Robert Glaeser
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American biochemist
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Robert Glaeserbiology Degrees
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Biochemistry
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Biology
Robert Glaeser's Degrees
- PhD Biochemistry University of California, Berkeley
- Bachelors Chemistry University of California, Berkeley
Why Is Robert Glaeser Influential?
(Suggest an Edit or Addition)According to Wikipedia, Robert Martin Glaeser is an American biochemist. He is a professor emeritus of Biochemistry, Biophysics and Structural Biology at the University of California, Berkeley and a faculty scientist at Lawrence Berkeley National Laboratory, in Berkeley, California, US. His main research area is electron diffraction and membrane models.
Robert Glaeser's Published Works
Number of citations in a given year to any of this author's works
Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author
Published Works
- From words to literature in structural proteomics (2003) (456)
- SPARX, a new environment for Cryo-EM image processing. (2007) (398)
- Electron Diffraction of Frozen, Hydrated Protein Crystals (1974) (390)
- What can x-ray scattering tell us about the radial distribution functions of water? (2000) (346)
- Limitations to significant information in biological electron microscopy as a result of radiation damage. (1971) (330)
- A high-quality x-ray scattering experiment on liquid water at ambient conditions (2000) (249)
- Radiation damage relative to transmission electron microscopy of biological specimens at low temperature: a review (1978) (212)
- Electron microscopy of frozen hydrated biological specimens. (1976) (196)
- Quantitative analysis of image contrast in electron micrographs of beam-sensitive crystals (1985) (188)
- The relevance of dose-fractionation in tomography of radiation-sensitive specimens. (1995) (169)
- Water structure as a function of temperature from X-ray scattering experiments and ab initio molecular dynamics (2003) (169)
- How good can cryo-EM become? (2015) (161)
- Review: electron crystallography: present excitement, a nod to the past, anticipating the future. (1999) (151)
- Automatic particle selection: results of a comparative study. (2004) (149)
- Retrospective on the early development of cryoelectron microscopy of macromolecules and a prospective on opportunities for the future. (2008) (137)
- Radiation damage of purple membrane at low temperature. (1979) (135)
- Review: automatic particle detection in electron microscopy. (2001) (125)
- Practical factors affecting the performance of a thin-film phase plate for transmission electron microscopy. (2009) (116)
- Invited review article: Methods for imaging weak-phase objects in electron microscopy. (2013) (116)
- Electron Crystallography of Biological Macromolecules (2007) (115)
- Electron microscopy of human serum lipoproteins using negative staining (1968) (115)
- Mobilities of Electrons and Holes in Organic Molecular Solids. Comparison of Band and Hopping Models (1966) (111)
- Structure of an early intermediate in the M-state phase of the bacteriorhodopsin photocycle. (2001) (109)
- Peptide-chain secondary structure of bacteriorhodopsin. (1983) (105)
- Development of methodology for low exposure, high resolution electron microscopy of biological specimens. (1975) (99)
- Opinion: hazards faced by macromolecules when confined to thin aqueous films (2016) (94)
- Laser phase plate for transmission electron microscopy (2019) (93)
- Design of a microfabricated, two-electrode phase-contrast element suitable for electron microscopy. (2006) (92)
- Improvement in high resolution image quality of radiation-sensitive specimens achieved with reduced spot size of the electron beam. (1986) (87)
