SAJSM  vol 24  No. 1  2012 27

COMMENTARY

Brain damage risk in diving 
There is a substantial body of research on the neurological and 
neuropsychological effects of compressed gas diving that occurs in both 
the recreational and occupational spheres. A recent review of diving 
practice indicates that there are approximately 7 million divers active 
worldwide, and about 500 000 training every year,1 despite the fact 
that it is accompanied by a number of brain-related hazards including 
hypoxia, gas toxicity, bubble-related insults and decompression illness 
(DCI).* In a survey of 770 divers Beckett and Kordick2 indicated that 
half of these divers (53%) had suspected decompression symptoms. 
Similarly, in a study of 156 air and saturation divers 51% had DCI, 

33% of these with neurological symptoms.3 In contrast to the high risk 
of DCI implied by these figures, Vann et al.4 suggest that if appropriate 
decompression procedures are followed, DCI is uncommon and 
incidence declines. They suggest that acceptable risk for commercial 
diving is 0.1% for mild cases and 0.025% for serious cases;  for US 
Navy diving acceptable risk is 2% for mild cases and 0.1% for serious 
cases. However, these authors concede that there are insufficient 
data for accurate estimates of incidence of decompression sickness 
both in the recreational and commercial spheres, and that incidence 
figures based on dives made well within maximum exposure limits 
of accepted procedures are an underestimate of the true rates at 
maximum limits. Notwithstanding uncertainty around the rate of 
occurrence of frank DCI, there is growing emphasis on the fact that 
divers may be suffering subtle symptoms that they do not recognise 
as DCI, and/or be suffering subclinical effects of repetitive ‘silent’ 
paradoxical gas embolisms that may have long-term deleterious 
neurological consequences.5,6

As reviewed in Wilmhurst,6 neuroradiological investigations on divers 
predominantly provide support for brain-related changes in association 
with diving. A series of studies have investigated long-term/cumulative 
neurological and neurocognitive effects via objective psychometric 
testing of divers in contrast to demographically matched non-diving 
controls, with outcome implicating deleterious CNS effects. Outcomes 
included prolonged reaction time scores for construction divers;7 
significantly poorer learning and short-term memory performance, 
and a tendency to sacrifice accuracy for speed for commercial abalone 
divers;8 and performance deficits in number of reference memory errors 
and navigation behaviour of construction divers.9 A cohort of divers who 
complained of forgetfulness were differentiated from divers without this 
complaint, on the basis of being significantly more impaired with regard 
to objective memory tests.10 

Further of note are studies that provide evidence for cumulative 
deleterious effects in association with repeat-diving. The study of Aarli 
et al.,11 investigating for CNS dysfunction, documented no significant 
changes in any of the professional divers immediately after one dive, 
but there was clear-cut impairment in a group who had performed 
two dives three months apart. Research by Vaernes et al.12 points 
to how repeated deep-diving activity is likely to result in greater 
neuropsychological impairment. It appears that, for professional 
divers with high exposure to decompression stress, the incidence 
of intellectual decline may be as high as 50%,13 and accordingly the 
concern is expressed that diving may produce residual intellectual 
decline equivalent to dementia or ‘punch-drunk syndrome’ as 
described in association with years of competitive participation 
in boxing. Finally, a very recent study of military divers without a 
history of DCI demonstrated higher motor and decision reaction 
times among very experienced divers logging extensive diving hours, 

Cerebral damage in diving: Taking the cue from sports concussion 
medicine
Ann B Shuttleworth-Edwards (PhD)
Victoria J Whitefield-Alexander (PhD)

National Sports Concussion Initiative, Department of Psychology, Rhodes University, Grahamstown, South Africa

Correspondence to: Ann Edwards (a.edwards@ru.ac.za)

Abstract
Within the compressed gas diving arena there is a risk of 
cerebral damage with deleterious neuropsychological sequelae in 
association with decompression illness (DCI), hypoxia, gas toxicity, 
as well as the cumulative subclinical effect of ‘silent’ paradoxical gas 
embolisms, the last being an area of growing concern. However, 
within diving medicine there is little evidence of the regular 
use of neuropsychological evaluation to monitor brain-related 
sequelae of frequent diving activity. In contrast, in recent years 
there has been an explosion of interest in the management of 
sports concussive injury, including emphasis on the pivotal role of 
neuropsychological evaluation within that context. Taking the cue 
from sports concussion medicine, it is proposed that there is an 
urgent need to incorporate neurocognitive baseline and follow-up 
screening as a core component in the medical management of those 
involved in intensive commercial and recreational compressed air 
diving activities. The objective would be to facilitate (i) accurate 
neurodiagnostic follow-up of frank DCI or an identifiable 
hypoxic or toxic incident; (ii) timeous identification of cumulative 
deleterious effects of repetitive subclinical hypoxic/toxic incidents 
and/or ‘silent’ paradoxical gas embolisms that might affect them in 
later life; and (iii) disability assessment following any such events 
or the combination thereof for rehabilitation and compensation 
purposes.

