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Multiple complications after internal jugular vein catheterisation (1986)

GAMULIN, Z. ; BRÜCKNER, J.-C. ; FORSTER, A. ; [et al.]

Oxford, UK : Blackwell Publishing Ltd

Anaesthesia 41 (1986), S. 0

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ISSN: 1365-2044

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Medicine

Notes: We report a case of a young female who developed multiple life threatening complications after a single internal jugular vein catheterisation. They consisted of pleural misplacement of the catheter. massive haemorrhage with cardiovascular collapse following catheter removal, and development of arteriovenous fistula, diagnosed 18 months later.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1365-2044.1986.tb13229.x

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The energy cost of running increases with the distance covered (1991)

Brueckner, J. C. ; Atchou, G. ; Capelli, C. ; [et al.]

Springer

European journal of applied physiology 62 (1991), S. 385-389

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ISSN: 1439-6327

Keywords: Energy cost of running ; Distance ; Fatigue

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The net energy cost of running per unit of body mass and distance (Cr, ml O2·kg−1·km−1) was determined on ten amateur runners before and immediately after running 15, 32 or 42 km on an indoor track at a constant speed. The Cr was determined on a treadmill at the same speed and each run was performed twice. The average value of Cr, as determined before the runs, amounted to 174.9 ml O2·kg−1·km−1 SD 13.7. After 15 km, Cr was not significantly different, whereas it had increased significantly after 32 or 42 km, the increase ranging from 0.20 to 0.31 ml O2·kg−1·km−1 per km of distance (D). However, Cr before the runs decreased, albeit at a progressively smaller rate, with the number of trials (N), indicating an habituation effect (H) to treadmill running. The effects of D alone were determined assuming that Cr increased linearly with D, whereas H decreased exponentially with increasing N, i.e.C r =C r0+aD+He−bN. The Cro, the “true” energy cost of running in nonfatigued subjects accustomed to treadmill running, was assumed to be equal to the average value of Cr before the run for N equal to or greater than 7 (171.1 ml O2·kg−1·km−1, SD 12.7;n = 30). A multiple regression of Cr on N and D in the form of the above equation showed firstly that Cr increased with the D covered by 0.123%·km−1, SEM 0.006 (i.e. about 0.22 ml O2·kg−1·km−1 per km,P〈0.001); secondly, that in terms of energy consumption (obtained from oxygen consumption and the respiratory quotient), the increase of Cr with D was smaller, amounting on average to 0.08%·km−1 (0.0029 J·kg−1·m−1,P〈0.001) and thirdly that the effects of H amounted to about 16% of Cr0 for the first trial and became negligible after three to four trials.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00626607

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The energetics of endurance running (1986)

Prampero, P. E. ; Atchou, G. ; Brückner, J. -C. ; [et al.]

Springer

European journal of applied physiology 55 (1986), S. 259-266

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ISSN: 1439-6327

Keywords: Endurance running ; Energy cost of running ; Running performance

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Maximal O2 consumption ( $$\dot V_{O_{_2 max} } $$ and energy cost of running per unit distance (C) were determined on the treadmill in 36 male amateur runners (17 to 52 years) who had taken part in a marathon (42.195 km) or semi-marathon (21 km), their performance times varying from 149 to 226 and from 84 to 131 min, respectively. $$\dot V_{O_{_2 max} } $$ was significantly (2p〈0.001) greater in the marathon runners (60.6 vs 52.1 ml · kg−1 · min−1) whileC was the same in both groups (0.179±0.017, S.D., mlO2 · kg−1 · m−1 above resting), and independent of treadmill speed. It can be shown that the maximal theoretical speed in endurance running (vEND) is set by $$\dot V_{O_{_2 max} } $$ , its maximal sustainable fraction (F), andC, as described by:vEND=F · $$\dot V_{O_{_2 max} } $$ ·C −1. SinceF was estimated from the individual time of performance,vEND could be calculated. The average speed of performance (vMIG) andvEND (m · s−1) were found to be linearly correlated:vMIG=1.12+0.64vEND (r 2=0.72;n=36). The variability ofvMIG explained byvEND, as measured byr 2, is greater than that calculated from any one regression betweenvMIG and $$\dot V_{O_{_2 max} } $$ (r 2=0.51),F · $$\dot V_{O_{_2 max} } $$ (r 2=0.58), or $$\dot V_{O_{_2 max} } $$ ·C −1 (r 2=0.63). The mean ratio of observed (vMIG) to theoretical (vEND) speeds amounted to 0.947±0.076 and increased to 0.978±0.079 (±S.D.;n=36) when the effects of air resistance were taken into account. It is concluded thatvEND=F · $$\dot V_{O_{_2 max} } $$ ·C −1 is a satisfactory quantitative description of the energetics of endurance running.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF02343797

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