Development of corticosteroid liposomes for delivery to airway macrophages

Maas, Janet Catherine

January 1996

No description available.

572

Asthma; Lung surfactant

THE INTERACTION BETWEEN CHOLESTEROL AND SURFACTANT PROTEIN-C IN LUNG SURFACTANT

Gómez Gil, Leticia

07 July 2009

The presence of cholesterol is critical in defining a dynamic lateral structure in pulmonary surfactant membranes, including the segregation of fluid-ordered and fluid-disordered phases. However, an excess of cholesterol has been associated with impaired surface activity both in surfactant models and in surfactant from injured lungs. It has also been reported that surfactant protein SP-C interacts with cholesterol in lipid/protein interfacial films. In the present study, we have analyzed the effect of SP-C on the thermodynamic properties of phospholipid membranes containing cholesterol and on the ability of lipid/protein complexes containing surfactant proteins and cholesterol to form and re-spread interfacial films capable of producing very low surface tensions upon repetitive compression-expansion cycling. We have also analyzed the effect of cholesterol on the structure, orientation and dynamic properties of SP-C embedded in physiologically relevant model membranes.

cholesterol

Lung surfactant

SP-C

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

Involvement of innate immune humoral factors, CFHR5 and SP-D, in glioblastoma multiforme

De Cordova, Syreeta

January 2017

Glioblastoma Multiforme (GBM) is an extremely aggressive grade IV brain tumour that is highly infiltrative and can spread to other parts of the brain quickly. It is the most common primary brain tumour where patients have a median survival of 14.6 months. Symptoms vary depending upon the location of the tumour and include seizures, progressive headaches and focal neurological deficit. The poor prognosis is characterised by deregulation of many key signalling pathways involving survival, growth, apoptosis and evasion of immune surveillance. In this study, we investigated whether complement factor H related protein 5 (CFHR5) from primary GBM cells direct from patients exhibited functional activity similar to factor H. The presence of CFHR5 was validated by western blot and ELISA technique from B30, B31 and B33 primary GBM cells. The functional capacity of CFHR5 was examined through the alternative pathway, co-factor, and decay acceleration assay. We demonstrated that CFHR5 was able to inhibit the alternative pathway through the same mechanism as factor H. Emerging evidence had shown that the innate immune protein surfactant protein D (SP-D) and recombinant human SP-D (rhSP-D) were able to induce apoptosis in eosinophilic leukaemic cells. We studied the ability of rhSP-D to induce apoptosis in U87 GBM cells through apoptotic and viability assays. rhSP-D was unable to mediate cell death and instead increased cell viability. This led us to investigate the expression of SP-D in U87 and B30 GBM cells through western blot, ELISA and immuno-fluorescence detection. We demonstrated novel information about the production of SP-D by GBM cells. To extend our study, we investigated the interaction of THP-1 macrophage with rhSP-D bound U87 cells. We carried out live cell imaging, RT-qPCR, and cell viability assays, to study the changes in cytokine expression and viability of cells. THP-1 did not engulf U87 cells; however, it did reduce the number of cells and decrease the expression of pro-tumourigenic cytokines. This study highlights the ability of primary GBM cells to evade innate immune detection by the secretion of functionally active CFHR5. It also demonstrated the ability of U87 to evade destruction by rhSP-D and THP-1 highlighting the extremely aggressive behaviour of the tumour and lack of new treatment to improve prognosis in over a decade.

Axisymmetric Drop Shape Analysis (ADSA) and Lung Surfactant

Saad, Sameh Mossaad Iskander

11 January 2012

The objective of this thesis was to further develop a methodology for surface tension measurement called Axisymmetric Drop Shape Analysisn(ADSA) and to adapt it to studies of lung surfactants, i.e. the material that coats and facilitates the functioning of the lungs of all mammals. The key property of a functioning lung surfactant is its surface tension, which can reach extremely low values. Such values are difficult to measure; but a certain configuration of ADSA, using a constrained sessile drop (ADSA--CSD), is capable of performing such measurements. Clinically, lung surfactant films can be altered from both sides, i.e. from the airspace as well as from the bulk liquid phase that carries the film. Therefore, being able to access the interface from both sides is important. Here, ADSA--CSD was redesigned to be used as a micro film balance allowing access to the interface from both gas- and liquid-side. This allows deposition from the gas side as well as complete exchange of the bulk liquid phase. The new design was used to study lung surfactant inhibition and inhibition reversal. A dynamic compression-relaxation model (CRM) was developed to describe the mechanical properties of lung surfactant films by investigating the response of surface tension to changes in surface area. The model evaluates the quality of lung surfactant preparations -- beyond the minimum surface tension value -- and calculates the film properties, i.e. elasticity, adsorption and relaxation, independent of the compression protocol. The accuracy of the surface tension measurement can depend on drop size. A detailed analysis of drop shapes and accuracy of measured surface tension values was performed using a shape parameter concept. Based on this analysis, the design of ADSA--CSD was optimized to facilitate more accurate measurements. The validity analysis was further extended to the more conventional pendant drop setup (ADSA--PD). An overall upgrade of both hardware and software of ADSA--CSD, together with extensive numerical work, is described and applied to facilitate a more efficient operation. Finally, it is noted that the ADSA--CSD setup developed here can be used for a wide range of colloid and surface chemical applications.