- Crystal structure of the D85S mutant of bacteriorhodopsin: model of an O-like photocycle intermediate. (2001) (87)
- Ultrafast Protein Dynamics of Bacteriorhodopsin Probed by Photon Echo and Transient Absorption Spectroscopy (2002) (80)
- PROTEINS, INTERFACES, AND CRYO-EM GRIDS. (2017) (80)
- Retrospective: radiation damage and its associated "information limitations". (2008) (78)
- Periodic surface array in Caulobacter crescentus: fine structure and chemical analysis (1981) (77)
- Images of paraffin monolayer crystals with perfect contrast: minimization of beam-induced specimen motion. (2011) (77)
- Precise beam-tilt alignment and collimation are required to minimize the phase error associated with coma in high-resolution cryo-EM. (2011) (76)
- Reaching the information limit in cryo-EM of biological macromolecules: experimental aspects. (2011) (74)
- Structural comparison of native and deoxycholate-treated purple membrane. (1985) (71)
- Direct evidence for modified solvent structure within the hydration shell of a hydrophobic amino acid. (1996) (68)
- Factors that Influence the Formation and Stability of Thin, Cryo-EM Specimens. (2016) (63)
- How Good Can Single-Particle Cryo-EM Become? What Remains Before It Approaches Its Physical Limits? (2019) (56)
- Specimen Charging on Thin Films with One Conducting Layer: Discussion of Physical Principles (2003) (55)
- Design of an electron microscope phase plate using a focused continuous-wave laser (2010) (54)
- Specimen Behavior in the Electron Beam. (2016) (54)
- How Cryo-EM Became so Hot (2017) (54)
- A method for the alignment of heterogeneous macromolecules from electron microscopy. (2009) (53)
- The bacteriorhodopsin photocycle: direct structural study of two substrates of the M-intermediate. (1994) (46)
- Multi-pass transmission electron microscopy (2016) (46)
- Electron diffraction analysis of the M412 intermediate of bacteriorhodopsin. (1986) (45)
- High-resolution electron crystallography of protein molecules. (1993) (45)
- Hydrophilic support films of controlled thickness and composition. (1973) (43)
- A giant protease with a twist: the TPP II complex from Drosophila studied by electron microscopy (2002) (43)
- Long shelf-life streptavidin support-films suitable for electron microscopy of biological macromolecules. (2016) (41)
- Molecular orientation of bacteriorhodopsin within the purple membrane of Halobacterium halobium. (1978) (40)
- Experimental Characterization and Mitigation of Specimen Charging on Thin Films with One Conducting Layer (2004) (39)
- Differences in hydration structure near hydrophobic and hydrophilic amino acids. (1997) (38)
- High resolution cold stage for the JEOL 100B and 100C electron microscopes. (1980) (38)
- Survey of large protein complexes in D. vulgaris reveals great structural diversity (2009) (38)
- Characterization of conditions required for X-Ray diffraction experiments with protein microcrystals. (2000) (37)
- Absorption flattening in the circular dichroism spectra of small membrane fragments. (1985) (37)
- Specimen flatness of thin crystalline arrays: influence of the substrate. (1992) (37)
- Molecular architecture and assembly mechanism of Drosophila tripeptidyl peptidase II. (2005) (37)
- Interfacial energies and surface‐tension forces involved in the preparation of thin, flat crystals of biological macromolecules for high‐resolution electron microscopy (1991) (36)
- Particle picking by segmentation: a comparative study with SPIDER-based manual particle picking. (2005) (36)
- Ultrathin Carbon Support Films for Electron Microscopy (1972) (35)
- Three-dimensional reconstructions from incomplete data: interpretability of density maps at "atomic" resolution. (1989) (33)
