The growing world population puts ever-increasing demands on the agricultural and agrochemical industries to increase agricultural yields. This can only be achieved by investing in fundamental plant and agrochemical research and in the development of improved analytical tools to support research in these areas.There is currently a lack of analytical tools that provide non-invasive structural and chemical analysis of plant tissues at the cellular scale. Imaging techniques such as coherent anti-Stokes Raman scattering (CARS) and stimulated Raman scattering (SRS) microscopy provide labelfree chemically specific image contrast based on vibrational spectroscopy. Over the past decade these techniques have been shown to offer clear advantages for a vast range of biomedical research applications. The intrinsic vibrational contrast provides label-free quantitative functional analysis; it does not suffer from photobleaching; and allows near realtime imaging in 3D with submicron spatial resolution. However, due to the susceptibility of current detection schemes to optical absorption and fluorescence from pigments (such as chlorophyll) the plant science and agrochemical research communities have not been able to benefit from these techniques and their application in plant research has remained virtually unexplored.In this paper we explore the effect of chlorophyll fluorescence and absorption in CARS and SRS microscopy. We show that with the latter it is possible to use phase-sensitive detection to separate the vibrational signal from the (electronic) absorption processes. Finally we demonstrate the potential of SRS for a range of in planta applications by presenting in-situ chemical analysis of plant cell wall components, epicuticular waxes, and the deposition of agrochemical formulations onto the leaf surface.
A thermostatted micro volume Couette cell has been designed to enable linear dichroism (LD) data to be collected at a range of temperatures. The cell is a development of the traditional Couette flow LD cell and includes the recent development of micro-volume LD (20-40 microL) coupled with the addition of a heating element, temperature probe and controller. This new micro volume Couette LD cell opens the way not only to the LD analysis of systems where sample volume is critical, but also for the LD analysis of temperature sensitive samples. The polymerization of the microtubule protein tubulin has been followed in a range of different conditions using the thermostatted micro volume Couette LD cell. The focusing lenses on the cell, which are required for the microvolume cell, have the side benefit of significantly reducing the light-scattering artifacts caused by the large size of tubulin microtubules. It is now possible to monitor real-time polymerization and depolymerization kinetics, and any structural rearrangements of chromophores within the polymer. In the case of tubulin, the LD spectra revealed a greater change in the orientation of tryptophan residues at approximately 290 nm during polymerization compared to other contributing chromophores-guanine, phenylalanine, and tyrosine. The improvements in instrumental design have also allowed LD spectra of tubulin to be collected down to approximately 230 nm (previous data have only been available from the near UV region), which means that some indication of protein backbone-orientation changes are now available. It was observed during this work that apparent LD intensity maxima are in fact artifacts when the high-tension voltage is high. The onset of such artifacts has been observed at much lower voltages with light-scattering fibrous proteins (including tubulin) than with nonscattering samples. Therefore, caution must be used when interpreting LD data collected with medium to high photomultiplier tube voltages.
A combined single-crystal X-ray diffraction and NMR crystallography study of a 1:1 cocrystal of two fungicides, namely dithianon and pyrimethanil, is presented. Specifically, the role of hydrogen bonding and C—H⋯π and S⋯O intermolecular interactions is quantitatively investigated.
The cuticle is a ubiquitous, predominantly waxy layer on the aerial parts of higher plants that fulfils a number of essential physiological roles, including regulating evapotranspiration, light reflection, and heat tolerance, control of development, and providing an essential barrier between the organism and environmental agents such as chemicals or some pathogens. The structure and composition of the cuticle are closely associated but are typically investigated separately using a combination of structural imaging and biochemical analysis of extracted waxes. Recently, techniques that combine stain-free imaging and biochemical analysis, including Fourier transform infrared spectroscopy microscopy and coherent anti-Stokes Raman spectroscopy microscopy, have been used to investigate the cuticle, but the detection sensitivity is severely limited by the background signals from plant pigments. We present a new method for label-free, in vivo structural and biochemical analysis of plant cuticles based on stimulated Raman scattering (SRS) microscopy. As a proof of principle, we used SRS microscopy to analyze the cuticles from a variety of plants at different times in development. We demonstrate that the SRS virtually eliminates the background interference compared with coherent anti-Stokes Raman spectroscopy imaging and results in label-free, chemically specific confocal images of cuticle architecture with simultaneous characterization of cuticle composition. This innovative use of the SRS spectroscopy may find applications in agrochemical research and development or in studies of wax deposition during leaf development and, as such, represents an important step in the study of higher plant cuticles.
Providing sufficient, healthy food for the increasing global population is putting a great deal of pressure on the agrochemical industry to maximize crop yields without sustaining environmental damage. The growth and yield of every plant with sexual reproduction, depends on germination and emergence of sown seeds, which is affected greatly by seed disease. This can be most effectively controlled by treating seeds with pesticides before they are sown. An effective seed coating treatment requires a high surface coverage and adhesion of active ingredients onto the seed surface and the addition of adhesive agents in coating formulations plays a key role in achieving this. Although adhesive agents are known to enhance seed germination, little is understood about how they affect surface distribution of actives and how formulations can be manipulated to rationally engineer seed coating preparations with optimized coverage and efficacy. We show, for the first time, that stimulated Raman scattering microscopy can be used to map the seed surface with microscopic spatial resolution and with chemical specificity to identify formulation components distributed on the seed surface. This represents a major advance in our capability to rationally engineer seed coating formulations with enhanced efficacy.
The analysis of human milk for residues of polychlorinated biphenyls and organochlorine pesticides is a laborious and expensive procedure. This paper describes an approach to this analysis which is significantly less labour-intensive and more cost effective than traditional methods. These advantages were achieved by the adsorption of the milk on to a polar substrate prior to Soxhlet extraction, using a polymeric HPLC column for the clean-up of the extract followed by a highly selective capillary GC -MS analysis for the determination of the residues.
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