Literature DB >> 18632313

The biophysical function of pulmonary surfactant.

Sandra Rugonyi1, Samares C Biswas, Stephen B Hall.   

Abstract

Pulmonary surfactant lowers surface tension in the lungs. Physiological studies indicate two key aspects of this function: that the surfactant film forms rapidly; and that when compressed by the shrinking alveolar area during exhalation, the film reduces surface tension to very low values. These observations suggest that surfactant vesicles adsorb quickly, and that during compression, the adsorbed film resists the tendency to collapse from the interface to form a 3D bulk phase. Available evidence suggests that adsorption occurs by way of a rate-limiting structure that bridges the gap between the vesicle and the interface, and that the adsorbed film avoids collapse by undergoing a process of solidification. Current models, although incomplete, suggest mechanisms that would partially explain both rapid adsorption and resistance to collapse as well as how different constituents of pulmonary surfactant might affect its behavior.

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Year:  2008        PMID: 18632313      PMCID: PMC2669693          DOI: 10.1016/j.resp.2008.05.018

Source DB:  PubMed          Journal:  Respir Physiol Neurobiol        ISSN: 1569-9048            Impact factor:   1.931


  101 in total

1.  Rapid compression transforms interfacial monolayers of pulmonary surfactant.

Authors:  J M Crane; S B Hall
Journal:  Biophys J       Date:  2001-04       Impact factor: 4.033

2.  Tracing surfactant transformation from cellular release to insertion into an air-liquid interface.

Authors:  T Haller; P Dietl; H Stockner; M Frick; N Mair; I Tinhofer; A Ritsch; G Enhorning; G Putz
Journal:  Am J Physiol Lung Cell Mol Physiol       Date:  2004-01-02       Impact factor: 5.464

3.  Metastability of a supercompressed fluid monolayer.

Authors:  Ethan C Smith; Jonathan M Crane; Ted G Laderas; Stephen B Hall
Journal:  Biophys J       Date:  2003-11       Impact factor: 4.033

4.  Transformation diagrams for the collapse of a phospholipid monolayer.

Authors:  Sandra Rugonyi; Ethan C Smith; Stephen B Hall
Journal:  Langmuir       Date:  2004-11-09       Impact factor: 3.882

Review 5.  How proteins produce cellular membrane curvature.

Authors:  Joshua Zimmerberg; Michael M Kozlov
Journal:  Nat Rev Mol Cell Biol       Date:  2006-01       Impact factor: 94.444

6.  Surface active materials from dog lung. 3. Thermal analysis.

Authors:  R J King; J A Clements
Journal:  Am J Physiol       Date:  1972-09

7.  Determination of alveolar surface area and tension from in situ pressure-volume data.

Authors:  M J Fisher; M F Wilson; K C Weber
Journal:  Respir Physiol       Date:  1970-09

8.  Temperature and surface forces in excised rabbit lungs.

Authors:  H Inoue; C Inoue; J Hildebrandt
Journal:  J Appl Physiol Respir Environ Exerc Physiol       Date:  1981-10

9.  Relations among recoil pressure, surface area, and surface tension in the lung.

Authors:  T A Wilson
Journal:  J Appl Physiol Respir Environ Exerc Physiol       Date:  1981-05

10.  Differential activity and lack of synergy of lung surfactant proteins SP-B and SP-C in interactions with phospholipids.

Authors:  Z Wang; O Gurel; J E Baatz; R H Notter
Journal:  J Lipid Res       Date:  1996-08       Impact factor: 5.922
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  29 in total

1.  Direct simulation of protein-mediated vesicle fusion: lung surfactant protein B.

Authors:  Svetlana Baoukina; D Peter Tieleman
Journal:  Biophys J       Date:  2010-10-06       Impact factor: 4.033

2.  Hydrophobic surfactant proteins induce a phosphatidylethanolamine to form cubic phases.

Authors:  Mariya Chavarha; Hamed Khoojinian; Leonard E Schulwitz; Samares C Biswas; Shankar B Rananavare; Stephen B Hall
Journal:  Biophys J       Date:  2010-04-21       Impact factor: 4.033

3.  Influence of liquid-layer thickness on pulmonary surfactant spreading and collapse.

Authors:  Trina A Siebert; Sandra Rugonyi
Journal:  Biophys J       Date:  2008-08-01       Impact factor: 4.033

4.  Hydrophobic surfactant proteins strongly induce negative curvature.

Authors:  Mariya Chavarha; Ryan W Loney; Shankar B Rananavare; Stephen B Hall
Journal:  Biophys J       Date:  2015-07-07       Impact factor: 4.033

Review 5.  Liquid and surfactant delivery into pulmonary airways.

Authors:  David Halpern; Hideki Fujioka; Shuichi Takayama; James B Grotberg
Journal:  Respir Physiol Neurobiol       Date:  2008-05-23       Impact factor: 1.931

Review 6.  Structure-function correlations of pulmonary surfactant protein SP-B and the saposin-like family of proteins.

Authors:  Bárbara Olmeda; Begoña García-Álvarez; Jesús Pérez-Gil
Journal:  Eur Biophys J       Date:  2012-09-21       Impact factor: 1.733

7.  Size influences the effect of hydrophobic nanoparticles on lung surfactant model systems.

Authors:  Mridula V Dwivedi; Rakesh Kumar Harishchandra; Olga Koshkina; Michael Maskos; Hans-Joachim Galla
Journal:  Biophys J       Date:  2014-01-07       Impact factor: 4.033

8.  Tear lipids interfacial rheology: effect of lysozyme and lens care solutions.

Authors:  Tatyana F Svitova; Meng C Lin
Journal:  Optom Vis Sci       Date:  2010-01       Impact factor: 1.973

9.  Effects of the lung surfactant protein B construct Mini-B on lipid bilayer order and topography.

Authors:  Dharamaraju Palleboina; Alan J Waring; Robert H Notter; Valerie Booth; Michael Morrow
Journal:  Eur Biophys J       Date:  2012-08-19       Impact factor: 1.733

10.  An anionic phospholipid enables the hydrophobic surfactant proteins to alter spontaneous curvature.

Authors:  Mariya Chavarha; Ryan W Loney; Shankar B Rananavare; Stephen B Hall
Journal:  Biophys J       Date:  2013-02-05       Impact factor: 4.033
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