Global ETD Search

11	From Bench to Battlefield: An Evaluation of in situ Forming Hydrogels as Vitreous Substitutes for Military and Combat Veterans MacPherson, Meoghan E. January 2017 (has links) Central to ocular health is the vitreous body, a complex, gelatinous tissue filling the space between the lens and retina. It is a natural polymeric hydrogel whose delicate architecture of collagen and hyaluronic acid loses its mechanical structure under the influence of degeneration or destruction, leaving the retina vulnerable to injury and disease. Since World War II, combat ocular trauma has increased six-fold while the population of aging veterans continues to grow in tandem. Compared to injuries in the civilian sector, injuries in theaters of combat operations are sustained in dirty, dusty, high-stress environments under hostile fire. These penetrating and perforating ocular injuries have predicable consequences, cascading into scarring on or under the retina (known as proliferative vitreoretinopathy or PVR). The growing population of aging veterans also faces a multitude of vitreous-related and vision-threatening pathologies. Current standards of care call for the removal and replacement of the vitreous, but contemporary substitutes are ill suited for long-term use. As such, there is critical need for development of a successful, long-term vitreous substitute. A biomimetic in situ forming hydrogel has been developed that utilizes a reversible disulfide cross-linker, enabling easy injection into the vitreous cavity. Recently, a copolymer has been introduced with this new formulation that possesses a unique comb-like structure whose characteristic bristles inhibit protein adsorption and cellular adherence, perfectly suited for the inhibition of PVR. The objective of this dissertation was to evaluate select formulations of this unique in situ forming hydrogel as potential vitreous substitutes. This was accomplished through rigorous in vivo rabbit modeled testing of long-term biocompatibility and bioperformance utilizing electroretinography, clinical examination, and histopathological assessment. We hypothesized that the in situ forming hydrogels would serve as a substantial improvement over the current gold standard, silicone oil, in terms of biocompatibility and the ability to inhibit PVR. / Bioengineering Engineering, Biomedical Ophthalmology Dutch-belted Electroretinogram In Situ Phosphocholine Proliferative Vitreoretinopathy Vitreous
12	Nanopatterning and functionalization of phospholipid-based Langmuir-Blodgett and Langmuir-Schaefer films Tang, Nathalie Y.-W. 08 1900 (has links) Durant les dernières décennies, la technique Langmuir-Blodgett (LB) s’est beaucoup développée dans l’approche « bottom-up » pour la création de couches ultra minces nanostructurées. Des patrons constitués de stries parallèles d’environ 100 à 200 nm de largeur ont été générés avec la technique de déposition LB de monocouches mixtes de 1,2-dilauroyl-sn-glycéro-3-phosphatidylcholine (DLPC) et de 1,2-dipalmitoyl-sn-glycéro-3-phosphatidylcholine (DPPC) sur des substrats de silicium et de mica. Afin d’amplifier la fonctionnalité de ces patrons, la 1-palmitoyl-2-(16-(S-methyldithio)hexadécanoyl)-sn-glycéro-3-phosphatidylcholine (DSDPPC) et la 1-lauroyl-2-(12-(S-methyldithio)dodédecanoyl)-sn-glycéro-3-phosphatidylcholine (DSDLPC) ont été employées pour la préparation de monocouches chimiquement hétérogènes. Ces analogues de phospholipide possèdent un groupement fonctionnel méthyldisulfide qui est attaché à la fin de l’une des chaînes alkyles. Une étude exhaustive sur la structure de la phase des monocouches Langmuir, Langmuir-Schaefer (LS) et LB de la DSDPPC et de la DSDLPC et leurs différents mélanges avec la DPPC ou la DLPC est présentée dans cette thèse. Tout d’abord, un contrôle limité de la périodicité et de la taille des motifs des stries parallèles de DPPC/DLPC a été obtenu en variant la composition lipidique, la pression de surface et la vitesse de déposition. Dans un mélange binaire de fraction molaire plus grande de lipide condensé que de lipide étendu, une vitesse de déposition plus lente et une plus basse pression de surface ont généré des stries plus continues et larges. L’addition d’un tensioactif, le cholestérol, au mélange binaire équimolaire de la DPPC/DLPC a permis la formation de stries parallèles à de plus hautes pressions de surface. La caractérisation des propriétés physiques des analogues de phospholipides a été nécessaire. La température de transition de phase de la DSDPPC de 44.5 ± 1.5 °C comparativement à 41.5 ± 0.3 °C pour