scholarly article | Q13442814 |
P2093 | author name string | Ran Arieli | |
P2860 | cites work | On the use of a bubble formation model to calculate diving tables | Q28307716 |
Nucleation processes of nanobubbles at a solid/water interface | Q28834584 | ||
Skins of varying permeability: A stabilization mechanism for gas cavitation nuclei | Q29029881 | ||
Intramembrane cavitation as a unifying mechanism for ultrasound-induced bioeffects | Q30474477 | ||
Effects of degassing on the long-range attractive force between hydrophobic surfaces in water | Q33218034 | ||
A physiological model of the release of gas bubbles from crevices under decompression. | Q33434336 | ||
Evidence for gas nuclei in decompressed rats. | Q33483503 | ||
An alternative view of the role(s) of surfactant and the alveolar model | Q33774147 | ||
The incidence of venous gas emboli in recreational diving. | Q33966468 | ||
The endothelial surface layer. | Q34046782 | ||
Microparticle production, neutrophil activation, and intravascular bubbles following open-water SCUBA diving | Q34253455 | ||
Reduced gradient bubble model | Q34286443 | ||
Influence of repeated daily diving on decompression stress | Q34351257 | ||
A hydrophobic oligolamellar lining to the vascular lumen in some organs | Q34379390 | ||
Air bubble contact with endothelial cells causes a calcium-independent loss in mitochondrial membrane potential | Q34455190 | ||
Evolution of bubbles from gas micronuclei formed on the luminal aspect of ovine large blood vessels | Q34691606 | ||
Bubble size on detachment from the luminal aspect of ovine large blood vessels after decompression: The effect of mechanical disturbance | Q35640170 | ||
Air bubble contact with endothelial cells in vitro induces calcium influx and IP3-dependent release of calcium stores | Q35741077 | ||
Expansion of bubbles under a pulsatile flow regime in decompressed ovine blood vessels | Q35848087 | ||
Bubble-Induced Endothelial Microparticles Promote Endothelial Dysfunction | Q36257626 | ||
Haemodynamic changes induced by submaximal exercise before a dive and its consequences on bubble formation | Q36768112 | ||
Correlation between Patent Foramen Ovale, Cerebral "Lesions" and Neuropsychometric Testing in Experienced Sports Divers: Does Diving Damage the Brain? | Q36889685 | ||
Endothelial dysfunction correlates with decompression bubbles in rats | Q37247864 | ||
Effect of decompression-induced bubble formation on highly trained divers microvascular function | Q37411062 | ||
Endothelia-Targeting Protection by Escin in Decompression Sickness Rats | Q37599468 | ||
Time Course of Endothelial Dysfunction Induced by Decompression Bubbles in Rats | Q37716802 | ||
Was the appearance of surfactants in air breathing vertebrates ultimately the cause of decompression sickness and autoimmune disease? | Q38281021 | ||
Decompression models: review, relevance and validation capabilities | Q38308842 | ||
Intrapulmonary shunt and SCUBA diving: another risk factor? | Q38360654 | ||
A biophysical vascular bubble model for devising decompression procedures | Q38892450 | ||
Flying after diving: should recommendations be reviewed? In-flight echocardiographic study in bubble-prone and bubble-resistant divers | Q38947319 | ||
Preconditioning to Reduce Decompression Stress in Scuba Divers | Q39016396 | ||
Association of microparticles and neutrophil activation with decompression sickness. | Q40772138 | ||
Pre-dive Whole-Body Vibration Better Reduces Decompression-Induced Vascular Gas Emboli than Oxygenation or a Combination of Both. | Q42362009 | ||
Microparticle enlargement and altered surface proteins after air decompression are associated with inflammatory vascular injuries | Q42622343 | ||
Gender differences in circulating bubble production after SCUBA diving | Q42627462 | ||
Doppler bubble grades after diving and relevance of body fat. | Q42672884 | ||
Endothelial function and stress response after simulated dives to 18 msw breathing air or oxygen | Q43199438 | ||
Nitrogen dioxide solubility and permeation in lipid membranes. | Q43767499 | ||
Diving decompression models and bubble metrics: modern computer syntheses. | Q45960686 | ||
Effects of dissolved gas on the hydrophobic attraction between surfactant-coated surfaces. | Q46020232 | ||
Spontaneous formation of bubbles in gas-supersaturated water | Q46199170 | ||
Antioxidant pretreatment and reduced arterial endothelial dysfunction after diving. | Q46861948 | ||
Ex vivo bubble production from ovine large blood vessels: size on detachment and evidence of "active spots". | Q47580738 | ||
Mechanisms underlying spinal cord damage in decompression sickness | Q48466227 | ||
