The control of pulmonary surfactant development in oviparous amniotes / Lucy C. Sullivan.

Sullivan, Lucy Catherine

January 2002

"April 2002" / Bibliography: leaves 154-193. / ix, 198 leaves : ill. (some col.), plates (some col.) ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Environmental Biology, 2002

Pulmonary surfactant.

Amniotes.

Pulmonary surfactant protein a regulation of macrophage toll-like receptor expression, activity, and trafficking /

Henning, Lisa Novik,

January 2008

Thesis (Ph. D.)--Ohio State University, 2008. / Title from first page of PDF file. Includes bibliographical references (p. 151-178).

Control of pulmonary surfactant secretion : an evolutionary perspective /

Wood, Philip

January 1999

Thesis (Ph.D.) -- University of Adelaide, Dept. of Physiology, 1999. / Bibliography: leaves 209-254.

Development of the pulmonary surfactant system in non-mammalian amniotes /

Johnston, Sonya D.

January 2001

Thesis (Ph.D.) -- University of Adelaide, Dept. of Physiology, 2001. / "March 2001". Bibliography: leaves 193-238.

Association and interactions of pulmonary surfactant lipids and proteins in model membranes at the air-water interface /

Nag, Kaushik,

January 1996

Thesis (Ph.D.)--Memorial University of Newfoundland, 1997. / Bibliography: leaves 304-374.

A report on the surfactant system of the lung

Ray, Jeanette Susan

January 2010

Photocopy of typescript. / Digitized by Kansas Correctional Industries

Lungs

Pulmonary surfactant

Surface active agents

The evolution of a physiological system: the pulmonary surfactant system in diving mammals.

Miller, Natalie J

January 2005

Pulmonary surfactant is a complex mixture of lipids and proteins that lowers surface tension, increases lung compliance, and prevents the adhesion of respiratory surfaces and pulmonary oedema. Pressure can have an enormous impact on respiratory function, by mechanically compressing tissues, increasing gas tension resulting in increased gas absorption and by increasing dissolved gas tensions during diving, resulting in the formation of bubbles in the blood and tissues. The lungs of diving mammals have a huge range of morphological adaptations to enable them to endure the extremely high pressures associated with deep diving. Here, I hypothesise that surfactant will also be modified, to complement the morphological changes and enable more efficient lung function during diving. Molecular adaptations to diving were examined in surfactant protein C (SP-C) using phylogenetic analyses. The composition and function of pulmonary surfactant from several species of diving mammals was examined using biochemical assays, mass spectrometry and captive bubble surfactometry. The development of surfactant in one species of diving mammal (California sea lion), and the control of surfactant secretion using chemical and mechanical stimuli were also determined. Diving mammals showed modifications to SP-C, which are likely to lead to stronger binding to the monolayer, thereby increasing its fluidity. Phospholipid molecular species concentrations were altered to increase the concentration of more fluid species. There was also an increase in the percentage of alkyl molecular species, which may increase the stability of the monolayer during compression and facilitate rapid respreading. Levels of SP-B were much lower in the diving species, and cholesterol was inversely proportional to the maximum dive depth of the three species. Surface activity of surfactant from diving mammals was very poor compared to surfactant from terrestrial mammals. The newborn California sea lion surfactant was similar to terrestrial mammal surfactant, suggesting that these animals develop the diving-type of surfactant after they first enter the water. The isolated cells of California sea lions also showed a similar response to neuro-hormonal stimulation as terrestrial mammals, but were insensitive to pressure. These findings showed diving mammal surfactant to have a primarily anti-adhesive function that develops after the first entry into the water, with a surfactant monolayer, which would be better suited to repeated collapse and respreading. / Thesis (Ph.D.)--School of Earth and Environmental Sciences, 2005.

Association and interaction of serum albumin with lung surfactant extract /

Vidyasankar, Sangeetha,

January 2004

Thesis (M.Sc.)--Memorial University of Newfoundland, 2005. / Bibliography: leaves 117-129.