la DPPC. L’isotherme de la DSDPPC est semblable à celui de la DPPC. La monocouche subit une transition de phase liquide-étendue-à-condensée (LE-C) à une pression de surface légèrement supérieure à celle de la DPPC (6 mN m-1 vs. 4 mN m-1) Tout comme la DLPC, la DSDLPC demeure dans la phase LE jusqu’à la rupture de la monocouche. Ces analogues de phospholipide existent dans un état plus étendu tout au long de la compression de la monocouche et montrent des pressions de surface de rupture plus basses que les phospholipides non-modifiés. La morphologie des domaines de monocouches Langmuir de la DPPC et de la DSDPPC à l’interface eau/air a été comparée par la microscopie à angle de Brewster (BAM). La DPPC forme une monocouche homogène à une pression de surface (π) > 10 mN/m, alors que des domaines en forme de fleurs sont formés dans la monocouche de DSDPPC jusqu’à une π ~ 30 mN m-1. La caractérisation de monocouches sur substrat solide a permis de démontrer que le patron de stries parallèles préalablement obtenu avec la DPPC/DLPC était reproduit en utilisant des mélanges de la DSDPPC/DLPC ou de la DPPC/DSDLPC donnant ainsi lieu à des patrons chimiquement hétérogènes. En général, pour obtenir le même état de phase que la DPPC, la monocouche de DSDPPC doit être comprimée à de plus hautes pressions de surface. Le groupement disulfide de ces analogues de phospholipide a été exploité, afin de (i) former des monocouches auto-assemblées sur l’or et de (ii) démontrer la métallisation sélective des terminaisons fonctionnalisées des stries. La spectrométrie de photoélectrons induits par rayons X (XPS) a confirmé que la monocouche modifiée réagit avec la vapeur d’or pour former des thiolates d’or. L’adsorption de l’Au, de l’Ag et du Cu thermiquement évaporé démontre une adsorption préférentielle de la vapeur de métal sur la phase fonctionnalisée de disulfide seulement à des recouvrements sub-monocouche. / In the past two decades, the Langmuir-Blodgett (LB) technique has emerged as a bottom-up route to create nanostructured ultrathin films. Patterns consisting of parallel stripes, ∼100 to 200 nm in width, were generated via the LB deposition of mixed monolayers of 1,2-dilauroyl-sn-glycero-3-phosphocholine (DLPC), and 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) onto silicon and mica substrates. To expand the functionality of these patterns, 1-palmitoyl-2-(16-(S-methyldithio)hexadecanoyl)-sn-glycero-3-phosphocholine (DSDPPC) and 1-lauroyl-2-(12-(S-methyldithio)dodecanoyl)-sn-glycero-3-phosphocholine (DSDLPC) were used to prepare chemically heterogeneous films. These phospholipid analogues have a methyldisulfide group attached to one of the alkyl chain ends. An extensive study of the phase structure of Langmuir, Langmuir-Shaefer and LB films of DSDPPC and DSDLPC and their mixtures with DPPC or DLPC is presented in this thesis. Limited control over the regularity and feature size of the DPPC/DLPC stripe pattern was achieved by varying the lipid composition, deposition pressure, and substrate withdrawal speed. A higher percentage of condensed versus fluid lipid, slower deposition speed, and lower surface pressure create more continuous and wider stripes. The addition of a lineactant, cholesterol, to the DPPC/DLPC 1:1 (mol/mol) mixture allowed the formation of parallel stripes at higher surface pressure. The gel-to-liquid crystalline transition temperature of DSDPPC was determined to be 44.5 ± 1.5 °C versus 41.5 ± 0.3 °C for DPPC by DSC and turbidity measurements. The pressure-area isotherm of DSDPPC is similar to that of DPPC. The monolayer undergoes a liquid expanded-to-condensed (LE-C) phase transition at a surface pressure slightly higher than that of DPPC (6 mN m-1 vs. 4 mN m-1). Like DLPC, DSDLPC remains in the LE phase until the film collapse. The disulfide-modified lipids exist in a more expanded state throughout the monolayer compression and exhibit lower collapse pressures than the unmodified phospholipids. The domain morphologies of DPPC and DSDPPC at the air/water interface were compared using Brewster Angle Microscopy. DPPC forms a homogeneous monolayer at a surface pressure (π) > 10 mN m-1, while flower-like domains exist in the DSDPPC monolayers until π ∼ 30 mN m-1. Solid-supported DSDPPC films were prepared and characterized using various surface analysis techniques. The parallel stripe pattern previously obtained with mixtures of DPPC/DLPC was reproduced using DSDPPC/DLPC or DPPC/DSDLPC mixtures resulting in chemically-differentiated patterns. The average stripe width varied from 150 to 500 nm, depending on the