- Chemical and physical evidence for multiple functional steps comprising the M state of the bacteriorhodopsin photocycle. (2000) (33)
- Evaporated carbon stabilizes thin, frozen-hydrated specimens (1989) (33)
- Historical background: Why is it important to improve automated particle selection methods? (2004) (33)
- Structure of the surface layer protein of the outer membrane of Spirillum serpens. (1979) (33)
- Structural characterization of the L-to-M transition of the bacteriorhodopsin photocycle. (1998) (33)
- Deprotonation of D96 in bacteriorhodopsin opens the proton uptake pathway. (2013) (33)
- Cryo-electron microscopy of biological nanostructures (2008) (32)
- A binary segmentation approach for boxing ribosome particles in cryo EM micrographs. (2004) (31)
- Electron microscopy of biotinylated protein complexes bound to streptavidin monolayer crystals. (2012) (30)
- Restoration of weak phase-contrast images recorded with a high degree of defocus: the "twin image" problem associated with CTF correction. (2008) (30)
- Assessment of resolution in biological electron crystallography. (1992) (30)
- Crystal structure of the bromide-bound D85S mutant of bacteriorhodopsin: principles of ion pumping. (2003) (29)
- Measurement of focus and spherical aberration of an electron microscope objective lens. (1976) (29)
- Monolayer-Crystal Streptavidin Support Films Provide an Internal Standard of cryo-EM Image Quality (2016) (29)
- High-voltage electron diffraction from bacteriorhodopsin (purple membrane) is measurably dynamical. (1989) (28)
- The scattering of high‐energy electrons. I. Feynman path‐integral formulation (1978) (27)
- Current outcomes when optimizing ‘standard’ sample preparation for single‐particle cryo‐EM (2019) (27)
- Single-Particle Cryo-Electron Microscopy (Cryo-EM): Progress, Challenges, and Perspectives for Further Improvement (2014) (26)
- Radiation damage in stained catalase at low temperature (1975) (25)
- Experimental evaluation of support vector machine-based and correlation-based approaches to automatic particle selection. (2011) (25)
- Preparation of frozen-hydrated specimens for high resolution electron microscopy. (1984) (25)
- Micro-scale fluid behavior during cryo-EM sample blotting (2019) (25)
- Projected structure of the pore-forming OmpC protein from Escherichia coli outer membrane. (1985) (24)
- Three-dimensional diffractive imaging for crystalline monolayers with one-dimensional compact support. (2003) (24)
- Direct phasing of electron diffraction data from organic crystals: the effect of n‐beam dynamical scattering (1979) (24)
- Crystal structures of bR(D85S) favor a model of bacteriorhodopsin as a hydroxyl‐ion pump (2004) (24)
- Solution X-ray scattering as a probe of hydration-dependent structuring of aqueous solutions (1999) (23)
- The surface of evaporated carbon films is an insulating, high-bandgap material. (2011) (23)
- Electron Microscopy of Biological Macromolecules: Bridging the Gap between What Physics Allows and What We Currently Can Get (2003) (23)
- Accurate modeling of single-particle cryo-EM images quantitates the benefits expected from using Zernike phase contrast. (2011) (23)
- Design of a hybrid double-sideband/single-sideband (schlieren) objective aperture suitable for electron microscopy. (2011) (23)
- Difference Fourier analysis of "surface features" of bacteriorhodopsin using glucose-embedded and frozen-hydrated purple membrane. (1987) (22)
- Factors affecting high resolution fixed-beam transmission electron microscopy. (1977) (22)
- Two progressive substrates of the M-intermediate can be identified in glucose-embedded, wild-type bacteriorhodopsin. (1994) (22)
- Characterization of the conformational change in the M1 and M2 substates of bacteriorhodopsin by the combined use of visible and infrared spectroscopy. (1992) (21)
