Transmission electron microscopy characterization of composite nanostructures

García Gutiérrez, Domingo Ixcóatl

28 August 2008

Not available / text

Transmission electron microscopy

Electron energy loss spectroscopy

Nanostructures--Analysis

Transmission Electron Tomography: Imaging Nanostructures in 3D

Wang, Xiongyao

Unknown Date

No description available.

3D Reconstruction

Electron tomography

Transmission electron microscopy

Nanostructure

Characterization of Starch Nanoparticles by Fluorescence Techniques

Yi, Wei

21 May 2015

Abstract The properties of starch nanoparticles (SNPs) labeled with the fluorescent dye pyrene (Py-SNPs) were probed by using fluorescence quenching, pyrene excimer formation, and transmission electron microscopy (TEM). Pyrene labeling of the SNPs was achieved by reacting 1-pyrenebutyric acid with the hydroxyl groups of the SNPs under basic conditions and in the presence of diisopropylcarbodiimide. This procedure did not degrade the SNPs as confirmed by dynamic light scattering (DLS) and afforded a means to generate a pyrene labeling level ranging from 0.5 to 5.0 mol% of the glucose units making up the SNPs. A polymeric quencher was also synthesized to probe the accessibility of the interior of the Py-SNPs by using fluorescence quenching measurements. The polymeric quencher was a 2K poly(ethylene glycol) terminated at one end with a methyl group and a nitropropane group at the other. Unfortunately these quenching experiments were abandoned when it was found that the polymeric quencher synthesized for these experiments absorbed too strongly where pyrene absorbs. Intramolecular pyrene excimer formation in the Py-SNPs was investigated by steady-state and time-resolved fluorescence. These experiments demonstrated that the Py-SNPs contract but do not overlap like linear polymers do in the semi-dilute regime. They also showed that despite the inherent rigidity of starch, the Py-SNPs deformed in water to allow their hydrophobic pyrene labels to cluster toward the center of the SNPs to minimize pyrene-solvent contacts. This segregation of the hydrophobic pyrene labels led to a distinct core-shell structure for the Py-SNPs which was illustrated in TEM images acquired on films prepared with the Py-SNPs. In summary, this thesis has uncovered some unexpected properties of the SNPs. Their branched structure makes their interpenetration difficult in the semi-dilute regime which forces them to contract. SNPs are thus deformable and their deformation can be probed quantitatively by using fluorescence and TEM.

Starch Nanoparticle

Fluorescence

Polymeric Quencher

Transmission Electron Microscopy

TEM crack tip investigations of SCC

Lozano-Perez, Sergio

January 2002

Over the last few years, TEM has become a powerful technique to study cracks and specially crack tips. However, the number of publications including TEM results has not grown as it was expected. The main reason for this might be difficulties in the sample preparation. In this work we present a novel FIB sample preparation technique which has proved to be an ideal tool for preparing cross sectional samples containing crack tips. The morphology of intergranular stress corrosion cracking (IGSCC) has been investigated in Alloy 600 subjected to constant load and slow strain rate tests in simulated primary circuit pressurized water reactor conditions. Cracks were observed to nucleate at high-angle grain boundaries and propagate to depths of a few tens of micrometer along such boundaries, still in the initiation stage. Electron diffraction, energy dispersive x-ray (EDX) and electron energy loss spectroscopy (EELS) have been used to identify the different corrosion products and precipitates. Elemental mapping was employed to reveal changes in composition in the crack tip area. Major observations at cracks and grain boundaries include: the presence of different oxides in different locations, differences in grain boundary oxides and open crack/free surface oxides. These observations suggest that IGSCC involves oxygen diffusion through a porous oxide region along grain boundaries to the bare metal. This is a novel concept that offers an alternative to previous mechanisms proposed in the literature e.g. H embrittlement, slip-dissolution, etc., for which no supporting evidence has been found.

620

Studies on the Morphology and Evolution of 'Orphan' Eukaryotes

Heiss, Aaron A.