lipid composition and deposition pressure. The disulfide group of the analogues was exploited to (i) form self-assembled monolayers of phospholipids on gold and (ii) demonstrate the selective metallization of the disulfide-terminated areas of the stripe patterns. X-ray photoelectron spectroscopy (XPS) confirmed that the monolayer-bound disulfides react with Au vapor to form a gold-thiolate species. Thermally evaporated Au, Ag and Cu exhibit preferential absorption onto the modified lipids only at submonolayer coverages. DPPC DPPC DLPC DLPC Séparation de phase Phase separation Langmuir-Blodgett Langmuir-Blodgett Langmuir-Schaefer Langmuir-Schaefer Patronnage de surface Surface patterning Thiolate d'or Gold-thiolates Métallisation sélective Selective metallization
13	Comparison of Anti-Pneumococcal Functions of Native and Modified Forms of C-Reactive Protein Ngwa, Donald Neba 01 May 2016 (has links) The anti-pneumococcal function of native C-reactive protein (CRP) involves its binding to phosphocholine molecules present on Streptococcus pneumoniae and subsequent activation of the complement system. However, when pneumococci recruit complement inhibitory protein factor H on their surface, they escape complement attack. Non-native forms of CRP have been shown to bind immobilized factor H. Accordingly, we hypothesized that modified CRP would bind to factor H on pneumococci, masking its complement inhibitory activity, allowing native CRP to exert its anti-pneumococcal function. As reported previously, native CRP protected mice from lethal pneumococcal infection when injected 30 minutes before infection but not when injected 24 hours after infection. However, a combination of native and mutant CRP was found to protect mice even when administered 24 hours after infection. Therefore, it is concluded that while native CRP is protective only against early-stage infection, a combination of native and mutant CRP offers protection against late-stage infection. C-reactive protein Complement Factor H Phosphocholine Phosphoethanolamine Pneumococcal C-polysaccharide Streptococcus pneumoniae Immunity Immunology of Infectious Disease Immunopathology Pathogenic Microbiology
14	Nanopatterning and functionalization of phospholipid-based Langmuir-Blodgett and Langmuir-Schaefer films Tang, Nathalie Y.-W. 08 1900 (has links) Durant les dernières décennies, la technique Langmuir-Blodgett (LB) s’est beaucoup développée dans l’approche « bottom-up » pour la création de couches ultra minces nanostructurées. Des patrons constitués de stries parallèles d’environ 100 à 200 nm de largeur ont été générés avec la technique de déposition LB de monocouches mixtes de 1,2-dilauroyl-sn-glycéro-3-phosphatidylcholine (DLPC) et de 1,2-dipalmitoyl-sn-glycéro-3-phosphatidylcholine (DPPC) sur des substrats de silicium et de mica. Afin d’amplifier la fonctionnalité de ces patrons, la 1-palmitoyl-2-(16-(S-methyldithio)hexadécanoyl)-sn-glycéro-3-phosphatidylcholine (DSDPPC) et la 1-lauroyl-2-(12-(S-methyldithio)dodédecanoyl)-sn-glycéro-3-phosphatidylcholine (DSDLPC) ont été employées pour la préparation de monocouches chimiquement hétérogènes. Ces analogues de phospholipide possèdent un groupement fonctionnel méthyldisulfide qui est attaché à la fin de l’une des chaînes alkyles. Une étude exhaustive sur la structure de la phase des monocouches Langmuir, Langmuir-Schaefer (LS) et LB de la DSDPPC et de la DSDLPC et leurs différents mélanges avec la DPPC ou la DLPC est présentée dans cette thèse. Tout d’abord, un contrôle limité de la périodicité et de la taille des motifs des stries parallèles de DPPC/DLPC a été obtenu en variant la composition lipidique, la pression de surface et la vitesse de déposition. Dans un mélange binaire de fraction molaire plus grande de lipide condensé que de lipide étendu, une vitesse de déposition plus lente et une plus basse pression de surface ont généré des stries plus continues et larges. L’addition d’un tensioactif, le cholestérol, au mélange binaire équimolaire de la DPPC/DLPC a permis la formation de stries parallèles à de plus hautes pressions de surface. La caractérisation des propriétés physiques des analogues de phospholipides a été nécessaire. La température de transition de phase de la DSDPPC de 44.5 ± 1.5 °C comparativement à 41.5 ± 0.3 °C pour la DPPC. L’isotherme de la DSDPPC est semblable à celui de la DPPC. La monocouche subit une transition de phase liquide-étendue-à-condensée (LE-C) à une pression de surface légèrement supérieure à celle de la DPPC (6 mN m-1 vs. 4 mN m-1) Tout comme la DLPC, la DSDLPC demeure dans la