Surface Thermodynamics

Surface Tension

ADSA

Lung Surfactant

0548

0541

Axisymmetric Drop Shape Analysis (ADSA) and Lung Surfactant

Saad, Sameh Mossaad Iskander

11 January 2012

The objective of this thesis was to further develop a methodology for surface tension measurement called Axisymmetric Drop Shape Analysisn(ADSA) and to adapt it to studies of lung surfactants, i.e. the material that coats and facilitates the functioning of the lungs of all mammals. The key property of a functioning lung surfactant is its surface tension, which can reach extremely low values. Such values are difficult to measure; but a certain configuration of ADSA, using a constrained sessile drop (ADSA--CSD), is capable of performing such measurements. Clinically, lung surfactant films can be altered from both sides, i.e. from the airspace as well as from the bulk liquid phase that carries the film. Therefore, being able to access the interface from both sides is important. Here, ADSA--CSD was redesigned to be used as a micro film balance allowing access to the interface from both gas- and liquid-side. This allows deposition from the gas side as well as complete exchange of the bulk liquid phase. The new design was used to study lung surfactant inhibition and inhibition reversal. A dynamic compression-relaxation model (CRM) was developed to describe the mechanical properties of lung surfactant films by investigating the response of surface tension to changes in surface area. The model evaluates the quality of lung surfactant preparations -- beyond the minimum surface tension value -- and calculates the film properties, i.e. elasticity, adsorption and relaxation, independent of the compression protocol. The accuracy of the surface tension measurement can depend on drop size. A detailed analysis of drop shapes and accuracy of measured surface tension values was performed using a shape parameter concept. Based on this analysis, the design of ADSA--CSD was optimized to facilitate more accurate measurements. The validity analysis was further extended to the more conventional pendant drop setup (ADSA--PD). An overall upgrade of both hardware and software of ADSA--CSD, together with extensive numerical work, is described and applied to facilitate a more efficient operation. Finally, it is noted that the ADSA--CSD setup developed here can be used for a wide range of colloid and surface chemical applications.

Surface Thermodynamics

Surface Tension

ADSA

Lung Surfactant

0548

0541

[en] PHYSICAL-CHEMICAL STUDIES OF THE EFFECT OF ANTIBIOTIC INCORPORATION IN THE STRUCTURE AND MOLECULAR ORGANIZATION OF CLINICAL-GRADE LUNG SURFACTANT MONOLAYERS AND MEMBRANE MODELS AT THE AIR-WATER INTERFACE / [pt] ESTUDOS FÍSICO-QUÍMICOS SOBRE O EFEITO DA INCORPORAÇÃO DE ANTIBIÓTICOS NA ESTRUTURA E ORGANIZAÇÃO MOLECULAR DE MONOCAMADAS DE SURFACTANTE PULMONAR DE GRAU CLÍNICO E EM MODELOS DE MEMBRANA NA INTERFACE AR-ÁGUA

STEPHANIE ORTIZ COLLAZOS

15 February 2019

[pt] O surfactante pulmonar é um sistema lipo-proteico que atua na interface alveolar com vital importância para manter funcional a mecânica respiratória. Os comprometimentos na sua função estão associados a diversas infecções pulmonares. Os sistemas de administração de fármacos baseados em surfactantes pulmonares derivados de animais são complexos, dificultando a compreensão do papel individual das moléculas hóspedes nas suas interações com a membrana. Aqui apresentamos uma caracterização de um extrato surfactante de pulmão porcino de grau clínico misturado com os antibióticos Levofloxacina e Claritromicina, usando uma abordagem multi-técnica – em conjunto com a metodologia de monocamadas de Langmuir– consistindo de isotermas de pressão de superfície-area, microscopia de ângulo de Brewster (BAM), espectroscopia de reflexão-absorção do infravermelho com modulação da polarização (PM-IRRAS), reflectometria de nêutrons (NR), ensaios in vitro e simulações de dinâmica molecular. Avaliou-se o efeito de ambos os antibióticos na estrutura das monocamadas de surfactantes de origem porcino bem como em monocamadas de DPPC. Foi revelado que a estabilidade / integridade das monocamadas é preservada na presença de ambas as drogas. Os sistemas mistos de antibiótico / surfactante pulmonar aumentam a atividade antibacteriana contra bactérias Gram-positivas (Bacillus cereus) e Gram-negativas (Escherichia coli). Essas descobertas fornecem novas percepções sobre a otimização de sistemas eficientes de administração de medicamentos para o tratamento de condições patológicas no nível respiratório. / [en] The lipo-proteic surfactant system acting at the alveolar interface is of vital importance for keeping functional the respiratory mechanics. Its impairments are associated with several pulmonary infections. Drug delivery systems based on animal-derived lung surfactants are complex making it difficult to understand the individual role of guest molecules in membrane interactions. Here we present a characterization of a clinical-grade porcine lung surfactant extract mixed with the antibiotics Levofloxacin and Clarithromycin, using a multi-technique approach –in conjunction with the Langmuir-monolayer methodology– consisting of surface pressure-area isotherms, Brewster angle microscopy (BAM), polarization modulation-infrared reflection-adsorption spectroscopy (PM-IRRAS), neutron reflectometry (NR), in vitro assays, and molecular dynamics simulations. The effect of both antibiotics in the structure of porcine lung surfactant monolayers as well as in DPPC monolayers was examined. It was revealed that the stability/integrity of the monolayers is preserved in the presence of both drugs. The mixed antibiotic/lung surfactant systems enhance the antibacterial activity against Gram-positive (Bacillus cereus) and Gram-negative (Escherichia coli) bacteria. These findings provide new insights into the optimization of efficient drug delivery systems for the treatment of pathological conditions at the respiratory level.