- Some statistical aspects of low-dose electron imaging of crystals (1990) (21)
- High-throughput film-densitometry: an efficient approach to generate large data sets. (2005) (20)
- The scattering of high-energy electrons. II. Quantitative validity domains of the single-scattering approximations for organic crystals (1980) (20)
- Application of electron diffraction to biological electron microscopy. (1969) (20)
- Preparing Better Samples for Cryo-Electron Microscopy: Biochemical Challenges Do not End with Isolation and Purification. (2021) (20)
- Three-dimensional structure of an invertebrate intercellular communicating junction. (1991) (20)
- Ranking TEM cameras by their response to electron shot noise. (2013) (20)
- Modified airlock door for the introduction of frozen specimens into the JEM 100B electron microscope (1975) (20)
- Modeling chemical bonding effects for protein electron crystallography: the transferable fragmental electrostatic potential (TFESP) method. (2002) (19)
- Octomeric pyruvate-ferredoxin oxidoreductase from Desulfovibrio vulgaris. (2007) (19)
- Focused issue on X-ray microscopy of biological materials. (2012) (19)
- The energy dependence of electron radiation damage in 1-valine. (1976) (18)
- Stroboscopic image capture: reducing the dose per frame by a factor of 30 does not prevent beam-induced specimen movement in paraffin. (2006) (18)
- Near-concentric Fabry-Pérot cavity for continuous-wave laser control of electron waves. (2017) (18)
- Three-dimensional structure of the surface layer protein of Aquaspirillum serpens VHA determined by electron crystallography (1986) (18)
- Minimizing electrostatic charging of an aperture used to produce in-focus phase contrast in the TEM. (2013) (17)
- Chemical bonding effects in the determination of protein structures by electron crystallography. (1999) (17)
- Estimating the effect of finite depth of field in single-particle cryo-EM. (2018) (17)
- UV microscopy at 280 nm is effective in screening for the growth of protein microcrystals (2005) (17)
- High-power near-concentric Fabry–Perot cavity for phase contrast electron microscopy (2020) (16)
- RADIATION DAMAGE WITH BIOLOGICAL SPECIMENS AND ORGANIC MATERIALS (1979) (15)
- Membrane-protein stability in a phospholipid-based crystallization medium. (2006) (15)
- Specimen flatness of glucose-embedded biological materials for electron crystallography is affected significantly by the choice of carbon evaporation stock. (1994) (15)
- Spectral DQE of the Volta phase plate. (2020) (14)
- Disulfide Linkage and Structure of Highly Stable Yeast-derived Virus-like Particles of Murine Polyomavirus* (2014) (14)
- Energy transduction in transmembrane ion pumps. (2004) (14)
- Specificity of anion binding in the substrate pocket of bacteriorhodopsin. (2003) (13)
- New kinds of phase transitions: transformations in disordered substances (2001) (13)
- Stroboscopic imaging of macromolecular complexes (2013) (12)
- Single atom image contrast: conventional dark‐field and bright‐field electron microscopy (1975) (12)
- The parallelization of SPIDER on distributed-memory computers using MPI. (2007) (12)
- Continuous 40 GW/cm$^2$ laser intensity in a near-concentric optical cavity (2016) (12)
- Crystallization of membrane proteins from media composed of connected-bilayer gels. (2002) (11)
- Interfacial Concentration Profiles of Rubbery Polyolefin Lamellae Determined by Quantitative Electron Microscopy (2008) (10)
- What spectroscopy can still tell us about the secondary structure of bacteriorhodopsin. (1991) (10)
- Validity domain of the weak-phase-object approximation for electron diffraction of thin protein crystals. (1988) (10)
- The "born energy" problem in bacteriorhodopsin. (1984) (9)
