A Biophysical Vascular Bubble Model for Devising Decompression Procedures

Overview

Journal Physiol Rep

Specialty Physiology

Date 2017 Mar 22

PMID 28320890

Citations 14

Authors

Ran Arieli

Abraham Marmur

Affiliations

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Abstract

Vascular bubble models, which present a realistic biophysical approach, hold great promise for devising suitable diver decompression procedures. Nanobubbles were found to nucleate on a flat hydrophobic surface, expanding to form bubbles after decompression. Such active hydrophobic spots (AHS) were formed from lung surfactants on the luminal aspect of ovine blood vessels. Many of the phenomena observed in these bubbling vessels correlated with those known to occur in diving. On the basis of our previous studies, which proposed a new model for the formation of arterial bubbles, we now suggest the biophysical model presented herein. There are two phases of bubble expansion after decompression. The first is an extended initiation phase, during which nanobubbles are transformed into gas micronuclei and begin to expand. The second, shorter phase is one of simple diffusion-driven growth, the inert gas tension in the blood remaining almost constant during bubble expansion. Detachment of the bubble occurs when its buoyancy exceeds the intermembrane force. Three mechanisms underlying the appearance of arterial bubbles should be considered: patent foramen ovale, intrapulmonary arteriovenous anastomoses, and the evolution of bubbles in the distal arteries with preference for the spinal cord. Other parameters that may be quantified include age, acclimation, distribution of bubble volume, AHS, individual sensitivity, and frequency of bubble formation. We believe that the vascular bubble model we propose adheres more closely to proven physiological processes. Its predictability may therefore be higher than other models, with appropriate adjustments for decompression illness (DCI) data.

Citing Articles

Taravana syndrome and posterior reversible encephalopathy syndrome: a microbubble hypothesis for neurological accidents in breath-hold divers.

Druelle A, Castagna O, Roffi R, Louge P, Faivre A, Blatteau J Front Physiol. 2024; 15:1478650.

PMID: 39381329 PMC: 11458415. DOI: 10.3389/fphys.2024.1478650.

Eccentric exercise 24 h prior to hypobaric decompression increases decompression strain.

Gottschalk F, Eiken O, Elia A, Gennser M Eur J Appl Physiol. 2023; 123(9):2001-2011.

PMID: 37140728 PMC: 10460726. DOI: 10.1007/s00421-023-05214-3.

The increased protein tau in blood after SCUBA diving can be related to distal arterial bubbles.

Arieli R Eur J Appl Physiol. 2022; 122(10):2315-2316.

PMID: 35752661 DOI: 10.1007/s00421-022-04993-5.

Reply: Diving-related disorders in breath-hold divers could be explained with the distal arterial bubble hypothesis.

Kohshi K Diving Hyperb Med. 2021; 51(4):383-384.

PMID: 34897606 PMC: 8920907. DOI: 10.28920/dhm51.4.383-384.

Arieli R Diving Hyperb Med. 2021; 51(4):382-383.

PMID: 34897605 PMC: 8920904. DOI: 10.28920/dhm51.4.382-383.

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