phase LE jusqu’à la rupture de la monocouche. Ces analogues de phospholipide existent dans un état plus étendu tout au long de la compression de la monocouche et montrent des pressions de surface de rupture plus basses que les phospholipides non-modifiés. La morphologie des domaines de monocouches Langmuir de la DPPC et de la DSDPPC à l’interface eau/air a été comparée par la microscopie à angle de Brewster (BAM). La DPPC forme une monocouche homogène à une pression de surface (π) > 10 mN/m, alors que des domaines en forme de fleurs sont formés dans la monocouche de DSDPPC jusqu’à une π ~ 30 mN m-1. La caractérisation de monocouches sur substrat solide a permis de démontrer que le patron de stries parallèles préalablement obtenu avec la DPPC/DLPC était reproduit en utilisant des mélanges de la DSDPPC/DLPC ou de la DPPC/DSDLPC donnant ainsi lieu à des patrons chimiquement hétérogènes. En général, pour obtenir le même état de phase que la DPPC, la monocouche de DSDPPC doit être comprimée à de plus hautes pressions de surface. Le groupement disulfide de ces analogues de phospholipide a été exploité, afin de (i) former des monocouches auto-assemblées sur l’or et de (ii) démontrer la métallisation sélective des terminaisons fonctionnalisées des stries. La spectrométrie de photoélectrons induits par rayons X (XPS) a confirmé que la monocouche modifiée réagit avec la vapeur d’or pour former des thiolates d’or. L’adsorption de l’Au, de l’Ag et du Cu thermiquement évaporé démontre une adsorption préférentielle de la vapeur de métal sur la phase fonctionnalisée de disulfide seulement à des recouvrements sub-monocouche. / In the past two decades, the Langmuir-Blodgett (LB) technique has emerged as a bottom-up route to create nanostructured ultrathin films. Patterns consisting of parallel stripes, ∼100 to 200 nm in width, were generated via the LB deposition of mixed monolayers of 1,2-dilauroyl-sn-glycero-3-phosphocholine (DLPC), and 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) onto silicon and mica substrates. To expand the functionality of these patterns, 1-palmitoyl-2-(16-(S-methyldithio)hexadecanoyl)-sn-glycero-3-phosphocholine (DSDPPC) and 1-lauroyl-2-(12-(S-methyldithio)dodecanoyl)-sn-glycero-3-phosphocholine (DSDLPC) were used to prepare chemically heterogeneous films. These phospholipid analogues have a methyldisulfide group attached to one of the alkyl chain ends. An extensive study of the phase structure of Langmuir, Langmuir-Shaefer and LB films of DSDPPC and DSDLPC and their mixtures with DPPC or DLPC is presented in this thesis. Limited control over the regularity and feature size of the DPPC/DLPC stripe pattern was achieved by varying the lipid composition, deposition pressure, and substrate withdrawal speed. A higher percentage of condensed versus fluid lipid, slower deposition speed, and lower surface pressure create more continuous and wider stripes. The addition of a lineactant, cholesterol, to the DPPC/DLPC 1:1 (mol/mol) mixture allowed the formation of parallel stripes at higher surface pressure. The gel-to-liquid crystalline transition temperature of DSDPPC was determined to be 44.5 ± 1.5 °C versus 41.5 ± 0.3 °C for DPPC by DSC and turbidity measurements. The pressure-area isotherm of DSDPPC is similar to that of DPPC. The monolayer undergoes a liquid expanded-to-condensed (LE-C) phase transition at a surface pressure slightly higher than that of DPPC (6 mN m-1 vs. 4 mN m-1). Like DLPC, DSDLPC remains in the LE phase until the film collapse. The disulfide-modified lipids exist in a more expanded state throughout the monolayer compression and exhibit lower collapse pressures than the unmodified phospholipids. The domain morphologies of DPPC and DSDPPC at the air/water interface were compared using Brewster Angle Microscopy. DPPC forms a homogeneous monolayer at a surface pressure (π) > 10 mN m-1, while flower-like domains exist in the DSDPPC monolayers until π ∼ 30 mN m-1. Solid-supported DSDPPC films were prepared and characterized using various surface analysis techniques. The parallel stripe pattern previously obtained with mixtures of DPPC/DLPC was reproduced using DSDPPC/DLPC or DPPC/DSDLPC mixtures resulting in chemically-differentiated patterns. The average stripe width varied from 150 to 500 nm, depending on the lipid composition and deposition pressure. The disulfide group of the analogues was exploited to (i) form self-assembled monolayers of phospholipids on gold and (ii) demonstrate the selective metallization of the disulfide-terminated areas of the stripe patterns. X-ray photoelectron spectroscopy (XPS) confirmed that the monolayer-bound disulfides react with Au vapor to form a gold-thiolate species. Thermally evaporated Au, Ag and Cu exhibit preferential absorption onto the modified lipids only at submonolayer coverages. DPPC DPPC DLPC DLPC Séparation de phase Phase separation Langmuir-Blodgett Langmuir-Blodgett Langmuir-Schaefer Langmuir-Schaefer Patronnage de surface Surface patterning Thiolate d'or Gold-thiolates Métallisation sélective Selective metallization
