Christopher M. Dettmar scite author profile

Second harmonic generation (SHG) microscopy measurements indicate that inkjet-printed racemic solutions of amino acids can produce nanocrystals trapped in metastable polymorph forms upon rapid solvent evaporation. Polymorphism impacts the composition, distribution, and physico-kinetic properties of organic solids, with energetic arguments favoring the most stable polymorph. In this study, unfavored noncentrosymmetric crystal forms were observed by SHG microscopy. Polarization-dependent SHG measurement and synchrotron X-ray microdiffraction analysis of individual printed drops are consistent with formation of homochiral crystal production. Fundamentally, these results provide evidence supporting the ubiquity of Ostwald’s Rule of Stages, describing the hypothesized transitioning of crystals between metastable polymorphic forms in the early stages of crystal formation. Practically, the presence of homochiral metastable forms has implications on chiral resolution and on solid form preparations relying on rapid solvent evaporation.

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Towards protein-crystal centering using second-harmonic generation (SHG) microscopy

Kissick

Dettmar

Becker

et al. 2013

Acta Crystallogr D Biol Cryst

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The potential of second-harmonic generation (SHG) microscopy for automated crystal centering to guide synchrotron X-ray diffraction of protein crystals was explored. These studies included (i) comparison of microcrystal positions in cryoloops as determined by SHG imaging and by X-ray diffraction rastering and (ii) X-ray structure determinations of selected proteins to investigate the potential for laser-induced damage from SHG imaging. In studies using 2 adrenergic receptor membrane-protein crystals prepared in lipidic mesophase, the crystal locations identified by SHG images obtained in transmission mode were found to correlate well with the crystal locations identified by raster scanning using an X-ray minibeam. SHG imaging was found to provide about 2 mm spatial resolution and shorter image-acquisition times. The general insensitivity of SHG images to optical scatter enabled the reliable identification of microcrystals within opaque cryocooled lipidic mesophases that were not identified by conventional bright-field imaging. The potential impact of extended exposure of protein crystals to five times a typical imaging dose from an ultrafast laser source was also assessed. Measurements of myoglobin and thaumatin crystals resulted in no statistically significant differences between structures obtained from diffraction data acquired from exposed and unexposed regions of single crystals. Practical constraints for integrating SHG imaging into an active beamline for routine automated crystal centering are discussed.

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Integrated nonlinear optical imaging microscope for on-axis crystal detection and centering at a synchrotron beamline

Madden

Toth

Dettmar

et al. 2013

J Synchrotron Radiat

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Nonlinear optical (NLO) instrumentation has been integrated with synchrotron X-ray diffraction for combined single-platform analysis, examining the viability of NLO microscopy as an alternative to the conventional X-ray raster scan for the purposes of sample centering. Second-harmonic generation microscopy and two-photon excited ultraviolet fluorescence microscopy were evaluated for crystal detection, and assessed by X-ray raster scanning.

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Unified Theory for Polarization Analysis in Second Harmonic and Sum Frequency Microscopy

Dow

DeWalt

Newman

et al. 2016

Biophysical Journal

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A unified theoretical framework for the recovery of second-order nonlinear susceptibility tensors and sample orientations from polarization-dependent second harmonic generation and sum frequency generation microscopy was developed. Jones formalism was extended to nonlinear optics and was used to bridge the experimental observables and the local-frame tensor elements. Four commonly used experimental architectures were explicitly explored, including polarization rotation with no postsample optics, polarization-in polarization-out measurement, and polarization modulation with and without postsample optics. Polarization-dependent second harmonic generation measurement was performed on Z-cut quartz and the local-frame tensor elements were calculated. The recovered tensor elements agree with the expected values dictated by symmetry.

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Imaging local electric fields produced upon synchrotron X-ray exposure

Dettmar

Newman

Toth

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Electron-hole separation following hard X-ray absorption during diffraction analysis of soft materials under cryogenic conditions produces substantial local electric fields visualizable by second harmonic generation (SHG) microscopy. Monte Carlo simulations of X-ray photoelectron trajectories suggest the formation of substantial local electric fields in the regions adjacent to those exposed to X-rays, indicating a possible electric-field-induced SHG (EFISH) mechanism for generating the observed signal. In studies of amorphous vitreous solvents, analysis of the SHG spatial profiles following X-ray microbeam exposure was consistent with an EFISH mechanism. Within protein crystals, exposure to 12-keV (1.033-Å) X-rays resulted in increased SHG in the region extending ∼3 μm beyond the borders of the X-ray beam. Moderate X-ray exposures typical of those used for crystal centering by raster scanning through an X-ray beam were sufficient to produce static electric fields easily detectable by SHG. The X-ray-induced SHG activity was observed with no measurable loss for longer than 2 wk while maintained under cryogenic conditions, but disappeared if annealed to room temperature for a few seconds. These results provide direct experimental observables capable of validating simulations of X-ray-induced damage within soft materials. In addition, X-ray-induced local fields may potentially impact diffraction resolution through localized piezoelectric distortions of the lattice.synchrotron | EFISH | X-ray damage | piezoelectric | structural biology T he ability to determine atomic-resolution structures and the quality of resulting structures recovered by X-ray diffraction can be profoundly affected by X-ray induced damage during the diffraction data acquisition. At the energies typically used for protein structure determination, for every X-ray photon resulting in elastic scattering approximately 10-fold more photons result in inelastic scattering or absorption and deposition of energy into the crystal. The excess energy can perturb the molecules within a crystal through a variety of different mechanisms, typically resulting in the reduction of overall diffracted intensity (1). With biological macromolecules, such as proteins, this effect in combination with the initial inherent degree of ordering often limits the achievable resolution possible through signal averaging.X-ray induced radiation damage in protein crystals can manifest as two different types: global and specific (1). Specific damage occurs when irradiation causes specific chemical changes within the protein such as loss of side chains or disulfide bridge linkages (2, 3), damage to active sites (2), and damage to metal centers within the protein (1). Disulfide anion radicals, evidence of specific damage, have previously been observed by UV-vis microspectrophotometry after X-ray exposure for tens of milliseconds (4). Damage to nonspecific sites, known also as global damage, results in a decrease in the intensity of the high-angle spots with increasing X-ray dose, and t...

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