20 August 2012

Most living eukaryotes are currently classified into one of five or six ‘supergroups’, which are in turn often divided between two assemblages: ‘unikonts’ and ‘bikonts’. This thesis explores the cytoskeletal morphology and phylogeny of three lineages that do not belong to any supergroup: ancyromonads, apusomonads, and breviates, likely relatives of supergroups Opisthokonta and Amoebozoa. It also investigates the phylogeny of malawimonads (basal members of supergroup Excavata) and collodictyonids (another unaffiliated lineage). Serial-section transmission electron microscopy was used to model the flagellar apparatus cytoskeletons of the ancyromonad Ancyromonas sigmoides, the breviate Breviata anathema, and the apusomonad Thecamonas trahens. Each has two main posterior microtubular roots and at least one anterior root (two in Ancyromonas). All three possess splitting posterior right microtubular roots and supernumerary singlets, features also characteristic of basal members of the supergroup Excavata (‘typical excavates’). One peripheral microtubule system in Ancyromonas, and the ‘right ribbon’ in Thecamonas, are likely homologous to dorsal fans in Breviata and ‘typical excavates’, and to the ‘r2’ root of myxogastrid Amoebozoa. One of the branches of the splitting root in Breviata and Thecamonas joins the right and intermediate roots, similarly to some myxogastrids. This implies that myxogastrids, and not the simpler pelobionts, represent the ancestral state for Amoebozoa. A phylogenomic analysis was performed focussing on apusomonads breviates, ancyromonads, and the problematic ‘typical excavate’ malawimonads, based on new transcriptomic data from Ancyromonas and an undescribed malawimonad. Rapid-site- removal analyses recover the ‘unikont’/‘bikont’ partition, and do not support the previously demonstrated affiliation between breviates and the ‘unikont’ supergroup Amoebozoa. Specifically, they group apusomonads with the ‘unikont’ supergroup Opisthokonta, and ancyromonads with breviates. Taxon-removal analyses group ancyromonads, breviates, and apusomonads together. Most analyses group malawimonads (perhaps with collodictyonids, another problematic group) between ‘unikonts’ and (other) ‘bikonts’, while other excavates are in a basal position amongst other ‘bikonts’. Combining these morphological and phylogenetic results suggests that splitting right roots, supernumerary intermediate singlets, and dorsal fans are found in multiple ‘basal’ lineages in both ‘unikont’ and ‘bikont’ portions of the eukaryotic tree, are likely characters of the last common ancestor of most or all living eukaryotes.

protist

transmission electron microscopy

cytoskeleton

molecular phylogeny

phylogenomics

Structure and Function of Leukocytes in the Family Macropodidae

k.hulme-moir@vet.gla.ac.uk, Karen Lisa Hulme-Moir

January 2007

Leukocytes play a central role in protecting the body against infectious organisms and their research is essential for understanding the mechanisms of immunity. By studying leukocytes across a range of species, insights are provided into differing strategies employed to ensure resistance to disease. Surprisingly, the structure and function of marsupial leukocytes has received very limited study. Marsupials represent a major evolutionary pathway with distinct differences in reproduction and development from placental mammals. These differences in the life history of marsupials place unique challenges on the immune system, and differences in leukocyte structure and function could be reasonably expected. In this thesis, studies were undertaken to examine the cytochemical, ultrastructural and functional features of leukocytes from species of marsupials, belonging to the family Macropodidae (kangaroos and wallabies). The aim of these studies was to elucidate the characteristics of macropodid leukocytes and to compare and contrast these features with the known characteristics of other mammalian leukocytes. Leukocytes from two species of macropodid, the tammar wallaby (Macropus eugenii) and the western grey kangaroo (Macropus fuliginosis), formed the basis of this study with additional material provided from quokka (Setonix brachyurus), woylie (Bettongia pencillata) and red kangaroo (Macropus rufus). Staining characteristics of cells were examined following reaction with Sudan black B, peroxidase, chloroacetate esterase, naphthyl butyrate esterase, alkaline phosphatase and periodic acid-Schiff. Peroxidase and Sudan Black B reactions were similar to domestic animal species but chloroacetate esterase and naphthyl butyrate esterase were unreliable as markers for macropodid neutrophils and monocytes, respectively. Significant variation in staining for alkaline phosphatase was seen between species of macropodid. Tammar wallabies and quokka demonstrated strong neutrophil alkaline phosphatase activity whereas western grey kangaroos, red kangaroos and woylies contained no activity within their leukocytes. Peroxidase and alkaline phosphatase cytochemistry were also assessed at the ultrastructural level with transmission electron microscopy. This allowed the identification of distinct granule populations within macropodid neutrophils. Two subcellular compartments containing alkaline phosphatase activity were identified within tammar wallaby neutrophils. These were considered equivalent to secretory vesicles and a subpopulation of specific granules. Tubular vesicles containing alkaline phosphatase were also identified within the eosinophils of tammar wallabies. These structures were a novel finding having not been reported previously in the eosinophils of other animal species. In addition to cytochemistry, the general ultrastructure of leukocytes from tammar wallabies and western grey kangaroos were reported. Results were similar to previous reports for other marsupial species. The current body of knowledge was extended by the first detailed description of the ultrastructure of basophils in a marsupial. To assess functional aspects of macropdid neutrophils, flow cytometric assays were performed examining oxidative burst responses and phagocytosis. Reactive oxygen species were generated by neutrophils from tammar wallabies and western grey kangaroos in response to phorbol 12-myristate 13-acetate but not N-formyl-Met-Leu-Phe or opsonised bacteria. Phagocytosis of opsonised bacteria was also measured in neutrophils from tammar wallabies, which was poor in contrast to ovine neutrophils. However, flow cytometric studies were limited by sample preparation. Further optimisation of isolation methods for tammar wallaby leukocytes should be undertaken before dogmatic conclusions are drawn. Overall, the results of this thesis demonstrate that, in the areas examined, the general characteristics of leukocyte structure and function of mammals are present in macropodids. However differences were identified both within and outside of the macropodid group. These differences have important ramifications for the use of ‘model’ species in the study of leukocyte biology in marsupials. The results also provide potentially useful tools for the clinical diagnosis of haematological disease in macropodids and may be of interest to those studying comparative and evolutionary aspects of leukocyte structure and function.