15	A Novel Mode of Action of C-reactive Protein in Protecting Against Streptococcus pneumoniae Infection and Synergy with Antibiotics Ngwa, Donald 01 May 2020 (has links) C-reactive protein (CRP) is a part of the innate immune system, is synthesized in the liver, its blood level increases in inflammatory states, and it binds to Streptococcus pneumoniae. The conformation of CRP is altered under conditions mimicking an inflammatory milieu and this non-native CRP also binds to immobilized/aggregated/pathogenic proteins. Experiments in mice have revealed that one of the functions of CRP is to protect against pneumococcal infection. For protection, CRP must be injected into mice within two hours of administering pneumococci, thus, CRP is protective against early-stage infection but not against late-stage infection. It is unknown how CRP protects or why CRP does not protect against late-stage infection. The hypotheses are that the protection requires complement activation by CRP-pneumococci complexes and that CRP cannot protect if pneumococci have time to recruit complement inhibitor factor H on their surface to become complement attack-resistant. To test these hypotheses, we generated CRP mutants by site-directed mutagenesis: a mutant that binds to pneumococci but does not activate complement and a mutant that binds to immobilized factor H. We found that mutant CRP incapable of activating complement was not protective against infection and that mutant CRP capable of binding to factor H was protective against both early and late stage infections. Additional experiments showed that CRP enhances the effects of the antibiotic clarithromycin in reducing bacteremia in infected mice. Moreover, we observed that mutant CRP capable of binding to factor H bound to several proteins immobilized on plastic, suggesting that CRP recognizes a pattern, probably an amyloid-like structure, on immobilized proteins. Indeed, mutant CRP, after binding to amyloid b peptides, prevented the formation of pathogenic amyloid fibrils. Lastly, employing a hepatic cell line, we investigated the mechanism of CRP expression in response to pro-inflammatory cytokines. We found that the transcription factor C/EBPb and two C/EBP-binding sites on the CRP promoter were critical for inducing CRP expression. We conclude that complement activation is necessary for CRP-mediated protection against infection, that CRP functions in two structural conformations, that CRP and clarithromycin act synergistically, that CRP has anti-amyloidogenic properties, and the increased CRP expression requires C/EBPb. C-reactive protein Complement Factor H Phosphocholine Pneumococcal C-polysaccharide Streptococcus pneumoniae Biochemistry Molecular Biology Pathogenic Microbiology
16	The Protective Function of Human C-Reactive Protein in Mouse Models of Streptococcus Pneumoniae Infection Agrawal, Alok, Suresh, Madathilparambil V., Singh, Sanjay K., Ferguson, Donald A. 01 December 2008 (has links) Human C-reactive protein (CRP), injected intravenously into mice or produced inside mice by a human transgene, protects mice from death following administration of lethal numbers of Streptococcus pneumoniae. The protective effect of CRP is due to reduction in the concentration of bacteria in the blood. The exact mechanism of CRP-dependent killing of pneumococci and the partners of CRP in this process are yet to be defined. The current efforts to determine the mechanism of action of CRP in mice are directed by four known in vitro functions of CRP: 1. the ability of pneumococcal C-polysaccharide-complexed CRP to activate complement pathways, 2. the ability of CRP to bind to Fcγ receptors on phagocytic cells, 3. the ability of CRP to bind to immobilized complement regulator protein factor H which can also be present on pneumococci, and, 4. the ability of CRP to interact with dendritic cells. CRP-treated dendritic cells may well be as host-defensive as CRP alone. An interesting condition for the protective function of CRP is that CRP must be given to mice within a few hours of the administration of pneumococci. CRP does not protect mice if given later, suggesting that CRP works prophylactically but not as a treatment for infection. However, full knowledge of CRP may lead to the development of CRP-based treatment strategies to control pneumococcal infection. Also, because CRP deficiency in humans has not yet been reported, it becomes important to investigate the deficiency of the mechanism of action of CRP in CRP-positive individuals. C-reactive protein complement system dendritic cells factor H Fcγ receptors lectin pathway phagocytosis phosphocholine pneumococci Biomedical Sciences
