2025 March;55(1)
Diving Hyperb Med. 2025 31 March;55(1):2−10. doi: 10.28920/dhm55.1.2-10. PMID: 40090020.
Agreement of precordial and subclavian Doppler ultrasound venous gas emboli grades in a large diving data set
S Lesley Blogg1,2, Arian Azarang3, Virginie Papadopoulou3, Peter Lindholm2
1 SLB Consulting, Home Park Barn, Kirkby Stephen, Cumbria, United Kingdom
2 Department of Emergency Medicine, University of California at San Diego, California, USA
3 Department of Radiology, The University of North Carolina at Chapel Hill and North Carolina State University, North Carolina, USA
Corresponding author: Dr S Lesley Blogg, SLB Consulting, Home Park Barn, Kirkby Stephen, Cumbria, United Kingdom
ORCiD: 0000-0002-6006-2065
Keywords
Bubbles; Decompression; Decompression sickness; Diving research
Abstract
(Blogg SL, Azarang A, Papadopoulou V, Lindholm P. Agreement of precordial and subclavian Doppler ultrasound venous gas emboli grades in a large diving data set. Diving and Hyperbaric Medicine. 2025 31 March;55(1):2−10. doi: 10.28920/dhm55.1.2-10. PMID: 40090020.)
Introduction: Doppler ultrasound is used to detect inert gas bubbles in the body following decompression from dives. Two sites may be monitored, the precordial (PC) and subclavian (SC) positions. PC is the predominant site, allowing observation of bubbles returning from the entire body. However, the SC site provides unambiguous signals, whereas the PC site is noisy and difficult to grade. This retrospective study compared agreement of PC and SC Doppler data.
Methods: Datasets from the large University of California at San Diego Doppler database were graded on the Kisman Masurel (KM) scale and included: one PC measurement at rest followed by three during movement (n = 4 measurements); this was repeated for the left (n = 4 measurements) and right (n = 4 measurements) SC veins, producing a set of 12 grades. Primary analysis included: agreement between resting PC and SC grades, between movement PC and SC grades, and for unmatched grades, whether the SC grade was higher or lower than PC.
Results: Four-hundred and fifty-three datasets were available (5,436 individual recordings). At rest, 281 (62.0%) PC and SC grades matched (weighted kappa agreement 0.33, 95% CI ± 0.04), while only 176 (38.9%) movement grades matched (0.29, ± 0.02). Of the unmatched data, resting SC grades were higher than PC in 70.3% and lower in 29.6%; after movement, SC grades were higher in 45.8% and lower in 54.2%.
Conclusions: These data revealed a large discrepancy between PC and SC grades. Overall, this suggests that Doppler observations from both positions will give the most comprehensive representation of bubble load.
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Original article
Diving Hyperb Med. 2025 31 March;55(1):11−17. doi: 10.28920/dhm55.1.11-17. PMID: 40090021.
Longitudinal study of changes in pulmonary function among inside attendants of hyperbaric oxygen therapy
Kubra Canarslan Demir1, Ahmet Uğur Avci2, Selcen Yüsra Abayli1, Fatma Sena Konyalioglu3, Burak Turgut2
1 Department of Undersea and Hyperbaric Medicine, Gülhane Research and Training Hospital, Turkey
2 Department of Aerospace Medicine, Gülhane Research and Training Hospital, Turkey
3 Department of Monitoring and Evaluation, General Directorate of Health Promotion, Ministry of Health, Turkey
Corresponding author: Dr Kübra Canarslan Demir, SBÜ-Gülhane Eğitim ve Araştırma Hastanesi, Sualtı Hekimliği ve Hiperbarik Tıp Kliniği, Etlik/Ankara, Turkey
ORCiD: 0000-0001-6911-2375
Keywords
Hyperbaric oxygen treatment; Long-term effects; Nursing; Pulmonary function; Respiratory
Abstract
(Canarslan Demir K, Avci1 AU, Yüsra Abayli S, Konyalioglu FS, Turgut B. Longitudinal study of changes in pulmonary function among inside attendants of hyperbaric oxygen therapy. Diving and Hyperbaric Medicine. 2025 31 March;55(1):11−17. doi: 10.28920/dhm55.1.11-17. PMID: 40090021.)
Introduction: Hyperbaric oxygen therapy (HBOT) administers 100% oxygen in a pressurised chamber at pressures above 1 atmosphere absolute. Inside hyperbaric personnel accompany patients during sessions and breathe compressed air, exposing them to risks like decompression illness and respiratory changes. This study investigated whether hyperbaric exposure affects the long-term lung function of inside hyperbaric personnel.