*The reader is referred elsewhere for a more comprehensive delineation of the physiological mecha-
nisms involved in injury to the nervous system in association with diving, including decompression 
illness, hypoxia, gas toxicity and ‘silent’ paradoxical gas embolisms,

4,5,25
 which are beyond the scope of 

the current article. 



28 SAJSM  vol 24  No. 1  2012

compared with less experienced military divers with significantly 
fewer diving hours.5 This study points to the possibility that cerebral 
lesions may occur after diving even without apparent DCI.

In essence, the neurocognitive decrements reported across the 
above-cited studies in association with diving participation fall 
broadly within the ambits of short-term memory, attentional abilities, 
processing speed and reaction time. 

Parallels between cerebral injury in field contact sport and 
diving
Despite very different neuropathological underpinnings, it is apparent 
that from a neuropsychological perspective a number of parallels 
can be drawn between cerebral injury sustained via participation 
in a field contact sport and compressed gas diving activity. Reviews 
indicate that the incidence of sustaining a concussion in American 
football or Rugby Union at adult level over a series of seasons is 
42% and 50%, respectively.14 Declines in neurocognitive function 
are more clearly evident when there is a history of two or more 
concussions and more extended periods of high-level participation 
in the sport, and it is commonly acknowledged that effects may go 
unrecognised or be subclinical, yet have cumulative deleterious long-
term effects.15 Finally, there is a substantial body of research that 
points to permanent neurocognitive consequences of concussive 
and cumulative subconcussive injury in association with American 
football, soccer, and Rugby Union,15 including diminished short-term 
memory, processing speed, reaction time, and attentional abilities.

Accordingly, while the incidence of concussion documented 
in the rugby-football sports appears considerably higher than the 
apparent incidence of DCI under suitably controlled conditions,4 the 
following broad-based similarities exist between the two contexts. 
Firstly, to a greater or lesser extent, there is known risk for the 
frank occurrence of a cerebrally noxious event to take place (i.e. 
concussion or DCI) that may/may not be accompanied by persisting 
neuropsychological dysfunction. In both forums, albeit for different 
reasons, there is growing concern for ‘silent’ subclinical neurological 
damage in association with participation in these activities, with 
deleterious neurocognitive consequences. Evidence for the presence 
of such neuropsychological dysfunction is enhanced in association 
with prolonged, repetitive and/or professional level participation in 
each of these activities. Finally, the neurocognitive consequences in 
association with cerebral damage sustained through participation in 
both contact sport and diving, albeit of different neuropathological 
origin, are nevertheless functionally similar, falling broadly within the 
areas of short-term memory, attentional abilities, processing speed 
and reaction time. Therefore, from a neuropsychological perspective, 
equivalent screening mechanisms for deleterious outcome due to 
cerebral damage that may occur in association with contact sport 
and diving (although neuropathogically distinct) are entirely in order.

Routine screening for neuropsychological impairment in 
divers
Despite the parallels that can be drawn around the occurrence and 
long-term outcome of neurological damage in association with 
concussion and diving-related brain impairment, there are marked 
differences in terms of how this aspect is medically managed within 
the two arenas. With regard to sports concussion, there has been an 
explosion of interest in the problem over the last decade, including 
the convening of three international conferences to initiate up-to-
date recommendations for optimal medical management of the 

concussive injury.16-18 One of the core guidelines to emerge from 
these seminal meetings is that individualised medical management 
of the concussed athlete is recommended including the use of 
neuropsychological assessment, optimally under the guidance of 
neuropsychologists who are considered to be ‘in the best position’ to 
interpret neuropsychological tests.18,19 

In contrast, underwater medicine appears to be a relatively neglected 
area, notably in terms of neuropsychological involvement, with the 
main attention still being paid to emergency care of respiratory crises 
with neurological consequences, rather than long-term aftercare 
including the assessment of disability for compensation purposes.20,21 
Ironically, there was an international consensus conference on the 
long-term health effects of diving that pre-dated the first of the 
concussion in sport consensus conferences22 at which longitudinal 
follow-up of divers was recommended. However, it appears that the 
convening of a forum of this type out of concern for the medical 
management of divers in particular (rather than hyperbaric 
medicine more generally) was not repeated, nor did it result in the 
implementation of neurocognitive screening on a routine or wide 
basis. A comprehensive Pubmed and Biomed search confirms the 
impression that any formally stated recommendation concerning 
neuropsychological evaluation as a routine part of the medical 
examination of commercial or recreational divers has never been in 
place, and continues to be neglected.

