Spelling suggestions: "subject:"bilayer.""
1 |
The simulation of biomembranes and drug transport therein using a Gay Berne modelHaubertin, David Yan January 2003 (has links)
No description available.
|
2 |
Post translational insertion of thylakoid membrane proteinsWoolhead, Cheryl Anne January 2001 (has links)
No description available.
|
3 |
The form and function of MP26 in artificial membranes and liposomesTickner, A. L. January 1995 (has links)
No description available.
|
4 |
Mimicking anhydrobiosis on solid supported lipid bilayersChapa, Vanessa Alyss 17 September 2007 (has links)
The studies presented in this thesis focus on the synthesis of air-stable solid
supported lipid bilayers by anhydrobiotic mechanisms. Supported lipid bilayers (SLBs)
serve as platforms that mimic cellular membrane surfaces in appearance and behavior.
One of the most attractive aspects of the SLB is that it exhibits two-dimensional fluidity
that allows for individual components to rearrange as they would in actual cellular
membranes. The one thing that would allow the SLB to become an ideal biosensor is the
ability to remain stable in the absence of bulk water. As it stands now, unprotected
SLBs are unstable in the presence of air causing the membrane to rearrange and
delaminate from the surface.
Several biological organisms utilize the process of anhydrobiosis to persevere in
severe dehydrated states. Anhydrobiosis occurs when organisms employ large amounts
of sugars, particularly disaccharides, to protect their cell membranes. The sugars, often
released as a stress response, protect the membrane by replacing the water around the
lipid headgroups while also interacting with other sugars to form a glass atop the bilayer. One of the most successful anhydrobiotic sugars has been trehalose, although other
sugars have been evaluated and are capable of protecting lipid bilayers minimally.
The experimental section of this thesis involves the creation of SLBs that are
examined with and without the presence of sugar molecules. Essentially, the SLB was
created, exposed to sugar solutions, dried, and subsequently rehydrated. Successful
experiments occurred when rehydrated bilayers exhibited little damage and were mobile
and functional. In addition to trehalose, several other mono- and disaccharides were
used as were glycolipids, lipids with sugar headgroups. Upon the completion of all
experiments it was clear that trehalose afforded the most protection of all species tested
and that glycolipids do not sufficiently protect the membrane during rehydration.
Therefore, the addition of a sugar such as trehalose to an SLB could allow for the
creation of an air-stable biosensor that would be both practical and require little
maintenance.
|
5 |
Supported phospholipid membranes as biometric labs-on-a-chip: analytical devices that mimic cell membrane architectures and provide insight into the mechanism of biopreservationAlbertorio, Fernando 17 September 2007 (has links)
This dissertation focuses on the applications of solid supported phospholipid
membranes as mimics of the cellular membrane using lab-on-a-chip devices in order to
study biochemical events such as ligand-receptor binding and the chemical mechanism
for the preservation of the biomembrane. Supported lipid bilayers (SLBs) mimic the
native membrane by presenting the important property of two-dimensional lateral
fluidity of the individual lipid molecules within the membrane. This is the same
property that allows for the reorganization of native membrane components and
facilitates multivalent ligand-receptor interactions akin to immune response, cell
signaling, pathogen attack and other biochemical processes.
The study is divided into two main facets. The first deals with developing a
novel lipopolymer supported membrane biochip consisting of Poly(ethylene glycol)
(PEG)-lipopolymer incorporated membranes. The formation and characterization of the
lipopolymer membranes was investigated in terms of the polymer size, concentration
and molecular conformation. The lateral diffusion of the PEG-bilayers was similar to
the control bilayers. The air-stability conferred to SLBs was determined to be more effective when the PEG polymer was at, or above, the onset of the mushroom-to-brush
transition. The system is able to function even after dehydration for 24 hours. Ligandreceptor
binding was analyzed as a function of PEG density. The PEG-lipopolymer acts
as a size exclusion barrier for protein analytes in which the binding of streptavidin was
unaffected whereas the binding of the much larger IgG and IgM were either partially or
completely inhibited in the presence of PEG.
The second area of this study presents a molecular mechanism for in vivo
biopreservation by employing solid supported membranes as a model system. The
molecular mechanism of how a variety of organisms are preserved during stresses such
as anhydrobiosis or cryogenic conditions was investigated. We investigated the
interaction of two disaccharides, trehalose and maltose with the SLBs. Trehalose was
found to be the most effective in preserving the membrane, whereas maltose exhibited
limited protection. Trehalose lowers the lipid phase transition temperature and
spectroscopic evidence shows the intercalation of trehalose within the membrane
provides the chemical and morphological stability under a stress environment.