[pt] SURFACTANTE PULMONAR

[en] LUNG SURFACTANT

[pt] CUROSURF

[en] CUROSURF

[pt] LEVOFLOXACINA

[en] LEVOFLOXACIN

[pt] CLARITROMICINA

[en] CLARITHROMYCIN

Molecular insights on the interference of simplified lung surfactant models by gold nanoparticle pollutants

Hossain, S.I., Gandhi, N.S., Hughes, Zak E., Gu, Y.T., Saha, S.C.

01 July 2019

Yes / Inhaled nanoparticles (NPs) are experienced by the first biological barrier inside the alveolus known as lung surfactant (LS), a surface tension reducing agent, consisting of phospholipids and proteins in the form of the monolayer at the air-water interface. The monolayer surface tension is continuously regulated by the alveolus compression and expansion and protects the alveoli from collapsing. Inhaled NPs can reach deep into the lungs and interfere with the biophysical properties of the lung components. The interaction mechanisms of bare gold nanoparticles (AuNPs) with the LS monolayer and the consequences of the interactions on lung function are not well understood. Coarse-grained molecular dynamics simulations were carried out to elucidate the interactions of AuNPs with simplified LS monolayers at the nanoscale. It was observed that the interactions of AuNPs and LS components deform the monolayer structure, change the biophysical properties of LS and create pores in the monolayer, which all interfere with the normal lungs function. The results also indicate that AuNP concentrations >0.1 mol% (of AuNPs/lipids) hinder the lowering of the LS surface tension, a prerequisite of the normal breathing process. Overall, these findings could help to identify the possible consequences of airborne NPs inhalation and their contribution to the potential development of various lung diseases. / University of Technology Sydney (UTS) FEIT Research Scholarship, UTS IRS (S.I.H.), 2018 Blue Sky scheme–Suvash Saha (Activity 2232368), N.S.G is supported by the Vice-Chancellor fellowship funded by QUT.

Lung surfactant

Gold nanoparticles

Surface tension

Coarse-grained molecular dynamics

Lipid monolayers

The role of SP-B1-25 peptides in lung surfactant monolayers exposed to gold nanoparticles

Hossain, S.I., Gandhi, N.S., Hughes, Zak E., Saha, S.C.

29 June 2020

Yes / Lung surfactant (LS) monolayers that continuously expand and compress during breathing cycles, act as the first line barrier for inhaled nanoparticles. It is known that nanoparticles which adsorb to the surface of the surfactant layer facilitate the rearrangement of lipids and peptides at various stages of the breathing cycle. However, the structural mechanisms for this ability of the lipid rearrangement are not yet fully understood. Coarse-grained molecular dynamics simulations are performed to investigate the role of surfactant protein B (SP-B) segments (SP-B1–25) in modulating the biophysical properties of the surfactant monolayer in the presence of polydisperse gold nanoparticles (AuNPs) at different concentrations. Herein, we observe that the AuNPs significantly alter the inherent structural and dynamical properties of the monolayer and its components in three different breathing states. When adsorbed into the monolayer, the AuNPs inhibit the ability of the monolayer to recover its surface tension and other properties. The presence of SP-B1–25 in the monolayer accelerates the diffusion of the monolayer phospholipids, contrarily to the role of AuNPs on phospholipid diffusion. Also, the AuNPs and the peptides in the monolayer significantly increase their agglomeration in the presence of one another. Overall, the simulations predict that the presence of polydisperse AuNPs hampers the stability and biophysical functions of the LS in contrast to the role of the peptide. This study provides a clear view of the hydrophobic peptide role in the LS monolayer at the interface along with the interactions and the translocation of AuNPs that could have a significant impact to assess the NPs inhalation. / This work was completed with the support of University of Technology Sydney (UTS) FEIT Research Scholarship, UTS IRS (S. I. H.).

Lung surfactant (LS) monolayers

Nanoparticles

SP-B1-25 peptides

Breathing cycles

Gold nanoparticles (AuNPs)