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DOI: 10.1055/s-2004-821038
© Georg Thieme Verlag KG Stuttgart · New York
Brain Magnetic Resonance Imaging, Aerobic Power, and Metabolic Parameters Among 30 Asymptomatic Scuba Divers
Publication History
Accepted after revision: March 5, 2004
Publication Date:
10 September 2004 (online)
Abstract
The aim of the study was to evaluate the presence of cerebral lesions in asymptomatic scuba divers and explain the causes of them: potential risk factors associating cardiovascular risk factors, low aerobic capacity, or characteristics of diving (maximum depth, ascent rate). Experienced scuba divers, over 40 years of age, without any decompression sickness (DCS) history were included. We studied 30 scuba divers (instructors) without any clinical symptoms. For all of them, we carried out a clinical examination with fatty body mass determination and we questioned them about their diving habits. A brain Magnetic Resonance imaging (MRI), an assessment of maximal oxygen uptake, glycemia, triglyceridemia, and cholesterolemia were systematically carried out. Cerebral spots of high intensity were found at 33 % in the scuba diving group and 30 % in the control group. In the diving group, abnormalities were related to unsafe scuba-diving or metabolic abnormalities. In our study, we did not find a significant relationship between the lesions of the central nervous system, and the age, depth of the dives, number of dives, and ergometric performances (maximal oxygen uptake, V·O2max, serum level of blood lactate). Nevertheless, we found a significant relationship between the lesions of the central nervous system and ascent rate faster than 10 meters per minute (r = 0.57; p = 0.003) or presence of high level of cholesterolemia (r = 0.6; p = 0.001). We found concordant results using the Cochran's Test: meaningful link between the number of brain lesions and the speed of decompression (Uexp = 14 < Utable = 43; α = 0.05, p < 0.01). We concluded that hyperintensities can be explained by preformed nitrogen gas microbubbles and particularly in presence of cholesterol, when the ascent rate is up to 10 meters per minute. So, it was remarkable to note that asymptomatic patients practicing scuba diving either professionally or recreationally, presented lesions of the central nervous system. This survey permitted us to highlight in a population of professional divers, neurological and also cardiovascular abnormalities (ventricular arrhythmias); although none of them present any symptoms today. It seems therefore important to us to propose in the future, for a better prevention of neurological injuries, a systematic follow-up by maximal oxygen consumption measure, brain MRI, and cholesterolemia. In the same way, our results suggest a modification of the diving tables with a maximal decompression rate at 9 m · mn-1.
Key words
Scuba diving - MRI - decompression rate - maximum oxygene uptake - cholesterolemia - microbubbles
References
- 1 Astrand P O, Rhyming (Eds) L. Manuel de Physiologie de L'Exercice Musculaire. Paris; Masson 1973
- 2 Bosquet L, Léger L, Legros P. Les méthodes de détermination de l'endurance aérobie. Sci & Sports. 2000; 15 55-73
- 3 Boussuges A, Succo E, Juhan-Vague I, Sainty J M. Activation of coagulation in decompression illness. Aviat Space Environ Med. 1998; 69 129-132
- 4 Bove A A. Risk of decompression sickness with patent foramen ovale. Undersea Hyperb Med. 1998; 25 175-178
- 5 Bowen A C, Barker W W, Loewenstein D A. et al . MR signal abnormalities in memory disorder and dementia. ANJR. 1990; 11 283-290
- 6 Butler B D, Hills B A. Transpulmonary passage of venous air emboli. J Appl Physiol. 1985; 59 543-547
- 7 Carturan D, Boussuges A, Burnet H, Fondarai J, Vanuxem P, Gardette B. Circulating venous bubbles in recreational diving: relationships with age, weight, maximal oxygen uptake and body fat percentage. Int J Sports Med. 1999; 20 410-414
- 8 Dwyer J. Estimation of oxygen uptake from heart rate response to undersea work. Undersea Biomed Res. 1983; 10 77-87
- 9 Geraut C, Simon C, Dupas D, Bellec J M. Risques de la plongée sous-marine et du travail en milieu hyperbare. Encycl Méd Chir. 1993; 16 - 560-A-10 1-8
- 10 Jauchem J R, Waligora J M, Conkin J, Horrigan Jr D J, Johnson Jr P C. Blood biochemical factors in humans resistant and susceptible to formation of venous gas emboli during decompression. Eur J Appl Physiol. 1986; 55 68-73
- 11 Kindermann W, Simon G, Keul J. The significance of aerobic-anaerobic transition for the determination of workload intensities during endurance training. Eur J Appl Physiol. 1979; 42 25-34
- 12 Kissman K E, Masurel G, Guillerm R. Bubble evaluation code for Doppler ultrasonic decompression data. Undersea Biomed Res. 1978; 5 28
- 13 Knauth M, Ries S, Pohimann S, Kerby T, Forsting M, Daffertshofer M, Hennerici M, Sartor K. Cohort study of multiple brain lesions in sport divers: role of a patent foramen ovale. BMJ. 1997; 314 701-705
- 14 Lenz T, Weiss M, Werle E, Walz U, Pinther J, Weicker H. Influence of exercise in water on hormonal, metabolic and adrenergic receptor changes in man. Int J Sports Med. 1988; 9 125-131
- 15 Lohman T G. Applicability of body composition techniques and constants for children and youths. Exerc Sport Sci Rev. 1986; 14 325-357