17	Near-Field Investigations of the Anisotropic Properties of Supported Lipid Bilayers Johnson, Merrell A. 24 July 2012 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / The details of Polarization Modulation Near-Field Scanning Optical Microscopy (PM-NSOM) are presented. How to properly calibrate and align the system is also introduced. A measurement of Muscovite crystal is used to display the capabilities of the setup. Measurements of supported Lβʹ 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) lipid bilayers are presented, emphasizing how it was tooled in exploiting the anisotropic nature of the acyl chains. A discussion of how the effective retardance (ΔS = 2π( n_e-n_o )t/λ) and the direction of the projection of the acyl chains (θ) are measured simultaneously is given, (where t is the thickness of the bilayer and λ is the wavelength of light used). It is shown from ΔS the birefringence (ne-no) of the bilayer is determined, by assuming the acyl chain tilt with respect to the membrane's normal to be ϕ ≈ 32. Time varying experiments show lateral diffusions of ~ 2 x 10-12 cm2/s. Temperature controlled PM-NSOM is shown to be a viable way to determine the main phase transition temperature (Tm) for going from the gel Lβʹ to liquid disorder Lα state of supported DPPC bilayers. A change of ΔS ~ (3.8 +/- 0.3 mrad) at the main phase transition temperature Tm (≈41^o C) is observed. This agrees well with previous values of (ne-no) and translates to an assumed <ϕ> ~ 32^o when T < Tm and 0^o when T > Tm. Evidence of supper heating and supper cooling will be presented, along with a discussion of the fluctuations that occur around Tm. Finally it is shown how physical parameters such as the polarizability are extracted from the data. Values of the transverse (αt) and longitudinal (αl) polarizabilites of the acyl chains are shown to be, αt = 44.2 Å3 and αl = 94.4 Å3, which correspond well with the theoretical values of a single palmitic acid (C16) αt = 25.14 Å3 and αl = 45.8 Å3. Near-Field Scanning Optical Microscopy birefringence Near-field microscopy -- Technique Scanning probe microscopy Anisotropy Refractive index Materials at high temperatures Phospholipids
18	The lipopolysaccharide of Haemophilus parainfluenzae Young, Rosanna E. B. January 2011 (has links) Haemophilus parainfluenzae (Hp) and H. influenzae (Hi) are closely related members of the Pasteurellaceae family and are common commensal bacteria of the human nasopharynx. Whilst Hi is frequently implicated in meningitis, otitis media and respiratory tract infections, reports of pathogenic behaviour by Hp are very rare. Lipopolysaccharide (LPS) is a key component of the Gram negative cell wall, and its structure influences the ability of Haemophilus to interact with the host and evade immune clearance. A better understanding of the differences in LPS structure between Hi and Hp could help to ascertain which parts of the molecule are important for commensal and pathogenic behaviour. Hi LPS comprises lipid A, a conserved oligosaccharide inner core, and an oligosaccharide outer core that differs between strains. The latter is partly phase variable by the slipped strand mispairing during replication of DNA repeat tracts within several LPS biosynthesis genes. Very little was known about LPS in Hp so we investigated its biosynthesis and structure in a panel of 20 Hp carriage isolates. Using PCR, DNA sequencing and Southern analysis we demonstrated that Hp possesses homologues of the Hi lipid A and inner core LPS synthesis genes and a few of the genes for outer core synthesis; however, homologues of the Hi phase variable outer core genes were largely absent and did not contain repeat tracts. The results of immunoblotting and collaborative structural analysis were consistent with this data. Phosphocholine, a phase variable Hi LPS epitope that has been implicated in otitis media, was found to be absent in Hp LPS due to the lack of four genes required for its biosynthesis and incorporation. The introduction