Int J Sports Med 2001; 22(3): 166-174
DOI: 10.1055/s-2001-16379
Physiology and Biochemistry

Georg Thieme Verlag Stuttgart ·New York

Effect of Low-Dose Temazepam on Physiological Variables and Performance Tests Following a Westerly Flight Across Five Time Zones

T. Reilly1 ,  G. Atkinson1 ,  R. Budgett2
  • 1 Research Institute for Sport and Exercise Sciences, Liverpool John Moores University, Trueman Building, Henry Cotton Campus, Webster Street, Liverpool, UK
  • 2 British Olympic Medical Centre, Northwick Park Hospital, Watford Road, Harrow, Middlesex, UK
Weitere Informationen

Publikationsverlauf

Publikationsdatum:
31. Dezember 2001 (online)

Rapid travel across multiple time zones disturbs circadian rhythms and induces “jet lag”. The aims of this study were 1) to monitor a selection of subjective, physiological and performance variables in elite athletes and sedentary subjects following a westerly flight across five time zones, and 2) to examine whether the promotion of sleep by means of a low-dose benzodiazepine drug influences these responses to transmeridian travel.

Subjects comprised eight members of the British men's gymnastics squad, aged 18 - 30 years, and nine members of the British Olympic Association's support staff, aged 24 - 55 years (4 females, 5 males). Subjects were pair-matched for age, sex and athleticism (apart from one person) and assigned to either the treatment (n = 9) or placebo (n = 8) group. All subjects travelled from U.K., arriving at Tallahassee, Florida, at approximately 22:00 hours local time. A test battery was administered to the subjects at 07:00, 12:00, 17:00 and 21:00 hours on the first full day of arrival (this was designated day one) and then on alternate days (day 3, day 5 and day 7). Immediately before retiring to bed on days 1, 2 and 3, subjects were administered, in a double-blind fashion, either 10 mg of temazepam or a placebo. Measures in the test battery included sleep quality, sleep length, subjective jet lag (one-to-ten simple analogue scale), tympanic temperature, one-, two-, four- and eight-choice reaction time, grip strength (left and right), leg strength and back strength. Over the 24 h of each test day, subjects also recorded the volume of each urine voided. Data were analysed with a repeated measures general linear model. Alpha was set at 0.01 to control for type I errors with multiple dependent variables.

Mean subjective jet lag reduced from 4.6 units to baseline, and mean sleep quality improved by 2.0 units from day 1 to day 5 (P < 0.001), after which no further alterations were noted. Subjective jet Iag, left and right grip strength and choice reaction time all showed post-flight day × time of day interactions (P < 0.01). On day 1, these variables deteriorated as the day progressed to the worst recorded values. On days 3, 5 and 7, diurnal variations with the conventional high in the early evening and morning-to-evening differences of about 10 % were evident. There was a trend for the reduction in subjective jet lag over the post-flight days to be more rapid following ingestion of a low dose of temazepam (P = 0.037). We cannot rule out the possibility that this could be a type I error, since none of the treatment by day interactions reached the alpha level of significance (set at 0.01). The morning-to-evening variations of body temperature and grip strength were greater in the young athletes than in the older sedentary support staff (P < 0.01). Sleep quality was greater in the athletic subjects after the first full day in Tallahassee. These results suggest that the nightly administration of a low dose (10 mg) of temazepam has little influence on the recovery of subjective, physiological and performance measures following a westward flight across five time zones. In both the treatment and control groups, subjective jet lag and performance were worst in the evening of the first full day after arrival, and the young athletes slept better than the older support staff that same night. This illustrates the importance of monitoring jet lag symptoms and performance variables at different times of day following a flight to a new time zone.