Methods: An analysis was conducted on spirometry data from 14 personnel working between 2012 and 2023. Lung function tests measured forced vital capacity (FVC), forced expiratory volume in one second (FEV1), mid breath forced expiratory flow (FEF25–75), and peak expiratory flow (PEF) before and after hyperbaric exposure. Participants were categorised based on age, body mass index, number of HBOT sessions, and duration of employment.
Results: No clinically or statistically significant differences were found in FVC, FEV1, or PEF measurements before and after hyperbaric exposures (P > 0.05). However, FEF25–75, an indicator of small airway function, showed a (mean) 16% reduction in personnel with more than 150 HBOT sessions (P = 0.038). A post-hoc analysis confirmed a significant difference in FEF25–75 between personnel with fewer than 74 sessions and those with 150 or more sessions (P = 0.015). No clinically significant symptoms such as dyspnoea were reported during the study period.
Conclusions: The FEF25–75 reduction, without changes in FEV1, FVC, or PEF, could be due to improper performance of the FVC manoeuvre. Maintaining pulmonary health in inside hyperbaric personnel is essential, emphasising the importance of accurate FVC execution in assessments. Further studies are recommended to explore the long-term implications of these findings and the effects of repeated hyperbaric exposure on respiratory health.
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Original article
Diving and Hyperb Med. 2025 31 March;55(1):18−26. doi: 10.28920/dhm55.1.18-26. PMID: 40090022.
Divers with large or normal lungs: is the difference justified?
Pieter-Jan AM van Ooij1,2, Robert A van Hulst3
1 Diving Medical Centre, Royal Netherlands Navy, Den Helder, the Netherlands
2 Department of Respiratory Medicine, Amsterdam University Medical Centre (AUMC), University of Amsterdam, Amsterdam, the Netherlands
3 Department of Anesthesiology and Hyperbaric Medicine, Amsterdam University Medical Centre (AUMC), University of Amsterdam, Amsterdam, the Netherlands
Corresponding author: Dr Pieter-Jan van Ooij, Diving Medical Centre, Royal Netherlands Navy. PO Box 10,000 1781 ZX Den Helder, the Netherlands
ORCiD: 0000-0002-2108-320X
Keywords
Fitness to dive; Lung function; Medical conditions and problems; Military diving; Pulmonary barotrauma; Risk factors
Abstract
(van Ooij PJAM, van Hulst RA. Divers with large or normal lungs: is the difference justified? Diving and Hyperbaric Medicine. 2025 31 March;55(1):18−26. doi: 10.28920/dhm55.1.18-26. PMID: 40090022.)
Introduction: Measurements of forced vital capacity (FVC) have shown that divers have larger lungs than members of the general population. Bullae or decompression illness (DCI) secondary to pulmonary barotrauma is more likely to occur in large lungs (LLs) than in normal lungs (NLs). This study retrospectively compared lung function, high-resolution CT (HRCT) scan anomalies, the unfit-to-dive rate, and the prevalence of DCI in groups of divers with LLs and NLs.
Methods: The results of fitness examinations of divers with LLs (FVC z-score > 1.96) and NLs (FVC z-score ≤ 1.96) from 2011 to 2020 were retrospectively evaluated. Data were obtained from lung function tests, HRCT results, fitness examination outcomes, and whether the diver did or did not have DCI.
Results: The study included 1,069 divers, with 65 subjects, all male, fulfilling the requirements for LLs. Subjects with LLs had a significantly higher z-scores for FVC and FEV1 but a significantly lower FEV1/FVC ratio, than subjects with NLs. The rates of bullae, DCI, and unfit-to-dive did not differ significantly in the two groups.
Conclusions: Although FEV1/FVC ratio was significantly lower in the LL than in the NL group, there were no between-group differences in the rates of bullae and DCI. These findings suggest that subjects with LLs are not at a higher risk of bullae and DCI than are subjects with NLs.
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Original article
Diving and Hyperb Med. 2025 31 March;55(1):27−34. doi: 10.28920/dhm55.1.27-34. PMID: 40090023.