|
6 |
Interações entre vesículas sintéticas ou fosfolipídicas e superfícies de óxido de silício / Interactions between synthetic vesicles or phospholipids and silicon oxide surfacesRapuano, Renata 28 April 2000 (has links)
Isotermas de adsorção de anfifílicos sintéticos formadores de bicamadas ou fosfolipídios a partir de vesículas sobre partículas de sílica hidrofílica (AEROSIL OX-50) foram obtidas em diversas condições experimentais. Vesículas pequenas de fosfatidilcolina (PC), dipahnitoilfosfatidilcolina (DPPC), dihexadecilfosfato (DHP) e brometo de dioctadecildimetilamônio (DODAB) dispersas em 10 mM de dois diferentes tampões (Tris ou HEPES) em 3 diferentes valores de pH apresentam afinidades pela sílica que seguem a seqüência: DODAB>DPPC>PC>DHP. Deposição de bicamada de fosfolipídio é favorecida pela presença de Tris como tampão em pH ≤ 7,4, e temperaturas acima da temperatura de transição de fase para bicamada de fosfolipídio. Interação a 65 ºC por 1 hora entre vesículas de DPPC e sílica eficientemente gera a deposição de bicamada com uma adsorção máxima, se Tris é o tampão utilizado. Consistentemente, a molhabilidade de superfícies planares de SiO2 em condições de deposição de bicamada (como descrita pelas isotermas de adsorção) na presença de vesículas lipídicas mostra um grande aumento da hidrofobicidade da superfície para vesículas de DPPC a 65 ºC e DODAB em temperatura ambiente. Redução na absorção de luz pela MC540 em 565 nm foi usada como indicativa de deposição de bicamada sobre partículas de sílica. Durante a interação com partículas sólidas, a absorbância a 565 nm mostra uma diminuição que corresponde a porcentagem de marcador que se intercala entre a bicamada e a partícula sólida e, conseqüentemente, se esconde da luz incidente. Para DPPC, à 65 ºC, e DODAB à temperatura ambiente, mas não para PC, a ocorrência de deposição de bicamada, descrita pelas isotermas de adsorção, é confirmada pelas três técnicas empregadas para detecção. / Adsorption isotherms of bilayer-forming synthetic amphiphiles or phospholipids from vesicles onto hydrophilic silica particles (AEROSIL 0X-50) are obtained over a range of experimental conditions. Phosphatidylcholine (PC), dipalmitoylphosphatidylcholine (DPPC), and dioctadecyldimethylammonium bromide (DODAB) dispersed in 10 mM of two different buffers (Tris or HEPES) at 3 different pH values as small unilamellar vesicles present affinities for silica following the sequence: DODAB > DPPC > PC. Deposition of phospholipid bilayers was favoured by the presence of Tris as buffer, pH≤ 7.4, and temperatures above the phase transition temperature (Tc) for the phospholipid bilayer. Interaction at 65 ºC for 1 h between DPPC vesicles and silica efficiently leads to bilayer deposition at maximal adsorption, if Tris is the buffer used. Consistently, wettability of SiO2 planar surfaces precisely under conditions of bilayer deposition (as depicted from the isotherms) in the presence of the lipidic vesicles yielded a large increase on surface hydrophobicity for DPPC at 65 ºC and DODAB at room temperature. Reduction of merocyanine 540 absorbance at 565 nm was used as a marker for bilayer deposition onto the silica particles. Upon interaction with the solid particle, absorbance at 565 nm displays a decrease with rime that corresponds to the percentage of dye that became sandwiched between the bilayer and the solid particle surface and thereby hidden from the incident light. For DPPC at 65 ºC and DODAB at room temperature, but not for PC, occurrence of bilayer deposition depicted from the adsorption isotherms is confirmed from the three techniques employed for detection.
|
7 |
Physico-chemical investigations of, and characterization of model membranes for, lipid-peptide interactions /Wessman, Per, January 2009 (has links)
Diss. (sammanfattning) Uppsala : Uppsala universitet, 2009. / Härtill 3 uppsatser.
|
8 |
Investigating the aggregation of β-amyloid peptide (Aβ₄₂) and its interactions with lipid bilayers using advanced microscopy techniquesMari, Meropi January 2014 (has links)
The cell membrane is a highly complex structure consisting of a large diversity of phospholipids and macromolecules. There exist a variety of diseases that compromise the integrity of this key component of the cell. This thesis considers the investigation of interactions between β-amyloid peptide (Aβ₄₂) and lipid bilayers. To facilitate understanding of this complex system, it is advantageous to employ a model sample; supported lipid bilayers (SLB) and giant multilamellar vesicles (MLVs) are used as proxy cell membranes. These nanostructures are widely used as models of cellular membranes in many areas of scientific research. Phospholipid molecules self-organise into bilayer structures containing phase-separated microdomains, which are believed to be important in many biological processes. This study aims to develop model systems and experimental tools to explore hypothetical mechanisms through which the β-amyloid interacts with the lipid membranes. A lack of mechanistic understanding is the major challenge to our efforts to elucidate not only the interactions of the Aβ42 with the lipid membranes, but also the behaviour of these systems towards the changes of the environmental conditions (pH, concentration, temperature). Our results suggest that there are various different methods, such as AFM, CARS microscopy and Raman spectroscopy as well as neutron scattering that are capable of fast imaging. Overall, all these techniques contributed in a complementary study of Aβ₄₂ aggregation states under extreme and physiological conditions as well as to image Aβ₄₂ interactions with lipid bilayers consisted of specific lipids.
|
9 |
Interaction Between Antimicrobial Peptides and Phospholipid Membranes Effects of Peptide Length and Composition /Ringstad, Lovisa. January 2009 (has links)
Diss. (sammanfattning) Uppsala : Uppsala universitet, 2009. / Härtill 5 uppsatser.
|
10 |
Characterization of the interaction of phospholipase A₂ with binary lipid vesicles /Gadd, Martha Elaine. January 2000 (has links)
Thesis (Ph. D.)--University of Virginia, 2000. / Spine title: Phospholipase A₂ binding. Includes bibliographical references (p. 245-258). Also available online through Digital Dissertations.
|
Page generated in 0.0789 seconds