Leukocytes

marsupial

Macropodidae

cytochemistry

transmission electron microscopy

flow

Antecedent events underlying axon damage in an animal model of multiple sclerosis

Brinkoetter, Mary T.

January 2009

Thesis (M.S.)--Ball State University, 2009. / Title from PDF t.p. (viewed on Apr. 16, 2010). Includes bibliographical references (p. 36-37).

Transmission electron microscopy characterization of composite nanostructures

García Gutiérrez, Domingo Ixcóatl,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2006. / Vita. Includes bibliographical references.

A morphometric analysis of ultrastructural dynamics in the murine glomerulus following surgically-induced renal hypertension

Stevenson, James Ware

20 June 2016

Chronic kidney disease (CKD) and end stage renal disease (ESRD) are significant causes of adult morbidity and mortality worldwide. Though these conditions are common, the mechanisms of pathogenesis in kidney disease are poorly understood. Genetic predisposition has been established in the African American population; however this does not explain the ubiquity of CKD in the United States and abroad. Diabetes and hypertension are the two most frequently occurring co-morbidities in kidney disease and both have been identified as putative sources of injury to the delicate filtering structures of the kidney. Furthermore, the intrinsic functional relationship between the cardiovascular and renal organ systems adds to the plausibility of a hemodynamic cause. In light of this knowledge, we aim to explore the roles of genetic predisposition and hypertension in the pathogenesis and progression of CKD. The filtering apparatus of the kidney, the glomerulus, is a looping tuft of capillaries specialized to allow the passage of water and certain substances from the blood while restricting others. Glomeruli at the corticomedullary boundary of the kidney experience blood pressures closer to those in systemic arterioles and are subject to similar hemodynamic stresses. To evaluate the role of hypertension in CKD, we employed a well-known model of hypertensive kidney disease in mice involving uninephrectomy (UNX), subcutaneous implantation of a timed-release pellet containing the active aldosterone precursor deoxycorticosterone acetate (DOCA), and a high-salt diet. Given the role of heritability in human CKD pathogenesis, we applied the DOCA-UNX model in two strains of mice with differing susceptibility to kidney damage, the 129S6 and C57BL/6 strains, to evaluate the effects of genetic predisposition. Mice were subjected to varying lengths of hypertension exposure and their kidneys were subsequently examined by transmission electron microscopy (TEM). Ultrastructural lesions of glomeruli were evaluated by a renal pathologist and assigned subjective pathology scores based on the extent and severity of involvement. We hypothesized that certain glomerular lesions, particularly those involving the podocytes of the visceral epithelium, would increase in severity in mice with heritable susceptibility (129S6) as well as those with longer exposure to glomerular hypertension. Our observations demonstrate these hypotheses are partially correct. By TEM histopathology, mouse strain was found to have a significant effect on the severity of certain epithelial lesions while duration of hypertension had a significant effect on the overall morphological pathology of the podocytes, glomerular basement membrane, and glomerulus as a whole. These results provide a promising foundation for further investigation of the pathogenesis of CKD in mice.

Pathology

Histopathology

Hypertension

Kidney

Ultrastructure

Transmission electron microscopy

Single atom imaging with time-resolved electron microscopy

Furnival, Thomas

January 2017

Developments in scanning transmission electron microscopy (STEM) have opened up new possibilities for time-resolved imaging at the atomic scale. However, rapid imaging of single atom dynamics brings with it a new set of challenges, particularly regarding noise and the interaction between the electron beam and the specimen. This thesis develops a set of analytical tools for capturing atomic motion and analyzing the dynamic behaviour of materials at the atomic scale. Machine learning is increasingly playing an important role in the analysis of electron microscopy data. In this light, new unsupervised learning tools are developed here for noise removal under low-dose imaging conditions and for identifying the motion of surface atoms. The scope for real-time processing and analysis is also explored, which is of rising importance as electron microscopy datasets grow in size and complexity. These advances in image processing and analysis are combined with computational modelling to uncover new chemical and physical insights into the motion of atoms adsorbed onto surfaces. Of particular interest are systems for heterogeneous catalysis, where the catalytic activity can depend intimately on the atomic environment. The study of Cu atoms on a graphene oxide support reveals that the atoms undergo anomalous diffusion as a result of spatial and energetic disorder present in the substrate. The investigation is extended to examine the structure and stability of small Cu clusters on graphene oxide, with atomistic modelling used to understand the significant role played by the substrate. Finally, the analytical methods are used to study the surface reconstruction of silicon alongside the electron beam-induced motion of adatoms on the surface. Taken together, these studies demonstrate the materials insights that can be obtained with time-resolved STEM imaging, and highlight the importance of combining state-ofthe- art imaging with computational analysis and atomistic modelling to quantitatively characterize the behaviour of materials with atomic resolution.