The influence of wetsuit thickness (≥ 7 mm) on lung volumes in scuba divers
Graham Stevens1, David R Smart2
1 Department of Diving and Hyperbaric Medicine, Royal Hobart Hospital, Hobart, Tasmania, Australia
2 Private Consultant. Formerly: Clinical Professor, School of Medicine, University of Tasmania and Department of Diving and Hyperbaric Medicine, Royal Hobart Hospital, Hobart, Tasmania, Australia
Corresponding author: Dr Graham Stevens, Department of Diving and Hyperbaric Medicine, Royal Hobart Hospital, Hobart, Tasmania 7000, Australia
ORCiD: 0009-0001-3341-108X
Keywords
Diving research; Equipment; Fitness to dive; Lung; Respiratory; Spirometry
Abstract
(Stevens G, Smart DR. The influence of wetsuit thickness (≥ 7 mm) on lung volumes in scuba divers. Diving and Hyperbaric Medicine. 2025 31 March;55(1):27−34. doi: 10.28920/dhm55.1.27-34. PMID: 40090023.)
Introduction: We hypothesised that although thicker (≥ 7 mm) wetsuits delay hypothermia and allow divers to dive in cooler waters, they may hinder pulmonary function. The aim of this study was to investigate whether thicker wetsuits worn by Tasmanian divers affected lung volumes, primarily the forced vital capacity (FVC) and forced expiratory volume, one second (FEV1).
Methods: Sixty-two volunteer active divers were recruited from recreational dive clubs and Tasmania’s occupational diving industry. After confirming fitness and that the divers were currently active, spirometry testing was performed with and without the divers’ usual wet suits, in a controlled dry environment. Suits were of varying thickness, but all were
≥ 7 mm thickness.
Results: All divers had significantly reduced lung volumes when wearing ≥ 7 mm wetsuits. Recreational divers had greater decrements (-7% FVC and -5% FEV1), compared to occupational divers (-3% FVC, -3% FEV1). Males’ lung volumes declined -4% FVC and -4 % FEV1, whereas females declined -7 % FVC and -6 % FEV1. Female recreational divers experienced the greatest negative impact from thicker wetsuits (up to 15% reduction in FVC), and this group also demonstrated an inverse relationship between increasing wetsuit thickness and declining lung volumes.
Conclusions: Wearing thicker wet suits aids in thermal protection in temperate water diving but this study suggests it has negative effects on lung volumes. The real-life impact of this negative effect may be minor in fit healthy divers but might add additional risk to a less fit, recreational diving population with medical comorbidities.
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Original article
Diving and Hyperb Med. 2025 31 March;55(1):35−43. doi: 10.28920/dhm55.1.35-43. PMID: 40090024.
Diving-related fatalities in Victoria, Australia, 2000 to 2022
John Lippmann1,2,3
1 Australasian Diving Safety Foundation, Canterbury, Victoria, Australia
2 Department of Public Health and Preventive Medicine, Monash University, Victoria, Australia
3 Royal Life Saving Society Australia, Sydney, Australia
Corresponding author: Dr John Lippmann, Australasian Diving Safety Foundation, PO Box 478, Canterbury, VIC 3126, Australia
Keywords
Diving deaths; Obesity; Scuba diving; Seafood collection; Snorkelling; Surface supplied breathing apparatus (SSBA)
Abstract
(Lippman J. Diving-related fatalities in Victoria, Australia, 2000 to 2022. Diving and Hyperbaric Medicine. 2025 31 March;55(1):35−43. doi: 10.28920/dhm55.1.35-43. PMID: 40090024.)
Introduction: The aim was to examine the diving-related fatalities in Victoria, Australia from 2000 to 2022, identify trends and assess existing and potential countermeasures.
Methods: The National Coronial Information System and the Australasian Diving Safety Foundation (ADSF) database were searched to identify compressed gas diving and snorkelling/breath-hold diving deaths in Victoria for 2000–2022, inclusive. Data were extracted and analysed, and chain of events analyses conducted.
Results: Thirty-six scuba divers, one diver using surface supplied breathing apparatus (SSBA) and 25 snorkellers/breath-hold divers were identified. Compressed gas divers were older than snorkellers (medians 47 vs 36 years) with a higher proportion being overweight or obese (89% vs 61%), half with pre-existing medical conditions which likely contributed to their deaths. Most snorkellers died from primary drowning, often associated with inexperience. Half of all victims were inexperienced, and more than half of the accidents occurred while diving for seafood, often in rough conditions. Only one third of victims were with a buddy at the time of their accident. Of those known to be wearing weights, three-quarters were still wearing them when found.
