confirmed with different experimental approaches measuring the cuticular water permeability of Prunus laurocerasus intact leaves. Physiological analysis of water transport on isolated, astomatous leaf cuticles indicated a drastic decline of the barrier properties at elevated temperatures for Prunus laurocerasus but not for Nerium oleander. Cuticular components were quantitatively and qualitatively analysed by gas chromatography with a flame ionisation detector and a mass spectrometric detector, respectively. A high accumulation of pentacyclic triterpenoids as cuticular wax components in relation to the cutin monomer coverage was detected for Nerium oleander and for Rhazya stricta leaves, too. Accordingly, reinforcing of the cutin matrix by triterpenoids was proposed to improve the mechanical strength and to reduce the extensibility of plant cuticles. Thus, structural changes of the cuticular barrier properties were potentially suppressed at elevated temperatures. The function of the cuticular wax amount and/or wax composition and its relation with the cuticular water permeability remains to be elucidated. In the second part of this work the cuticular wax quantity and quality as well as its impact on the transpiration barrier properties was analysed in order to deduce a potential relation between chemistry and function of plant cuticles (Chapter IV - V). Chemical analyses of the cuticular wax components of a wide range of plant species, including one tropical (Vanilla planifolia), temperate (Juglans regia, Plantago lanceolata), Mediterranean (Nerium oleander, Olea europaea) and one desert (Rhazya stricta) plant species, were conducted. The cuticular wax compositions of nine characteristic plant species from xeric limestone sites naturally located in Franconia (Southern Germany) were determined for the first time. The corresponding minimum or cuticular water permeabilities of both stomatous and astomatous leaf surfaces were measured to detect a potential relationship between the cuticular wax amount, wax composition and the cuticular barrier properties. It was demonstrated that abundant cuticular wax amounts did not constitute more efficient transpiration barriers. However, 55\% of the cuticular barrier function can be attributed to the very-long-chain aliphatic wax coverages. These new findings provide evidence that the acyclic wax constituents play a pivotal role establishing efficient transpiration barriers. Additionally, these findings strengthen the hypothesis that cyclic components, such as pentacyclic triterpenoids, do not hinder the water diffusion through plant cuticles as effectively as acyclic constituents. For the first time a relationship between the cuticular wax composition and the transpiration barrier properties of a wide range of plant species proved insights into the potential relation between chemistry and function of plant cuticles.},
  subject      = {Kutikula},
  language  = {en}
}
@phdthesis{Seufert2021,
  author    = {Seufert, Pascal},
  title     = {Chemical and physical structure of the barrier against water transpiration of leaves: Contribution of different wax compounds},
  doi       = {10.25972/OPUS-20896},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-208963},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2021},
  abstract  = {The cuticle is constituted of the biopolymer cutin and intra- and epicuticular waxes. In some cases, it has epicuticular wax crystals, protruding from the epicuticular wax film. One of the most important tasks is protection against desiccation. Many investigations were conducted to find the transport limiting component of the cuticle. It is evidentially confirmed that the waxes form this barrier. These waxes are multifactorial blends made of very-long-chain aliphatic (VLCA) compounds and triterpenoids (TRP). The VLCAs were proposed to constitute the transpiration barrier to water. However, experimental confirmation was lacking so far. The present study focuses on the development of a method to selectively extract TRPs from the cuticle and the impact of the removal on the transpiration barrier. The plants deployed in this study exhibited several features. They had no epicuticular crystals on their surfaces, were astomatous, had a rather durable and possibly isolatable cuticle. A broad range of wax compositions was covered from plants with no TRP content and low wax load like Hedera helix and Zamioculcas zamiifolia to plants with high TRP content and high wax load like Nerium oleander. The selective extraction was conducted using a sequence of solvents. TRPs were extracted almost exhaustively from CMs with the first MeOH extract. Only a minor amount of shorter chained VLCAs was obtained. The remaining waxes, consisting mostly of VLCAs and some remnant TRPs, were removed with the following TCM extract. After the extractions, the water permeance of native cuticular membranes (CM), MeOH extracted (M) and dewaxed cuticular discs (MX) was investigated gravimetrically. Compared to the water permeance of CMs, Ms showed no or only a small increase in water conductance. MXs, however, always showed strongly increased values. The knowledge about the wax compounds constituting the transport-limiting properties is vital for different projects. For various issues, it would be favourable to have a standardized wax mixture as an initial point of research. It could be used to develop screening procedures to investigate the impact of adjuvants on cuticular waxes or the influence of wax constituents on the properties of cuticular waxes. This work concentrated on the development of an artificial wax mixture, which mimics the physical properties of a plant leaf wax sufficiently. As target wax, the leaf wax of Schefflera elegantissima was chosen. The wax of this plant species consisted almost exclusively of VLCAs, had a rather simple composition regarding compound classes and chain length distribution and CMs could be isolated. Artificial binary, ternary and quaternary waxes corresponding to the conditions within the plant wax were investigated using differential scanning calorimetry (DSC), X-ray diffraction (XRD) techniques and Fourier-transform infrared (FTIR) spectroscopy. Phase diagrams were mapped out for a series of binary, ternary and quaternary wax mixtures. FTIR experiments were conducted using, ternary and a quaternary artificial wax blends. The blends were chosen to represent the conditions within the wax of the adaxial CM plant wax. The FTIR experiments exhibited an increasing resemblance of the artificial wax to the plant wax (adaxial CM wax) with an increasing number of compounds in the artificial wax. The same trend was found for DSC thermograms. Thermograms of ternary and quaternary blends exhibited more overlapping peaks and occurred in a temperature range more similar to the range of the whole leaf plant wax. The XRD spectrum at room temperature showed good conformity with the quaternary blend. The current work illustrates a method for selective extraction of TRPs from isolated CMs. It gives direct experimental proof of the association of the water permeance barrier with the VLCA rather than to the TRPs. Furthermore, the possibility to mimic cuticular waxes using commercially available wax compounds is investigated. The results show promising feasibility for its viability, enabling it to perform as a standardized initial point for further research (e.g. to examine the influence of different constituents on waxes), revealing valuable knowledge about the structure and the chemistry-function relationship of cuticular waxes.},
  subject      = {Kutikula},
  language  = {en}
}