References

  • 1 Arendt J, Deacon S. Treatment of circadian rhythm disorders - melatonin.  Chronobiology International. 1997;  14 185-204
  • 2 Atkinson G, Reilly T. Circadian variation in sports performance.  Sports Medicine. 1996;  21 292-312
  • 3 Atkinson G, Reilly T. Effects of age and time of day on preferred work-rates during prolonged exercise.  Chronobiology International. 1995;  12 121-129
  • 4 Atkinson G, Coldwells A, Reilly T, Waterhouse J. An age comparison of circadian rhythms in physical performance and mood states.  Journal of Interdisciplinary Cycle Research. 1992;  23 186-188
  • 5 Atkinson G, Coldwells A, Reilly T, Waterhouse J. A comparison of circadian rhythms in work performance between physically active and inactive subjects.  Ergonomics. 1993;  36 273-281
  • 6 Bland M. An introduction to Medical Statistics. Oxford; University Press 1995
  • 7 Coldwells A, Atkinson G, Reilly T. Sources of variation in back and leg dynamometry.  Ergonomics. 1994;  37 79-86
  • 8 Dawson D, Armstrong S M. Chronobiotics - drugs that shift rhythms.  Pharmacological Therapy. 1996;  69 15-36
  • 9 Donaldson E, Kennaway D J. Effects of temazepam on sleep, performance and rhythmic 6-sulphatoxymelatonin and cortisol excretion after transmeridian travel.  Aviation Space and Environmental Medicine. 1991;  62 654-660
  • 10 Eastman C I, Hoese E K, Youngstedt S D, Liu L. Phase shifting human circadian rhythms with exercise during the night shift.  Physiology and Behaviour. 1995;  58 1287-1291
  • 11 Edgar D M, Seidel W F, Dement W C. Triazolam-induced sleep in the rat: influence of prior sleep, circadian time and light/dark cycles.  Psychopharmacology. 1991;  105 374-380
  • 12 Anonymous editorial . Jet lag and its pharmacology.  Lancet. 1986;  2 493-494
  • 13 Fraschini F, Stankov B. Temazepam: pharmacological profile of a benzodiazepine and new trends in its clinical application.  Pharmacology Research. 1993;  27 97-113
  • 14 Harma M I, Ilmarinen J, Knauth P, Rutenfranz J, Hanninen P. Physical training intervention in shift-workers. 1. The effects of intervention on fitness, fatigue, sleep, and psychomotor symptoms.  Ergonomics. 1988;  31 39-50
  • 15 Hill D W, Hill C M, Fields K L, Smith J C. Effects of jet lag on factors related to sports performance.  Canadian Journal of Applied Physiology. 1993;  18 91-103
  • 16 Jehue R, Street D, Huizenga R. Effect of time zone and game time changes on team performance. National Football League.  Medicine and Science in Sports and Exercise. 1993;  25 127-131
  • 17 Klein K E, Wegman H M. The resynchronisation of human circadian rhythms after transmeridian flights as a result of flight direction and mode of activity. In: Scheving LE, Halberg F, Pauly JE (eds) Chronobiology. Tokyo; Igoku Shoin 1974: 564-570
  • 18 Minors D, Waterhouse J. Circadian rhythms and the human. London; Wright PSG 1981
  • 19 Moline M L, Pollak C P, Monk T H . et al . Age-related differences in recovery from simulated jet lag.  Sleep. 1992;  15 28-40
  • 20 Nevill A M, Atkinson G. Assessing agreement between measurements recorded on a ratio scale in sports medicine and sports science.  British Journal of Sports Medicine. 1997;  31 314-318
  • 21 Nicholson A N. Hypnotics: Clinical pharmacology and therapeutics. In: Kryger MH, Roth T, Dement WC (eds) Principles and Practice of Sleep Medicine. Philadelphia; WB Saunders 1994: 355-363
  • 22 Nicholson A N, Pascoe P A, Spencer M B . et al . Sleep after transmeridian flights.  Lancet. 1986;  2 1205-1208
  • 23 Nicholson A N, Pascoe P A, Spencer M B, Benson A J. Jet lag and motion sickness.  British Medical Bulletin. 1993;  49 285-304
  • 24 O'Connor P J, Morgan W. Athletic performance following rapid traversal of multiple time-zones.  Sports Medicine. 1990;  10 20-30
  • 25 O'Connor P J, Morgan W P, Koltyn K F . et al . Air travel across four time zones in college swimmers.  Journal of Applied Physiology. 1991;  70 756-763
  • 26 Penetar D M, Belenky G, Carrigan J J. Triazolam impairs learning and fails to improve sleep in a long-range aerial deployment.  Aviat Space Environ Med. 1989;  60 594-598
  • 27 Ralph M R, Menaker M. Effects of diazepam on circadian phase advances and delays.  Brain Research. 1986;  372 405-408
  • 28 Redlin U, Mrosovsky N. Exercise and human circadian rhythms. What we know and what we need to know.  Chronobiology International. 1997;  14 221-229
  • 29 Reilly T, Waterhouse J, Atkinson G. Aging, rhythms in physical performance and adjustment to changes in the sleep-activity cycle.  Occupational and Environmental Medicine. 1997;  54 812-816
  • 30 Reilly T. Human circadian rhythms and exercise.  Critical Reviews in Biomedical Engineering. 1990;  18 165-180
  • 31 Reilly T, Atkinson G, Waterhouse J. Biological Rhythms and Exercise. Oxford; Oxford University Press 1997
  • 32 Schultz R W, Gessaroli M E. The analysis of repeated measures designs involving multiple dependent variables.  Research Quarterly for Exercise and Sport. 1987;  58 132-149
  • 33 Shiota M, Sudou M, Ohshima M. Using outdoor exercise to decrease jet lag in airline crew members.  Aviation Space and Environmental Medicine. 1996;  67 1155-1160
  • 34 Stone B M, Turner C. Promoting sleep in shiftworkers and intercontinental travelers.  Chronobiology International. 1997;  14 133-143
  • 35 Turek F W, Losee-Olsen S. A benzodiazepine used in the treatment of insomnia phase-shifts the mammalian circadian clock.  Nature. 1986;  321 167-168
  • 36 Van Reeth O, Sturis J, Byrne M M . et al . Nocturnal exercise phase delays circadian rhythms of melatonin and thyrotropin secretion in normal men.  American Journal sp Physiology. 1994;  266 E964-E974
  • 37 Van Reeth O, Turek F W. Stimulated activity mediates phase shifts in the hamster circadian clock induced by dark pulses or benzodiazepines.  Nature. 1989;  339 49-55
  • 38 Waterhouse J, Minors D, Redfern P. Some comments on the measurement of circadian rhythms after time-zone transitions and during night work.  Chronobiology International. 1997;  14 125-132
  • 39 Wee B EF, Turek F W. Midazolam, a short acting benzodiazepine, resets the circadian clock of hamsters.  Pharmacol Biochem Behav. 1989;  32 901-906
  • 40 Wever R. Influence of physical workload on free running circadian rhythms of man.  Pflügers Archives. 1979;  381 119-126

Prof. T. Reilly

Research Institute for Sport and Exercise Sciences
Liverpool John Moores University
Trueman Building
Henry Cotton Campus

Webster Street
Liverpool, L3 3AF
UK


Telefon: Phone:+ 44 (151) 231-4323

Fax: Fax:+ 44 (151) 231-4353

eMail: E-mail:t.p.reilly@livjm.ac.uk