of these genes into Hp led to the phase variable addition of phosphocholine to the LPS, indicating that there is no fundamental reason why Hp could not use a similar mechanism of variation to Hi if it was advantageous to do so. SDS-PAGE data suggested the presence of O-antigens (repeated chains of sugars) in many of the Hp strains, an unusual feature for Haemophilus, and all of the strains were found to contain a potential O-antigen synthesis locus. Each locus encodes homologues of several glycosyltransferases in addition to either the Wzy polymerase- or ABC transporter-dependent mechanisms of O-antigen synthesis and transport. Comparisons of wild type and isogenic mutant strains showed that the O-antigen enhances resistance to complement-mediated killing and appears to affect adhesion to epithelial cells in vitro. Hp is a successful commensal organism but lacks the flexibility of adapting its LPS using repeat-mediated phase variation, potentially limiting its range of host niches. 579
19	Developent of a Phospholipid Encapsulation Process for Quantum Dots to Be Used in Biologic Applications Grimes, Logan 01 June 2014 (has links) (PDF) The American Cancer Society predicts that 1,665,540 people will be diagnosed with cancer, and 585,720 people will die from cancer in 2014. One of the most common types of cancer in the United States is skin cancer. Melanoma alone is predicted to account for 10,000 of the cancer related deaths in 2014. As a highly mobile and aggressive form of cancer, melanoma is difficult to fight once it has metastasized through the body. Early detection in such varieties of cancer is critical in improving survival rates in afflicted patients. Present methods of detection rely on visual examination of suspicious regions of tissue via various forms of biopsies. Accurate assessment of cancerous cells via this method are subjective, and often unreliable in the early stages of cancer formation when only few cancer cells are forming. With fewer cancer cells, it is less likely that a cancer cell will appear in a biopsied tissue. This leads to a lower detection rate, even when cancer is present. This lack of detection when cancer is in fact present is referred to as a false negative. False negatives can have a highly detrimental effect on treating the cancer as soon as possible. More accurate methods of detecting cancer in early stages, in a nonsubjective form would alleviate these problems. A proposed alternative to visual examination of biopsied legions is to utilize fluorescent nanocrystalline biomarker constructs to directly attach to the abnormal markers found on cancerous tissues. Quantum dots (QDs) are hydrophobic nanoscale crystals composed of semiconducting materials which fluoresce when exposed to specific wavelengths of radiation, most commonly in the form of an ultraviolet light source. The QD constructs generated were composed of cadmium-selenium (CdSe) cores encapsulated with zinc-sulfide (ZnS) shells. These QDs were then encapsulated with phospholipids in an effort to create a hydrophilic particle which could interact with polar fluids as found within the human body. The goal of this thesis is to develop a method for the solubilization, encapsulation, and initial functionalization of CdSe/ZnS QDs. The first stage of this thesis focused on the generation of CdSe/ZnS QDs and the fluorescence differences between unshelled and shelled QDs. The second stage focused on utilizing the shelled QDs to generate hydrophilic constructs by utilizing phospholipids to bind with the QDs. Analysis via spectroscopy was performed in an effort to characterize the difference in QDs both prior to and after the encapsulation process. The method generated provides insight on fluorescence trends and the encapsulation of QDs in polar substances. Future research focusing on the repeatability of the process, introducing the QD constructs to a biological material, and eventual interaction with cancer cells are the next steps in generating a new technique to target and reveal skin cancer cells in the earliest possible stages without using a biopsy. Quantum Dots nanotechnology nanotech nano bionanotechnology biomarker biomarkers nanoparticles fluorescent nanocrystal phospholipids phospholipid phosphocholine CdSe ZnS Biochemical and Biomolecular Engineering Bioimaging and Biomedical Optics Biology and Biomimetic Materials Biomaterials Biotechnology Ceramic Materials Nanomedicine Nanoscience and Nanotechnology Other Chemical Engineering Other Materials Science and Engineering Semiconductor and Optical Materials

Search results