- Prospects For Extending The Resolution Limit Of The Electron Microscope (1979) (9)
- Combining noisy images of small crystalline domains in high resolution electron microscopy (1989) (9)
- Electron crystallography of membrane proteins. (2007) (8)
- Electron diffraction from single crystals of DNA. (1980) (8)
- Spectral DQE of the Volta Phase Plate (2020) (8)
- Evaluation of Photographic Emulsions for Low-Exposure-Imaging (1980) (8)
- Use of Low Temperatures for Electron Diffraction and Imaging of Biological Macromolecular Arrays (1980) (8)
- Observation of the Relativistic Reversal of the Ponderomotive Potential. (2019) (8)
- Crystallographic extraction and averaging of data from small image areas. (1995) (8)
- The fatty acid monolayer technique for preparing frozen-hydrated specimens (1985) (7)
- THE ELECTRIC CHARGE AND SURFACE PROPERTIES OF INTACT CELLS. UCRL-10898. (1963) (7)
- Macromolecular structures without crystals (2008) (7)
- Glucose alone does not completely hydrate bacteriorhodopsin in glucose‐embedded purple membrane (1993) (6)
- Electron microscopy of biological specimens in liquid water. (2012) (6)
- Probing the structure of zeolites by Fourier transform electron microscopy: zeolite-L as a test case (1985) (6)
- Defocus-dependent Thon-ring fading (2020) (6)
- Replication and validation of cryo-EM structures. (2013) (6)
- A Critique of the Theoretical Basis for the Use of Hvem in Biology (1982) (6)
- Advantages and Objectives of High-throughput Data Collection in Single-particle Cryo-EM (2006) (5)
- Laser control of the electron wave function in transmission electron microscopy (2018) (5)
- Structure Analysis of Bacteriorhodopsin by Electron Crystallography (1987) (5)
- Protein complexes in focus (2016) (4)
- Probing toward atomic resolution in molecular topography. (1994) (4)
- Automated particle correspondence and accurate tilt-axis detection in tilted-image pairs. (2014) (4)
- Perspective: Biochemical and Physical Constraints Associated With Preparing Thin Specimens for Single-Particle Cryo-EM (2022) (3)
- Quantitative evaluation of high-resolution features in images of negatively stained Tobacco Mosaic Virus. (1983) (3)
- Development of a Laser Phase Plate for Zernike Phase Contrast in Electron Microscopy (2013) (3)
- Minimizing Crinkling of Soft Specimens Using Holey Gold Films on Molybdenum Grids for Cryogenic Electron Microscopy (2021) (3)
- Laser-Based Zernike Plate for Phase Contrast Transmission Electron Microscopy (2018) (3)
- Reducing Electron Beam Damage with Multipass Transmission Electron Microscopy (2017) (3)
- 9. Electron Microscopy (1982) (2)
- Structural biology: Signalling under the microscope (2017) (2)
- Simple assay for adsorption of proteins to the air-water interface. (2021) (2)
- Microcrystal screening with a novel design for beamline-mountable crystallization wells (2008) (2)
- Workshop on high resolution electron microscopy (1977) (2)
- Properties and Behavior of Amorphous Carbon Films Related to Phase Plate Applications (2012) (2)
- A ‘tulip aperture’ providing in-focus phase-contrast (2012) (1)
- Aspects of Using a Boersch Type Phase Shifting Device for Contrast Enhancement in Macromolecular Electron Microscopy (2008) (1)
- Structure of the D85S mutant of bacteriorhodopsin with bromide bound (2003) (1)
- The Growing Role of Electron Crystallography in Structural Biology (1999) (1)
- Optimal and fast rotational alignment of volumes with missing data in Fourier space. (2013) (1)
- Molecular Architecture and Assembly Mechanism of TPP II (2005) (1)
- Long shelf-life streptavidin support-films suitable for electron microscopy of biological macromolecules (2016) (1)
- A laser-based phase plate for phase contrast transmission electron microscopy (2018) (1)