-
16 Lohman T G, Going S B.
Multicomponent models in body composition research: opportunities and pitfalls. Ellis KJ, Eastman JD Human Body Composition. New York; Plenum 1993: 53-58 - 17 Molvaer O I, Albrektsen G. Hearing deterioration in professional divers: an epidemiologic study. Undersea Biomed Res. 1990; 17 231-246
- 18 Neubauer B, Tetzlaff K, Buslaps C, Schwarzkopf J, Bettinghausen E, Rieckert H. Blood lactate changes in men during graded workloads at normal atmospheric pressure (100 kPa) and under simulated caisson conditions (400 kPa). Int Arch Occup Environ Health. 1999; 72 178-181
- 19 Omerod I EC, Miller D H, Mac Donald W I. et al . The role of NMR imaging in assessment of multiple sclerosis. Brain. 1987; 110 1579-1616
- 20 Philp R B, Inwood M J, Warren B A. Interactions between gas bubbles and components of the blood: implications in decompression sickness. Aerosp Med. 1972; 43 946-953
- 21 Pluto R, Cruze S A, Weiss M, Hotz T, Mandel P, Weicker H. Cardiocirculatory, hormonal and metabolic reactions to various forms of ergometric tests. Int J Sports Med. 1998; 9 79-88
- 22 Reul J, Weis J, Jung A, Willmes K, Thron A. Central nervous system lesions and cervical disc herniations amateur divers. Lancet. 1995; 345 1403-1405
- 23 Rinck P A, Svihus R, de Francisco P. MR imaging of the central nervous system in divers. J Magn Reson Imaging. 1991; 3 293-299
- 24 Smith D J, Deuster P A, Ryan C J, Doubt T J. Prolonged whole body immersion in cold water: hormonal and metabolic changes. Undersea Biomed Res. 1990; 17 139-147
- 25 Smith K H, Stayton L. Hyperbaric Decompression by Means of Bubble Detection. Seattle; Virginia Mason Research Center, ONR report NOOO1469- C-0402 1978
- 26 Todnem K, Nyland H, Riise T, Kambestad B K, Vaernes R, Hjelle J O, Svihus R, Aarli J A. Analysis of neurologic symptoms in deep diving: implications for selection of divers. Undersea Biomed Res. 1990; 17 95-107
- 27 Vallier J M, Bigard A X, Carré F, Eclache J P, Mercier J. Détermination des seuils lactiques et ventilatoires. Position de la Société française de médecine du sport. Sciences & Sports. 2000; 15 133-140
- 28 Warren Jr L P, Djang W T, Moon R E, Camporesi E M, Sallee D S, Anthony D C, Massey E W, Burger P C, Heinz E R. Neuroimaging of scuba diving injuries to the CNS. AJR AM J Roentgenol. 1988; 5 1003-1008
- 29 Wasserman K, Hansen E J, Sue Y D, Whipp (Eds) J B. Principles of Exercise Testing and Interpretation. Philadelphia; Lea & Febiger 1987
- 30 Weiss M, Hack F, Stehle R, Pollert R, Weicker H. Effects of temperature and water immersion on plasma cathecholamines and circulation. Int J Sports Med. 1988; 9 113-117
- 31 Yanagawa Y, Okada Y, Terai C, Ikeda T, Ishida K, Fukuda H, Hirata F, Fujita K. MR imaging of the central nervous system in divers. Aviat Space Environ Med. 1998; 69 892-895
D. Tripodi
Institut de Médecine du Travail et des Risques Professionnels en Milieu Hyperbare Médecine Préventive
CHU Hôtel-Dieu
44035 Nantes cedex 01
France
Phone: + 330240084554
Fax: + 33 02 40 08 36 34
Email: dominique.tripodi@chu-nantes.fr