Conclusions: Diving medical assessment in divers aged 45 years or older needs to be strengthened and obesity should trigger medical assessment in older divers. Other identified risks included seafood collection, diving in adverse conditions, ineffective or no buddy system, overweighting, poor buoyancy control and failure to ditch weights. Many are longstanding problems, so relevant messages are still not penetrating the community. Constant reinforcement through formal training, internet forums and targeted educational campaigns is required.
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Original article
Diving and Hyperb Med. 2025 31 March;55(1):44−50. doi: 10.28920/dhm55.1.44-50. PMID: 40090025.
Venous gas emboli (VGE) in 2-D echocardiographic images following movement: grading and association with cumulative incidence of decompression sickness
Joshua B Currens1,2, David J Doolette1,3, F Gregory Murphy1
1 Navy Experimental Diving Unit, Panama City, Florida, USA
2 Department of Radiology and Joint Department of Biomedical Engineering, University of North Carolina – Chapel Hill, NC, USA
3 Department of Anaesthesiology, University of Auckland, Auckland, New Zealand
Corresponding author: Associate Professor David J Doolette, Navy Experimental Diving Unit, Panama City, Florida, USA
ORCID: 0000-0001-9027-3536
Keywords
Bubbles; Decompression illness; Decompression sickness; Diving; Echocardiography; Risk
Abstract
(Currens JB, Doolette DJ, Murphy FG. Venous gas emboli (VGE) in 2-D echocardiographic images following movement: grading and association with cumulative incidence of decompression sickness. Diving and Hyperbaric Medicine. 2025 31 March;55(1):44−50. doi: 10.28920/dhm55.1.44-50. PMID: 40090025.)
Introduction: Venous gas emboli (VGE) are a common surrogate experimental endpoint for decompression sickness (DCS). VGE numbers are graded, and the peak post-dive grade is associated with the probability of DCS (PDCS). VGE are typically graded with the subject at rest when bubble numbers are stable, and again after limb flexions which elicit a transient shower of bubbles. Detection of VGE using two-dimensional (2-D) echocardiography has become common, but the principal grading scales do not specify how to grade VGE after limb movement.
Methods: This was a retrospective analysis of 1,196 man-dives following which VGE were detected using 2-D echocardiography and graded on a scale 0–4 and 41 cases of DCS occurred. PDCS was estimated for each peak post-dive VGE grade from the cumulative incidence of DCS. Two different definitions of movement VGE grades were assessed in 84 measurements; the grade was either the maximum VGE number sustained for one diastole (1-cycle) or for six cardiac cycles (6-cycle).
Results: For each peak post-dive VGE grade (maximum of rest or movement) the cumulative incidences of DCS (%) were: grade 0 (0%); grade 1 (1.3%); grade 2 (2.5%); grade 3 (4.6%); grade 4 (5.7%). When grading movement VGE, 57% of 1-cycle grade 4 were reduced to grade 3 using the 6-cycle definition.
Conclusions: There is a need for consensus in the research community on how to assign movement VGE grades when using 2-D echocardiography. Publications should carefully explain methodology for assigning VGE grades and consider differences in methodologies when comparing historical data sets.
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Original article
Diving and Hyperb Med. 2025 31 March;55(1):51−55. doi: 10.28920/dhm55.1.51-55. PMID: 40090026.
Joint position statement on atrial shunts (persistent [patent] foramen ovale and atrial septal defects) and diving: 2025 update. South Pacific Underwater Medicine Society (SPUMS) and the United Kingdom Diving Medical Committee (UKDMC)
David Smart1, Peter Wilmshurst2, Neil Banham3, Mark Turner4, Simon J Mitchell5,6,7
1 Private Consultant. Formerly: Clinical Professor, School of Medicine, University of Tasmania and Department of Diving and Hyperbaric Medicine, Royal Hobart Hospital, Hobart, Tasmania, Australia
2 Cardiology Department, Royal Stoke University Hospital, Stoke-on-Trent, Staffordshire, United Kingdom
3 Department of Hyperbaric Medicine, Fiona Stanley Hospital, Murdoch, Western Australia
4 Bristol Heart Institute, Marlborough Street, Bristol, United Kingdom
5 Department of Anaesthesiology, University of Auckland, Auckland, New Zealand
6 Department of Anaesthesia, Auckland City Hospital, Auckland, New Zealand
7 Slark Hyperbaric Unit, North Shore Hospital, Auckland, New Zealand
Corresponding author: Clinical Professor David Smart, School of Medicine, University of Tasmania and Department of Diving and Hyperbaric Medicine, Royal Hobart Hospital, Hobart, Tasmania, 7000, Australia
ORCiD: 0000-0001-6769-2791
Keywords
Decompression illness; Decompression sickness; Echocardiography; Fitness to dive; Health surveillance; PFO; Right-to-left shunt
Abstract
(Smart D, Wilmshurst P, Banham N, Turner M, Mitchell SJ. Joint position statement on atrial shunts (persistent [patent] foramen ovale and atrial septal defects) and diving: 2025 update. South Pacific Underwater Medicine Society and the United Kingdom Diving Medical Committee. Diving and Hyperbaric Medicine. 2025 31 March;55(1):51−55. doi: 10.28920/dhm55.1.51-55. PMID: 40090026.)