- Conquer by cryo-EM without physically dividing. (2021) (1)
- Perspective: Emerging strategies for determining atomic-resolution structures of macromolecular complexes within cells (2021) (1)
- Generalization of the Matsumoto-Tonomura approximation for the phase shift within an open aperture. (2014) (1)
- The Electron Utilization Efficiency in STEM (1980) (1)
- Streptavidin Affinity Grids for cryo-EM (2018) (1)
- Energy dependence of radiation damage in 1-valine (1975) (1)
- Laser-Based Phase Contrast for Transmission Electron Microscopy (2019) (1)
- Holey-Gold Films on Molybdenum Grids for Cryogenic Electron Microscopy Imaging of 2D Polymer Crystals (2021) (1)
- Human tripeptidyl peptidase II: a gentle giant. (2012) (1)
- Microscale Fluid Mechanics of Making Thin Specimens for Cryo-EM (2019) (0)
- BACTERIORHODOPSIN D85S/F219L DOUBLE MUTANT AT 2.00 ANGSTROM RESOLUTION (2001) (0)
- Lawrence Berkeley National Laboratory Recent Work Title Crystal Structure of the Bromide-Bound D 85 S Mutant of Bacteriorhodopsin : Principles of Ion Pumping Permalink (2004) (0)
- Cryo EM Study of Protein Complexes Bound to Streptavidin Crystal Layers (2012) (0)
- X-ray structure of an early-M intermediate of bacteriorhodopsin (2001) (0)
- Streptavidin Monolayer-Crystal Affinity Grids: A Step Toward Controlling What Happens During Cryo-EM Sample Preparation (2017) (0)
- Laser Phase Plate: Advancing Beyond Proof-of-Concept (2022) (0)
- Protein complexes in focus A new advance in electron microscopy can reveal highly-detailed structures of protein complexes. (2016) (0)
- Overcoming resolution-loss mechanisms in laser phase plate cryo-electron microscopy. (2023) (0)
- Overcoming resolution loss due to thermal magnetic field fluctuations from phase plates in transmission electron microscopy. (2023) (0)
- Apparent Temperature Factor Due to Dynamical Scattering in Electron Diffraction of Protein Crystals (1981) (0)
- High Resolution Electron Cystallography of Protein Molecules (1993) (0)
- Protein complex analysis project (PCAP): Project overview (2007) (0)
- BACTERIORHODOPSIN O-LIKE INTERMEDIATE STATE OF THE D85S MUTANT AT 2.25 ANGSTROM RESOLUTION (2001) (0)
- Proteomic Survey of Large Macromolecular Complexes in D. vulgaris (2008) (0)
- Progress towards a Zernike Phase Plate for Electron Microscopy using a Focused Laser Beam (2012) (0)
- Assessment of resolution in biological electron crystallography (1991) (0)
- Structural Survey of Large Protein Complexes in Desulfovibrio Vulgaris (2010) (0)
- Overcoming Patch-Potential Effects on the Surfaces of Tem Phase-Contrast Devices (2014) (0)
- APPLICATION OF ELECTRON DIFFRACTION TO PROBLEMS IN BIOLOGICAL ELECTRON MICROSCOPY. (1968) (0)
- Development of High-Resolution TEM for Imaging Native, Radiation-Sensitive Biological Macromolecules (2017) (0)
- Characterization of a Fixed Beam Electron Microscope with a Field Emission Gun (1976) (0)
- Cryo-electron of biological (2008) (0)
- Lawrence Berkeley National Laboratory Recent Work Title Protein complexes in focus Permalink (2016) (0)
- THE STRUCTURAL ANALYSIS OF THE SURFACE LAYER PROTEIN OF Aquaspirillum serpens BY HIGH RESOLUTION ELECTRON MICROSCOPY (1983) (0)
- Measurement and reduction of damage in frozen hydrated crystalline specimens (1978) (0)
- Lawrence Berkeley National Laboratory Recent Work Title Estimating the effect of finite depth of field in single-particle cryo-EM Permalink (2017) (0)
- Conquer by Cryo-EM Without Physically Dividing Current limits and future potential for determining high-resolution structures of smaller macromolecules (2021) (0)
- Use of Ultrananocrystalline Diamond as a Phase-contrast Aperture Material (2015) (0)
- Overview of significant challenges in molecular biology amenable to computational methods. (1994) (0)
