Neutral Lipids Induce Critical Behavior in Interfacial Monolayers of Pulmonary Surfactant

Discher, Bohdana M.; Maloney, Kevin M.; Grainger, David W.; Sousa, Carolyn A.; Hall, Stephen B.

doi:10.1021/bi981386h

Cited by 74 publications

(110 citation statements)

References 40 publications

(65 reference statements)

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“…During compression of CLSE films, the l o phase appears at a π approximately 10 mN/m above the LE-TC transition for DPPC. 47 The l o -l d coexistence region for CLSE, with its multiple components, also extends over a much broader range of π than for DPPC. 49 Consequently, at 37 °C, where the main transition for DPPC begins at ~35 mN/m, the l o phase in CLSE appears just before the onset of collapse.…”

Section: Discussionmentioning

confidence: 98%

Distribution of Coexisting Solid and Fluid Phases Alters the Kinetics of Collapse from Phospholipid Monolayers

Yan

Hall

2006

J. Phys. Chem. B

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To determine how coexistence of liquid-expanded (LE) and tilted-condensed (TC) phases in phospholipid monolayers affects collapse from the air/water interface, we studied binary films containing dioleoyl phosphatidylcholine-dipalmitoyl phosphatidylcholine (DPPC) mixtures between 10 and 100% DPPC. Previously published results established that this range of compositions represents the LE-TC coexistence region at the equilibrium spreading pressure of 47 mN/m. When held at 49.5 mN/m on a captive bubble, the extent of total collapse fit with the LE area predicted by the phase diagram. The kinetics of collapse, however, when normalized for changes in the LE area, slowed with increasing mole fraction of DPPC. Surface area expressed as stretched exponential functions of time yielded an Avrami exponent that decreased from 1 for the homogeneously LE film to 0.3 for DPPC ≥ 70%. Microscopic studies showed that the largest changes in kinetics occurred when either alterations of the initial composition or the process of collapse induced the films to cross the percolation threshold, so that the LE phase became divided into isolated domains. Our results show that although coexisting solid and fluid phases collapse to extents that are independent, the kinetics of collapse, corrected for differences in LE area, depend on the distribution of the two phases.

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Section: Discussionmentioning

confidence: 98%

Distribution of Coexisting Solid and Fluid Phases Alters the Kinetics of Collapse from Phospholipid Monolayers

Yan

Hall

2006

J. Phys. Chem. B

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“…However, cholesterol is well recognized as a component that provides mechanical stability to cell membranes [48] and an important structural element to modulate their lateral structure, including segregation of specialized domains such as lipid rafts [49,50]. Recent results have shown that physiological proportions of cholesterol modulate the lateral organization and distribution of proteins and lipids in pulmonary surfactant membranes [51] and films [52,53], as well as the dynamical behaviour of surfactant films subjected to compression-expansion cycling [54]. Presence of cholesterol could be particularly important to permit surfactant films to reach and sustain the lowest surface tensions at 100% humidity [55], a condition thought to exist in the alveolar spaces but poorly reproduced in in vitro models.…”

mentioning

confidence: 99%

Synthetic Pulmonary Surfactant Preparations: New Developments and Future Trends

Mingarro¹,

Lukovic²,

Vilar³

et al. 2008

CMC

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Pulmonary surfactant is a lipid-protein complex that coats the interior of the alveoli and enables the lungs to function properly. Upon its synthesis, lung surfactant adsorbs at the interface between the air and the hypophase, a capillary aqueous layer covering the alveoli. By lowering and modulating surface tension during breathing, lung surfactant reduces respiratory work of expansion, and stabilises alveoli against collapse during expiration.Pulmonary surfactant deficiency, or dysfunction, contributes to several respiratory pathologies, such as infant respiratory distress syndrome (IRDS) in premature neonates, and acute respiratory distress syndrome (ARDS) in children and adults. The main clinical exogenous surfactants currently in use to treat some of these pathologies are essentially organic extracts obtained from animal lungs. Although very efficient, natural surfactants bear serious defects: i) they could vary in composition from batch to batch; ii) their production involves relatively high costs, and sources are limited; and iii) they carry a potential risk of transmission of animal infectious agents and the possibility of immunological reaction. All these caveats justify the necessity for a highly controlled synthetic material.In the present review the efforts aimed at new surfactant development, including the modification of existing exogenous surfactants by adding molecules that can enhance their activity, and the progress achieved in the production of completely new preparations, are discussed. Pulmonary surfactant function and dysfunctionThe respiratory surface of lungs constitutes the largest area of the human body exposed to the environment. Efficient gas exchange requires a large enough surface to be continuously exposed to air while minimising the barriers for oxygen and carbon dioxide to diffuse between air and the blood compartment [1]. At the same time, a selection of combined defence mechanisms is required to help keep such an essentially exposed area sterile of potential pathogenic microorganisms. Pulmonary surfactant, a lipid-protein complex produced by the alveolar epithelium of lungs, has been optimised to coordinate two main activities through natural evolution. On the one hand, it stabilises the respiratory surface against physical forces, therefore minimising the work required to maintain the large respiratory surface open to air [2][3][4]. On the other hand, pulmonary surfactant contains elements responsible for establishing a primary innate antipathogenic barrier, essential to ensure an intrinsically low pathogen load in the absence of induced defence mechanisms [5]. Extensive research in the last few decades has revealed some of the molecular mechanisms involved in pulmonary surfactant action. However, the manner in which both the biophysical and defence activities are intermingled and coordinately modulated in the alveolar spaces is now only beginning to be envisioned.Pulmonary surfactant is composed of approximately 90% lipids and 8-10% proteins, although only around 5% ...

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“…Phase coexistence at σ e in calf lung surfactant extract (CLSE) can be minimal or nonexistent. During compression at 20°C, initial separation of two phases terminates before reaching σ e (34). Remixing immediately follows dramatic changes in the shape of the ordered domains and in the extent of the interfacial boundary, consistent with behavior caused by low line tension between two immiscible fluid phases close to a critical point.…”

Section: The Classical Modelmentioning

confidence: 54%

“…Remixing immediately follows dramatic changes in the shape of the ordered domains and in the extent of the interfacial boundary, consistent with behavior caused by low line tension between two immiscible fluid phases close to a critical point. This remixing requires the presence of cholesterol (34). Critical points between fluid phases are now well documented in monolayers containing mixtures of cholesterol and phospholipids (38).…”

Section: The Classical Modelmentioning

confidence: 99%

“…The multiple components also affect the progression of the transition as well as its onset. Although the Gibbs phase rule for a single component film confines coexistence to a single surface tension, the presence of multiple components releases these constraints, and completion of the transition for films that include the surfactant phospholipids requires compression through a broad range of surface tensions (33,34). Consequently at σ e and 37°C, the ordered phase in complete …”

Section: The Classical Modelmentioning

confidence: 99%

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Structure– Function Relationships of Hydrophobic Proteins SP-B and SP-C in Pulmonary Surfactant

́rez-Gil¹,

Cruz²,

Plasencia³

2005

Lung Surfactant Function and Disorder

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Neutral Lipids Induce Critical Behavior in Interfacial Monolayers of Pulmonary Surfactant

Cited by 74 publications

References 40 publications

Distribution of Coexisting Solid and Fluid Phases Alters the Kinetics of Collapse from Phospholipid Monolayers

Distribution of Coexisting Solid and Fluid Phases Alters the Kinetics of Collapse from Phospholipid Monolayers

Synthetic Pulmonary Surfactant Preparations: New Developments and Future Trends

Structure– Function Relationships of Hydrophobic Proteins SP-B and SP-C in Pulmonary Surfactant

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