This consensus statement is the product of a workshop at the South Pacific Underwater Medicine Society Annual Scientific Meeting 2024 with representation of the United Kingdom Diving Medical Committee (UKDMC) present, and subsequent discussions included the entire UKDMC. A large right-to-left shunt across a persistent (patent) foramen ovale (PFO), an atrial septal defect (ASD) or a pulmonary shunt is a risk factor for some types of decompression sickness (DCS). It is agreed that routine screening for a right-to-left shunt is not currently justifiable, but certain high risk sub-groups can be identified. Individuals with a history of cerebral, spinal, vestibulocochlear, cardiovascular or cutaneous DCS, migraine with aura or cryptogenic stroke; a family history of PFO or ASD and individuals with other forms of congenital heart disease have a higher prevalence, and for those individuals screening should be considered. If screening is undertaken, it should be by bubble contrast transthoracic echocardiography with provocative manoeuvres (including Valsalva release and sniffing). Appropriate quality control is important. If a shunt is present, advice should be provided by an experienced diving physician taking into account the clinical context and the size of shunt. If shunt-mediated DCS is diagnosed, the safest option is to stop diving. Another is to perform dives with restrictions to reduce the inert gas load, which is facilitated by limiting depth and duration of dives, breathing a gas with a lower percentage of nitrogen and reducing repetitive diving. Divers may consider transcatheter device closure of the PFO or ASD in order to return to normal diving. If transcatheter PFO or ASD closure is undertaken, repeat bubble contrast echocardiography must be performed to confirm adequate reduction or abolition of the right-to-left shunt, and the diver should have stopped taking potent anti-platelet therapy (low dose aspirin is acceptable) before resuming diving.
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Guideline
Diving and Hyperb Med. 2025 31 March;55(1):56−58. doi: 10.28920/dhm55.1.56-58. PMID: 40090027.
A case of facial vascular occlusion after hyaluronic acid cosmetic filler injection treated with adjunctive hyperbaric oxygen
Graham Stevens1, Iestyn Lewis1
1 Department of Diving and Hyperbaric Medicine, Royal Hobart Hospital, Hobart, Tasmania
Corresponding author: Dr Graham Stevens, Department of Diving and Hyperbaric Medicine, Royal Hobart Hospital, Hobart, Tasmania 7000, Australia
ORCiD: 0009-0001-3341-108X
Keywords
Case report; Hyperbaric oxygen treatment; Ischaemia; Skin
Abstract
(Stevens G, Lewis I. A case of facial vascular occlusion after hyaluronidase cosmetic filler injection treated with adjunctive hyperbaric oxygen. Diving and Hyperbaric Medicine. 2025 31 March;55(1):56−58. doi: 10.28920/dhm55.1.56-58. PMID: 40090027.)
Treatment of suspected upper lip area vascular occlusion caused by facial hyaluronic acid filler injections with hyperbaric oxygen is reported. The patient was initially treated with hyaluronidase injections in the cosmetic clinic then again in the emergency department. Persistent symptoms and signs of occlusion prompted hyperbaric oxygen treatment at 284 kPa (nine treatments over seven days). The outcome was positive for this patient and adds supportive evidence to the sparse literature, which are mainly case studies.
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Case Report
Diving and Hyperb Med. 2025 31 March;55(1):59−64. doi: 10.28920/dhm55.1.59-64. PMID: 40090028.