- In-focus Cryo-EM Images Using a Hybrid Single-Sideband/Double-Sideband Aperture (2013) (0)
- A New Method for Single Atom Specimen Preparation (1975) (0)
- Dynamical Scattering in Crystalline Biological Specimens. II. The Domain of Validity for Different Approximations (1975) (0)
- FTIR spectroscopy of bacteriorhodopsin microcrystals at Beamline 1 (2001) (0)
- Investigating the Causes of Electrostatic Charging of Phase-contrast Apertures (2014) (0)
- Design for a Continuous-Wave Focused-Light Phase Plate for TEM (2010) (0)
- SIMPLE ASSAY FOR ADSORPTION OF PROTEINS TO THE AIR-WATER INTERFACE (2021) (0)
- High Throughput Identification, Purification and Structural Characterization of Water Soluble Protein Complexes in Desulfovibrio vulgaris (2010) (0)
- OVERCOMING RESOLUTION LOSS DUE TO THERMAL MAGNETIC FIELD FLUCTUATIONS FROM PHASE PLATES IN TRANSMISSION ELECTRON MICROSCOPY (2023) (0)
- structure of ground-state bacteriorhodopsin (2001) (0)
- Biological Properties of the Mammalian Surface Membrane. A Symposium Held at The Wistar Institute of Anatomy and Biology, April 28, 1967.Lionel A. Manson (1970) (0)
- Streptavidin Affinity Grids for Single-particle Cryo-EM (2019) (0)
- Development of Methodology for Low Exposure, High Resolution Electron Microscopy of Biological Specimens (1975) (0)
- Nitrate-bound D85S mutant of bacteriorhodopsin (2004) (0)
- Structural investigation of frozen-hydrated Omp C specimens prepared by the fatty acid monolayer technique (1983) (0)
- Phase Contrast Electron Microscopy Using Lasers (2019) (0)
- The 'missing cone' problem in electron crystallography: interpretability of high-resolution density maps (1987) (0)
- Addressing The Patch-Potential Effect For In-Focus Phase-Contrast Apertures (2012) (0)
- Electron Crystallography of Soluble and Membrane Proteins: Methods and Protocols . Ingeborg Schmidt-Krey and Yifan Cheng (Eds). Humana Press, New York, 2013, 586 pages. ISBN 978-1-62703-175-2 (2013) (0)
- Structure of a ""mock-trapped"" early-M intermediate of bacteriorhosopsin (2001) (0)
- Adapting the Spatial-frequency Bandpass of In-focus Phase-contrast Apertures for Biologcal Applications (2007) (0)
- Anion-free form of the D85S mutant of bacteriorhodopsin from crystals grown in the presence of halide (2004) (0)
- Extraction of macro-molecule images in cryo-EM micrographs (2003) (0)
- Device which tests and records radial symmetry in electron micrographic images. (1969) (0)
- Molecular orientation ofbacteriorhodopsi (1978) (0)
- Computational Modeling of the Benefits Expected For Zernike Phase Contrast in Cryo-EM (2009) (0)
- Surface Structure of Nucleated Animal Cells: Carbon Replicas (1967) (0)
- A laser-based phase plate for cryo-electron microscopy (2022) (0)
- Decision letter: Protein denaturation at the air-water interface and how to prevent it (2018) (0)
- Multi-pass transmission electron microscopy (2017) (0)
- Summary of Alternative Methods Intended for Imaging of Weak-Phase Objects in Transmission Electron Microscopy (2010) (0)
- Pure Water Structure and Hydration Forces for Protein Folding (2002) (0)
- Information Delocalization in Highly-defocused Phase-contrast images of ??Single-particle?? Specimens (2007) (0)
- Temperature Dependence of the Critical Electron Dose for Fatty Acid Monolayers (1982) (0)
- HIGH-THROUHGPUT FILM-DENSITOMETRY: AN EFFICIENT APPROACH TO GENERATE LARGE DATA SETS (2004) (0)
- 1 Electron-Scattering Events Can Be Either Elastic or Inelastic (2016) (0)
- High-Contrast In-Focus Imaging in Biological Cryo-EM (2012) (0)
- Dose fractionation theorem in 3-D reconstruction (tomography) (1997) (0)
- Dynamical Scattering in Crystalline Biological Specimens. I. Criteria of Validity for Scattering Approximations (1975) (0)
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