The Structure and Function of Lung Surfactant: Effect of Amyloid Fibril Formation

Hane, Francis

08 May 2009

The alveoli of mammalian lungs are covered in a thin lipid film referred to as pulmonary surfactant. The primary purpose of pulmonary surfactant is to reduce the surface tension of the air/liquid interface allowing breathing with minimal effort required. We investigated the effect of addition of cholesterol and amyloid-β peptide on structure and function of Bovine Lung Extract Surfactant (BLES) and model lipid films. In our first experiment, we have demonstrated the effect of amyloid-β and cholesterol on lipid films of DPPC, DPPC-DOPG and BLES. We saw that cholesterol inhibits multilayer formation in all monolayers. Amyloid-β increases multilayer formation in DPPC and DPPC-DOPG, but reduced multilayer formation in BLES. When cholesterol and amyloid-β is added to BLES, 1% amyloid-β is inconsequential, whereas 10% amyloid-β allows BLES to regain some of its surfactant function. In our second experiment, we observed that for bothanionic DOPG and cationic DOTAP films which are in the fluid phase, amyloid-β interacts with the bilayer much quicker than in zwitterionic DPPC which is in the gel phase. Approaching 24 hours, we see small fibrils form on the bilayer, but these fibrils are considerably smaller than those formed when amyloid-β is incubated in solution. For fluid phase bilayer membrane, disruption is also observed. We investigated the effect of addition of cholesterol and amyloid-β peptide on structure and function of Bovine Lung Extract Surfactant (pulmonary surfactant BLES) and model lipid films. In our first experiment, we have demonstrated the effect of amyloid-β and cholesterol on lipid films of DPPC, DPPC-DOPG and BLES. We saw that cholesterol inhibits multilayer formation in all monolayers. Amyloid-β increases multilayer formation in DPPC and DPPC-DOPG, but reduced multilayer formation in BLES. When cholesterol and amyloid-β is added to BLES, 1% amyloid-β is in consequential, whereas 10% amyloid-β allows BLES to regain some of its surfactant function. In our second experiment, we observed that in anionic DOPG films, amyloid-β inserts into the bilayer much quicker than in zwitterionic DPPC. Approaching 24 hours, we see small fibrils form in the bilayer, but these fibrils are considerably smaller than those formed when amyloid-β is incubated in solution.

Amyloid

Pulmonary Surfactant

Lung Surfactant

Amyloidosis

Biology

The Structure and Function of Lung Surfactant: Effect of Amyloid Fibril Formation

Hane, Francis

08 May 2009

The alveoli of mammalian lungs are covered in a thin lipid film referred to as pulmonary surfactant. The primary purpose of pulmonary surfactant is to reduce the surface tension of the air/liquid interface allowing breathing with minimal effort required. We investigated the effect of addition of cholesterol and amyloid-β peptide on structure and function of Bovine Lung Extract Surfactant (BLES) and model lipid films. In our first experiment, we have demonstrated the effect of amyloid-β and cholesterol on lipid films of DPPC, DPPC-DOPG and BLES. We saw that cholesterol inhibits multilayer formation in all monolayers. Amyloid-β increases multilayer formation in DPPC and DPPC-DOPG, but reduced multilayer formation in BLES. When cholesterol and amyloid-β is added to BLES, 1% amyloid-β is inconsequential, whereas 10% amyloid-β allows BLES to regain some of its surfactant function. In our second experiment, we observed that for bothanionic DOPG and cationic DOTAP films which are in the fluid phase, amyloid-β interacts with the bilayer much quicker than in zwitterionic DPPC which is in the gel phase. Approaching 24 hours, we see small fibrils form on the bilayer, but these fibrils are considerably smaller than those formed when amyloid-β is incubated in solution. For fluid phase bilayer membrane, disruption is also observed. We investigated the effect of addition of cholesterol and amyloid-β peptide on structure and function of Bovine Lung Extract Surfactant (pulmonary surfactant BLES) and model lipid films. In our first experiment, we have demonstrated the effect of amyloid-β and cholesterol on lipid films of DPPC, DPPC-DOPG and BLES. We saw that cholesterol inhibits multilayer formation in all monolayers. Amyloid-β increases multilayer formation in DPPC and DPPC-DOPG, but reduced multilayer formation in BLES. When cholesterol and amyloid-β is added to BLES, 1% amyloid-β is in consequential, whereas 10% amyloid-β allows BLES to regain some of its surfactant function. In our second experiment, we observed that in anionic DOPG films, amyloid-β inserts into the bilayer much quicker than in zwitterionic DPPC. Approaching 24 hours, we see small fibrils form in the bilayer, but these fibrils are considerably smaller than those formed when amyloid-β is incubated in solution.

Amyloid

Pulmonary Surfactant

Lung Surfactant

Amyloidosis

Biology