Severe neurological decompression sickness associated with right ventricular dilatation and a persistent foramen ovale
Jeremy S Mason1, Peter Wilmshurst2, Ian C Gawthrope1,3, Neil D Banham1
1 Department of Hyperbaric Medicine, Fiona Stanley Hospital, Murdoch, WA, Australia
2 Cardiology Department, Royal Stoke University Hospital, Stoke on Trent, United Kingdom
3 University of Notre Dame, Fremantle, WA, Australia
Corresponding author: Dr Jeremy Mason, Department of Hyperbaric Medicine, Fiona Stanley Hospital, 11 Robin Warren Drive, Murdoch, WA 6150, Australia
ORCiD: 0000-0002-9133-2179
Keywords
Arterial gas embolism; Case reports; Decompression illness; Diving incidents; Persistent (patent) foramen ovale (PFO); Scuba diving; Right-to-left shunt
Abstract
(Mason JS, Wilmshurst P, Gawthrope IC, Banham ND. Severe neurological decompression sickness associated with right ventricular dilatation and a persistent foramen ovale. Diving and Hyperbaric Medicine. 2025 31 March;55(1):59−64. doi: 10.28920/dhm55.1.59-64. PMID: 40090028.)
We present the case of a 28-year-old female diver who performed a scuba air dive with significant omitted decompression obligation. She developed constitutional and neurological symptoms. Brain magnetic resonance imaging post treatment demonstrated multifocal embolic infarcts and transthoracic echocardiogram with bubble contrast on day three revealed a persistent foramen ovale (PFO) and severe right ventricular (RV) dilatation.
We postulate that the high venous bubble load from the provocative decompression caused an increase in pulmonary artery pressure, leading to RV dilatation and increased right to left shunting of bubbles across her PFO, resulting in significant neurological deficits. This mechanism is analogous to that seen in acute thromboembolic pulmonary embolism.
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Case Report
Diving and Hyperb Med. 2025 31 March;55(1):65. doi: 10.28920/dhm55.1.65. PMID: 40090029.
PFO and DCS of hyperbaric personnel
Jacek Kot
Corresponding author: Professor Jacek Kot, MD, PhD, National Centre for Hyperbaric Medicine, Institute of Maritime and Tropical Medicine, Medical University of Gdansk, Powstania Styczniowego 9B, 81-519 Gdynia, Poland
Keywords
Decompression sickness; Hyperbaric oxygen treatment; Persistent (patent) foramen ovale (PFO); Risk factors; Safety
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Letter to the Editor
Diving and Hyperb Med. 2025 31 March;55(1):66. doi: 10.28920/dhm55.1.66. PMID: 40090030.
Reply – PFO and DCS of hyperbaric personnel
Peter T Wilmshurst1, Chris Edge2
1 Royal Stoke University Hospital, Cardiology Department, United Kingdom
2 Imperial College, Department of Life Sciences, United Kingdom
Corresponding author: Peter T Wilmshurst, Royal Stoke University Hospital, Cardiology Department, United Kingdom
Keywords
Decompression sickness; Echocardiography; Hyperbaric oxygen; Occupational health; Persistent (patent) foramen ovale (PFO)
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Letter to the Editor
Diving and Hyperb Med. 2025 31 March;55(1):67. doi: 10.28920/dhm55.1.67. PMID: 40090031.
Dive medicine capability at Rothera Research Station (British Antarctic Survey), Adelaide Island, Antarctica
Felix N R Wood1,2, Katie Bowen1, Rosemary Hartley1, Jonathon Stevenson4, Matt Warner1, Doug Watts1,3
1 British Antarctic Survey Medical Unit, Plymouth, United Kingdom
2 Academic Department of Military Emergency Medicine, Royal Centre for Defence Medicine, United Kingdom
3 DDRC Healthcare, Plymouth, United Kingdom
4 British Antarctic Survey, Cambridge, United Kingdom
Corresponding author: Dr Felix Wood, British Antarctic Survey Medical Unit, Science Park, Plymouth, PL6 8BU, United Kingdom
ORCiD: 0000-0002-5706-852X
Keywords
Cold; Diving; Diving emergencies; Drysuit; Recompression; Remote locations
In December, we published an article titled “Dive Medicine Capability at Rothera Research Station (British Antarctic Survey), Adelaide Island, Antarctica” by Wood FNR, Bowen K, Hartley R, et al.
The corresponding author would like to include an additional author, as their contribution was significant but was inadvertently omitted in the initial online publication. While this correction has been made in several versions circulated by the journal, not all have been updated. As a result, we are issuing an erratum. The correct authors are listed here.
Copyright: This article is the copyright of the authors who grant Diving and Hyperbaric Medicine a non-exclusive licence to publish the article in electronic and other forms.
Publication Type: Erratum