Risk factors for venous gas emboli after decompression from prolonged hyperbaric exposures. | Q48593755 | ||
The vertebral venous plexuses: the internal veins are muscular and external veins have valves. | Q51405668 | ||
Free energy wells for small gas bubbles in soft deformable materials. | Q51700297 | ||
Human dose-response relationship for decompression and endogenous bubble formation. | Q51727711 | ||
Generalizations of the Young-Laplace equation for the pressure of a mechanically stable gas bubble in a soft elastic material. | Q51775073 | ||
Microparticles initiate decompression-induced neutrophil activation and subsequent vascular injuries | Q53779704 | ||
Formation of surface nanobubbles and the universality of their contact angles: a molecular dynamics approach. | Q53815715 | ||
Bubble formation in supersaturated gelatin: A further investigation of gas cavitation nuclei | Q56864615 | ||
Knudsen Gas Provides Nanobubble Stability | Q56990543 | ||
Combined effect of denucleation and denitrogenation on the risk of decompression sickness in rats | Q57102804 | ||
Pre-Dive Vibration Effect on Bubble Formation After a 30-m Dive Requiring a Decompression Stop | Q58757540 | ||
Predive Sauna and Venous Gas Bubbles Upon Decompression from 400 kPa | Q58757561 | ||
Significance of Gas Micronuclei in the Aetiology of Decompression Sickness | Q58961308 | ||
Bubble Formation and Endothelial Function Before and After 3 Months of Dive Training | Q59007855 | ||
Modeling the observations of in vivo bubble formation with hydrophobic crevices | Q69558867 | ||
Ascent rate, age, maximal oxygen uptake, adiposity, and circulating venous bubbles after diving | Q74795943 | ||
Images of nanobubbles on hydrophobic surfaces and their interactions | Q77108672 | ||
Endothelial damage by bubbles in the pulmonary artery of the pig | Q77826573 | ||
Characterization of nanobubbles on hydrophobic surfaces in water | Q80339233 | ||
Dynamic equilibrium mechanism for surface nanobubble stabilization | Q83113903 | ||
Gas bubbles may not be the underlying cause of decompression illness - The at-depth endothelial dysfunction hypothesis | Q83156990 | ||
Pre-dive normobaric oxygen reduces bubble formation in scuba divers | Q83357199 | ||
Decompression sickness bubbles: are gas micronuclei formed on a flat hydrophobic surface? | Q83536552 | ||
Comparative incidences of decompression illness in repetitive, staged, mixed-gas decompression diving: is 'dive fitness' an influencing factor? | Q84365192 | ||
Prognostic factors of spinal cord decompression sickness in recreational diving: retrospective and multicentric analysis of 279 cases | Q84794614 | ||
Dynamics of gas micronuclei formed on a flat hydrophobic surface, the predecessors of decompression bubbles | Q85711015 | ||
Intramicroparticle nitrogen dioxide is a bubble nucleation site leading to decompression-induced neutrophil activation and vascular injury | Q85778286 | ||
Why surface nanobubbles live for hours | Q86129593 | ||
Nonintrusive optical visualization of surface nanobubbles | Q87367241 | ||
Presence of dipalmitoylphosphatidylcholine from the lungs at the active hydrophobic spots in the vasculature where bubbles are formed on decompression | Q88110807 | ||
P304 | page(s) | 591 | |
P577 | publication date | 2017-08-15 | |
P1433 | published in | Frontiers in Physiology | Q2434141 |
P1476 | title | Nanobubbles Form at Active Hydrophobic Spots on the Luminal Aspect of Blood Vessels: Consequences for Decompression Illness in Diving and Possible Implications for Autoimmune Disease-An Overview | |
P478 | volume | 8 |
Q47127867 | A combined three-dimensional in vitro-in silico approach to modelling bubble dynamics in decompression sickness |
Q55250801 | Extravascular Hydrophobic Surfaces, Fat Droplets, and the Connection With Decompression Illness: Spinal, Joint Pain, and Dysbaric Osteonecrosis. |
Q92271559 | Gas micronuclei that underlie decompression bubbles and decompression sickness have not been identified |
Q93095446 | Gas micronuclei underlying decompression bubbles may explain the influence of oxygen enriched gases during decompression on bubble formation and endothelial function in self-contained underwater breathing apparatus diving |
Q92245631 | In vitro evidence of decompression bubble dynamics and gas exchange on the luminal aspect of blood vessels: Implications for size distribution of venous bubbles |
Q92238083 | Static Metabolic Bubbles as Precursors of Vascular Gas Emboli During Divers' Decompression: A Hypothesis Explaining Bubbling Variability |
Q91471244 | Structure and function of the endothelial surface layer: unraveling the nanoarchitecture of biological surfaces |
Search more.