Specific issues pertaining to neuropsychological assessment
A number of neurocognitive screening programmes based on 
well-researched traditional neuropsychological test stimuli (i.e. 
having good face validity as neuropsychological instruments) 
have been especially developed within the sports concussion 
arena. These might be considered for use in the diving context, 
e.g. ANAM, Headminder and ImPACT.23 Of these the ImPACT 
programme, now in its fourth updated version, is the most 
commonly employed test of its kind worldwide, and is an HPCSA-
approved test for use within South Africa. The recommended 
mechanism within the spor ts arena is to conduct baseline 
neurocognitive evaluation on individuals prior to engagement in 
the cerebrally hazardous activity using a recognised instrument 
of this type for comparative purposes with follow-up testing after 
a cerebrally harmful event.  

Specifically, the ImPACT test provides an automated report 
on six cognitive composites that incorporate the functional 
areas described above that are typically implicated following 
the decompression event, viz. memor y function, attentional 
abilities, reaction time and processing speed. A strength of the 
ImPACT programme is the incorporation of a 24-item check 
list of neuropsychiatric symptoms that are typically in evidence 
after concussion. Recently, a special adaptation of ImPACT 
has been developed for work within the militar y, keeping the 
neurocognitive aspect intact, but making adjustments to the 
demographic and symptom questionnaires. 24 Similarly, for use 
within the diving context it would be possible to tailor-make 
the programme to include relevant details such as prior history 
of any incident of DCI, years involved in diving, estimate of 
number of dives completed, and purpose of diving. Furthermore, 
it would be possible to ensure that the symptom checklist 
incorporates neuropsychiatric sequelae that have regularly been 
described in association of decompression illness. Symptoms 
following diffuse cerebral presentations such as concussion and 



SAJSM  vol 24  No. 1  2012 29

DCI var y widely and are nonspecific, with many sequelae in 
common, such as ‘dizziness’, ‘headache’, ‘difficulty remembering’, 
‘numbness’, ‘tingling’, ‘difficulty concentrating’ and ‘fatigue’. From 
a neuropsychological point of view, it is of prime diagnostic value 
to have a testee’s idiosyncratic self-report symptom profile, in 
addition to the objective psychometric test profile, when drawing 
conclusions concerning the presence or absence of neurological 
fall-out and/or the extent of disability.

Conclusions
As a matter of some urgency, it would seem appropriate for diving 
medicine to consider taking the cue from sports concussion medicine, 
specifically with regard to the incorporation of neuropsychological 
evaluation (such as is widely applied within professional and amateur 
contact sports) to monitor its cerebrally hazardous injury. Ideally, this 
would involve the initiation of computerised neurocognitive baseline 
screening, and follow-up testing in the wake of any DCI incident, as 
well as other identifiable hypoxic or toxic respiratory incidents, to 
establish the extent of disability. Importantly, comparative baseline 
screening for divers on an annual or a bi-annual basis would provide 
the platform to establish the presence of ‘silent’ cognitive decline 
implicating the insidious onset of brain dysfunction that may affect 
them in the long term, such as may not be immediately in the diver’s 
awareness or apparent during a regular medical examination. 

As DCI appears to be a relatively uncommon and declining 
occurrence, especially when under controlled conditions (compared 
with the incidence of the concussive incident in contact sport), the 
initiation of routine neurocognitive baseline testing in all contexts 
might be deemed to be unwarranted. Nevertheless, it is still a distinct 
risk, and taken together with the growing concern for subclinical 
neuropathological changes due to paradoxical gas embolisms, such 
testing would appear to be the advised route to follow for those 
involved in recurrent compressed gas diving activity. At the very least, 
the implementation of longitudinal studies of both occupational and 
recreational divers utilising computerised neurocognitive testing 
with a tool such as ImPACT is indicated, to capture immediate and 
enduring neuropsychological outcome of both clearly identifiable as 
well as ‘silent’ neuropathological events.

Acknowledgements
This article is based on a paper presented by invitation at the 17th 
International Congress of Hyperbaric Medicine (ICHM), Cape Town 
Convention Centre, Cape Town, South Africa, 16 - 19 March 2011.

Funding for costs involved in the preparation and earlier 
presentation of this review was facilitated by National Research Fund 
(NRF) incentive funding, and a Rhodes University Joint Research 
Council (JRC) grant.

Declaration of conflict of interests
The authors are involved in implementing the ImPACT programme in 
South Africa and the UK for research and clinical purposes.

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